TS – Tectonics & Structural Geology

EGU22-13304 | Presentations | TS1.2 | Marie Tharp Medal Lecture

Analogue modelling of subduction: yesterday, today and tomorrow. 

Francesca Funiciello

The use of experimental tectonics (also known as analogue-, laboratory, or physical modelling) to study tectonic processes is not a novelty in Earth Science. Following Sir James Hall’s pioneer work (1815), many modellers squeezed, stretched, pushed and pulled a wide range of materials – e.g., sand, clay, oil, painters’ putties, gelatins, wax, paraffin, syrups, polymers – to unravel a wide range of tectonic processes to determine parameters controlling their geometry, kinematics and dynamics. However, only recently experimental analogue modelling has definitively transformed from a qualitative to a quantitative technique, thanks to appropriate scaling relationships, the improvement in the knowledge of the rheology of both natural and analogue materials and the use of high-resolution monitoring techniques to quantify morphology, kinematics, stress, strain and temperature.

Here, I specifically review the experimental work performed to study one of the most intriguing aspects of plate tectonics: the subduction process. Subduction provides the dominant engine for plate tectonics and mantle dynamics. Moreover, it has also societal importance playing a key role on hazard at short (i.e., earthquakes and mega-earthquakes, tsunami, effusive and explosive volcanic activities with impact on aviation safety) and long time scales (i.e., local and global climate change). Over the last decades, a noteworthy advance in the quality and density of global geological, geophysical and experimental data has allowed us to provide systematic quantitative analyses of global subduction zones and to speculate on their behaviour. These constraints have been integrated into a mechanical framework through modelling.

I will bring you to a journey through the past, the present and the future of analogue modelling and related efforts, results and perspectives for the study of the subduction process. It will be shown how analogue models, with their inherent 3D character and behaviour driven by simple and natural physical laws, contribute to successfully unravelling the subduction process, inspiring new ideas. Challenging ongoing perspectives of analogue models imply the possibility to compare time and space scales, allowing to merge, within the same model, both short- and long-term and shallow and deep processes.

How to cite: Funiciello, F.: Analogue modelling of subduction: yesterday, today and tomorrow., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13304, https://doi.org/10.5194/egusphere-egu22-13304, 2022.

EGU22-12964 | Presentations | TS2.1 | Highlight | TS Division Outstanding ECS Award Lecture

Crustal stress across spatial scales 

Mojtaba Rajabi and Oliver Heidbach

The study of crustal stress examines the causes and consequences of in-situ stress in the Earth’s crust. Stress at any given point has several geological sources, including ‘short-term and local-scale’ and ‘long-term, ongoing and wide-scale’ source. In order to better characterise the crustal stress state, the analyses of both local- and wide-scale sources, and the consequences of their superposition are required. The global compilation of stress data in the World Stress Map database has increased significantly since its first release in 1992 and its analysis revealed large rotations of the stress tensor in several intraplate settings.

Large-scale stress analysis, so called first-order, (> 500 km) provides information on the key drivers of the stress state that result from large density contrasts and plate boundary forces. The analyses of stress at smaller-scales (< 500 km) have numerous applications in reservoir geomechanics, geo-storage sites, civil engineering and mining industry. To date, numerous studies have investigated the stress analysis from different perspectives. However, the stress, in geosciences, is still enigmatic because it is a scale-dependant parameter. It means, stress variations can be studied at both the ‘spatial-scale’ and ‘temporal-scale’. This paper aims to investigate the crustal stress pattern with a particular emphasis on the orientation of maximum horizontal stresses at various spatial-scales, ranging from continental scales down to basin, field and wellbore scales, to better evaluate the role of various stress sources and their applications in the Earth’s crust. The stress analyses conducted in this work shows that stress pattern at large-scales do not necessarily represent the in-situ stress pattern at smaller-scales. Similarly, analysis of just a couple of borehole measurements in one area might not yield a good representation of the regional stress pattern.

How to cite: Rajabi, M. and Heidbach, O.: Crustal stress across spatial scales, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12964, https://doi.org/10.5194/egusphere-egu22-12964, 2022.

TS1 – Topics in Tectonics and Structural Geology

EGU22-854 | Presentations | TS1.2

Crustal evolution and oceanic core complexes at the Ascension fracture zone – MAR 7° S 

Anke Dannowski, Ingo Grevemeyer, Valentin Baehre, Jörg Bialas, and Tim Reston

The Ascension fracture zone (AFZ) is a double transform fault system and offsets the Mid-Atlantic Ridge axis by 230 km at 7 °S. The transform fault system is consisting of two parallel transform faults, the North and South Ascension Fracture Zone, sandwiching a ~20 km long ridge segment, which we name Ascension Fracture Zone segment. The segment shows strong topographical variations and corrugated surfaces typical for detachment faults that form oceanic core complexes. An elongated massif approximately 50 km east of the ridge axis with transform-parallel striations of over 100 km on top, indicate a detachment fault active for several million years. This would be one of the longest transform-parallel corrugated surface observed anywhere in the oceans. The question arises whether the corrugations belong to one OCC, representing a rather stable crustal accretion, or if several OCCs have been developed, representing a rather variable crustal accretion. Changes in melt supply influence the crustal structure, which in turn can be recognised by seismic methods.

RV Meteor (cruise M62-4) set out to acquire seismic refraction and wide-angle reflection data along a 265 km long spreading parallel transect to image the crustal velocity distribution and the crustal thickness of the intervening short AFZ segment. Densely spaced, every ~9.25 km, ocean bottom seismometers recorded P-wave and converted S-wave energy emitted from a 64 l G-gun cluster at a shot interval of 60 s, equal to ~125 m shot distance.

The results reveal P-wave velocities that vary along the profile from 3.5 km/s to 5 km/s at the seafloor and reach 7.2 km/s in ~6 km depth at the ridge axis and at 3 km to 4 km depth under the ridge shoulders. At larger offsets to the ridge axis. S-wave velocities vary from 2 km/s to 2.5 km/s at the seafloor and increase to 3.5 km/s in ~2 km depth east of the ridge axis, while the S-wave velocities west of the ridge axis show a lower velocity gradient and reach 3.5 km/s in 3 km to 4 km depth. A Vp/Vs ratio >1.9 is observed in areas where seafloor corrugations have been observed. These areas are interpreted as serpentinised mantle material. However, the high Vp/Vs ratio seems to be limited to the upper 1.5 km to 2 km of the subsurface, indicating that the hydration of the seafloor is limited to that depth. The eastern ridge flank is dominated by a high Vp/Vs ratio for offsets larger than 40 km from the ridge axis, however, it is interrupted by small stripes of Vp/Vs <1.9. Thus, in the short AFZ segment, detachment faulting seem to occur continuously over a long period with short interruptions when the magmatic budged exceeds a certain upper limit.

How to cite: Dannowski, A., Grevemeyer, I., Baehre, V., Bialas, J., and Reston, T.: Crustal evolution and oceanic core complexes at the Ascension fracture zone – MAR 7° S, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-854, https://doi.org/10.5194/egusphere-egu22-854, 2022.

EGU22-4929 | Presentations | TS1.2

Petrology of Alpine Tethys serpentinites: New insights on serpentinization at passive margins 

Flora Hochscheid, Marc Ulrich, Manuel Muñoz, Damien Lemarchand, and Gianreto Manatschal

Fluid-rock interactions in mantle rocks that turns peridotite into serpentinite has been widely documented during the past two decades, for geological settings such as mid-ocean ridges (MOR) and subduction zones. In contrast, serpentinization at rifted margins has received much less attention, while serpentinites at these settings are largely involved in geochemical and tectonic processes that occur from continental break-up to the establishment of a steady-state MOR. This study presents new petrological and mineralogical investigations on peridotites that were part of the subcontinental mantle exhumed along a former Ocean-Continent Transition (OCT) of the Jurassic Alpine Tethys, nowadays exposed as ophiolitic nappes (Platta, Tasna and Totalp) in the southeastern part of the Swiss Alps. These peridotites experienced various degrees of serpentinization, from moderately to completely serpentinized. At Totalp, initially located close to the continent, serpentinization forms a typical lizardite-bearing mesh texture that surrounds relics of primary minerals. Locally, the association of andradite and polyhedral serpentine occurs as alteration products of clinopyroxene, which may be interpreted in terms of low temperature serpentinization and near-isochemical conditions. At lower Platta, which represents the oceanwards (distal) domain of the OCT, serpentinization is extensive and, similarly to Totalp, predominantly formed by mesh lizardite. For the two previously mentioned sites, the typical mesh texture suggests a fluid-rock interaction with a low water-to-rock ratio. At Tasna and upper Platta, which both correspond to more proximal domains of the OCT (i.e., continentwards), serpentinites are characterized by several superimposed serpentinization events marked by successive generations of serpentine-filling veins with distinct morphologies and textures, forming the following sequence: Mesh texture —> Banded veins (V1) —> Crack seals (V2) —> Lamellar veins (V3). The V1 banded veins are made of several serpentine species including chrysotile, polygonal serpentine, polyhedral serpentine and lizardite. They formed as a result of gradual opening during exhumation of the mantle from a supersaturated solution. The progressive evolution from chrysotile to polygonal serpentine and then lizardite is attributed to more intense fluid-rock interactions and a lower fluid saturation with decreasing depth. V2 crack seals consist of chrysotile veins formed at shallow depth after strain release and under high water/rock ratios. Surprisingly, antigorite was identified as the latest vein generation (V3). Trace element compositions for V3 are comparable to those of earlier vein generations, but strongly differ from those attributed to the Alpine convergence, excluding their formation during prograde subduction metamorphism. Rather, we propose that antigorite veins formed as a result of compressive stresses generated by apparent unbending of the footwall during final exhumation. This result shows that antigorite is not only restricted to convergent domains, and that it may be more common in rifted margins and (ultra-)slow spreading centers than previously thought.

How to cite: Hochscheid, F., Ulrich, M., Muñoz, M., Lemarchand, D., and Manatschal, G.: Petrology of Alpine Tethys serpentinites: New insights on serpentinization at passive margins, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4929, https://doi.org/10.5194/egusphere-egu22-4929, 2022.

The 64°E region of the eastern SWIR is a melt poor end member region of the MOR system. Magma focusing to axial volcanoes leaves >50 km wide along axis corridor, where seafloor spreading occurs almost fully via successive alternate polarity detachment faults (Sauter et al., 2013). The present-day south-dipping young (~300 kyrs; Cannat et al., 2019), active detachment fault cuts through an older north dipping detachment fault. The active detachment emergence can be traced over 32 km from the shipboard bathymetry data (for comparison, the scoped-shaped finely corrugated 13°20’N exhumed detachment surface at the Mid-Atlantic Ridge extends only ~5-6 km along-axis; Escartin et al., 2017). HR micro-bathymetry maps acquired on the west and east sides of this emergence line indicate an along-strike variation of the fault structure and geometry. In the east, the fault emerges at an overall angle of ~26°-30° and the emerging fault surface is irregular, with undulations at hectometer to km scales, close to parallel to spreading direction, and rare occurrences of decameter-scale corrugations, up to 20° oblique to spreading. In the west, the detachment emerges in the form of two distinct fault splays, ~400 m apart, both at an angle ~40°-50°.  This western region receives some magma input, resulting in localized patches of basalt and hummocky ridges.

Near fault deformation structures, documented by Remotely Operated Vehicle (ROV) dives and sampling, also differ between east and west. In the west, sigmoidal blocks (~5-10 m) of moderately fractured serpentinized peridotite, some with gabbro dikes, are observed below the emerging faults, which consist of <1.5 m thick zone of serpentinite breccia, and micro-breccia, with cm-thick intervals of gouge. In the east, the highly strained intervals are thicker (up to 8 m), with a greater proportion of serpentinite gouge and microbreccia. The more coherent rocks below the fault are also more pervasively fractured, with planar decimeter to meter-spaced south-dipping joints. ROV dives near the detachment breakaway offer an opportunity to study the deformation below a more mature region of the previously active detachment. Steep landslide head scarps there expose vertical sections, up to 70 m thick, with several intervals of serpentine gouge and micro-breccia, intercalated with coarser brecciated serpentinized peridotite, and with sigmoidal, meter to decameter sized blocks of serpentinized peridotite. Together, these observations point to a heterogeneous structure and to a variable thickness of the strain localization/damage zone associated with the emerging portions of the 64°40'E SWIR detachment. Based also on the seismic reflection structure of the fault zone at depth (Momoh et al., 2017), we propose that the material that emerges samples distinct regions of a kilometer-thick heterogeneously deformed damage zone, leading to different geometries and structure of the emerged fault surface(s).

How to cite: Mahato, S. and Cannat, M.: Early stages of evolution of an axial detachment fault at the ultraslow spreading mid-ocean ridge (64°40'E SWIR), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5911, https://doi.org/10.5194/egusphere-egu22-5911, 2022.

EGU22-7065 | Presentations | TS1.2

Arctic Mid-Ocean Ridge seismicity: Results from an OBS deployment at Loki’s Castle 

Marie Eide Lien, Matthias Pilot, Vera Schlindwein, Lars Ottemöller, and Thibaut Barreyre

Activity along the Arctic Mid-Ocean Ridge (AMOR) has been progressively explored over the past 20 years. Along the ridge, processes such as dike intrusion and faulting cause earthquakes. We focus on an area around the Loki’s castle hydrothermal vent field (LCVF), located on the Mohn ultra-slow spreading ridge. Ultra-slow spreading systems are strongly controlled by tectonic processes, which provide an opportunity to study almost exclusively the effect of tectonism on a hydrothermal vent field.

In June 2019, we deployed a network of eight broadband ocean bottom seismometers (OBS) in an area of about 20 by 20 km around the LCVF. The OBSs were deployed for a one-year monitoring period until July 2020. We processed the OBS data using an automatic detection routine and machine learning approach to pick phases, and then located the local earthquakes based on a 1D velocity model. This provided an earthquake catalogue that was interpreted to understand the seismicity in terms of spatial and temporal distribution, and to identify fault structures. Within the broader tectonic system we aim to enhance our understanding of the LCVF.

How to cite: Lien, M. E., Pilot, M., Schlindwein, V., Ottemöller, L., and Barreyre, T.: Arctic Mid-Ocean Ridge seismicity: Results from an OBS deployment at Loki’s Castle, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7065, https://doi.org/10.5194/egusphere-egu22-7065, 2022.

EGU22-7217 | Presentations | TS1.2

Seafloor spreading modes across the Charlie Gibbs transform system (52°N, Mid Atlantic Ridge) 

Alessio Sanfilippo, Sergey Skolotnev, Marco Ligi, and Alexander Peyve and the A.N. Strakhov Expedition S50 and A.N. Vavilov Expedition V53 Science Parties

The prominent Charlie Gibbs right-lateral multi-transform system (52°-53°N) offsets the Mid Atlantic Ridge (MAR) by ~340 km. The transform system is formed by two distinct transform faults linked by a short ~40 km-long intra-transform spreading centre (ITR). The two adjacent MAR segments are influenced by both the Azores and the Iceland mantle plume. Recently, high resolution multibeam surveys and a dense sampling program of the entire transform system, including the adjacent southern and northern MAR segments, were carried out during expeditions of R/V Celtic Explorer (2015, 2016 and 2018) [1], R/V A.N. Strakhov (2020) and A.S. Vavilov (2021) [2]. The new surveys show widespread occurrence of large structures with corrugated surfaces and exhumed lower crust and mantle rocks on both sides of the intra-transform spreading axis. Morphological analyses of the intra-transform domain and magnetic data indicate that crustal accretion was driven by flip-flop detachment faulting [3], with minimal ridge melt supply and little axial volcanism. The tectonic spreading persisted for tens of millions of years. Along axis MORB chemistry shows that changes in seafloor accretion styles are mirrored by variations in melt supply, in turn dependent on mantle temperature and by a large-scale mantle heterogeneity. Charlie Gibbs is a key case study of how seafloor accretion modes at a spreading segment is critically dependent on mantle thermal state but also on its intrinsic compositional heterogeneity.

[1] Georgiopoulou A. and CE18008 Scientific Party, 2018. Tectonic Ocean Spreading at the Charlie-Gibbs Fracture Zone (TOSCA): CE18008 Research Survey Report. Marine Institute of Ireland, Dublin, pp 1-24. [2] Skolotnev, S. et al., 2021. Seafloor Spreading and Tectonics at the Charlie Gibbs Transform System (52-53ºN, Mid Atlantic Ridge): Preliminary Results from R/V AN Strakhov Expedition S50. Ofioliti, 46(1). [3] Cannat, Met al., 2019. On spreading modes and magma supply at slow and ultraslow mid-ocean ridges. Earth and Planetary Science Letters, 519, 223-233.

How to cite: Sanfilippo, A., Skolotnev, S., Ligi, M., and Peyve, A. and the A.N. Strakhov Expedition S50 and A.N. Vavilov Expedition V53 Science Parties: Seafloor spreading modes across the Charlie Gibbs transform system (52°N, Mid Atlantic Ridge), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7217, https://doi.org/10.5194/egusphere-egu22-7217, 2022.

EGU22-7720 | Presentations | TS1.2

The thermal regime of mid-ocean ridges: geological perspectives and numerical modelling 

Mathilde Cannat, Jie Chen, and Jean Arthur Olive

The thermal regime of mid-ocean ridges determines their spreading modes (i.e., the combination of mid-ocean ridge tectonic, magmatic and hydrothermal processes that control the composition and structure of the oceanic lithosphere). It is determined by the balance of heat supply and heat loss in the axial region. Most heat is supplied through magma, while hydrothermal energy fluxes depend on the permeability and depth extent of the hydrothermal cooling domain, and on the thickness of the conductive boundary layer at its base. At fast spreading ridges, the flux of melt is high, the thermal regime is hot, and melt resides at depths of only a few kms in a steady state fashion, well within the reach of vigourous axial hydrothermal convection. At slow ridges, the melt flux is lower, the thermal regime is colder, so that melt can only reside durably at depths that are commonly > 10 km, out of the reach of vigourous (high permeability) hydrothermal systems. Melt there, however, is commonly injected higher up in the axial lithosphere, forming transient melt bodies in colder host rocks and triggering high temperature, black smoker, hydrothermal systems.

Here we report on numerical models that explore the thermal effects of varying both the melt flux and the depth of magma emplacement, a parameter that previously published mid-ocean ridge thermal models did not take into account. Our models do predict the large variability in thermal regime that is documented at slow ridges, from cold detachment-dominated settings, to hotter melt-rich segment centers. We discuss these results and the strengths and limitations of the modelling approach. We also explore the potential effects of varying the melt flux and melt emplacement depth with time at a given slow spreading ridge location, on crustal construction processes and on the respective roles of faults and melt intrusions to accommodate plate divergence.  

How to cite: Cannat, M., Chen, J., and Olive, J. A.: The thermal regime of mid-ocean ridges: geological perspectives and numerical modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7720, https://doi.org/10.5194/egusphere-egu22-7720, 2022.

Lucky Strike volcano is the central edifice of the Lucky Strike segment, Mid-Atlantic Ridge. Its summit overlies an axial magma chamber (AMC), 3-3.8 km beneath the seafloor, and hosts one of the largest known deep-sea hydrothermal fields. Local seismicity beneath the hydrothermal field has been monitored since 2007 as a part of the EMSO (European Multidisciplinary Seafloor and water column Observatory)-Azores observatory by 5 OBSs with yearly redeployments. From the 2007-2019 earthquake catalog, the primary process for the seismicity observed beneath the volcano region is proposed to be thermal contraction at the base of the hydrothermal circulation. In this interpretation the most seismically active zones represent the domains of maximum heat extraction at the base of the hydrothermal system. Here we present the evolution of the hydrothermal system controlled by magmato-tectonic interactions in the frame of this interpretation.

First, we observe two shifts of the most seismically active zones from ~1.4km North-Northwest of the hydrothermal field as documented in 2007-2009 to ~0.7km to North of the field in between 2010-2013 and then Eastward for about ~0.6km from 2010-2013 to 2015-present. These shifts, of the order ~600-700 meters, occurring at time scales of a few years, might be driven by one or several of the following mechanisms: the relocation of the maximum heat extraction zone to a shallower region of the AMC after significant heat extraction, the relocation to a recent magmatic injection,  and/or a tectonically-driven change in the hydrothermal fluid pathways.

Second, we observe three main Higher Seismic Activity (HSA seismic rate > 18 events/week) periods: April-June 2009, August-September 2015 and April-May 2016. The 2009 HSA period lasted ~13 weeks and the events clustered just above the AMC, while the 2015 and 2016 HSA periods lasted ~4-5 weeks, with events forming a narrow, dike-shaped cluster between the AMC  and just few meters below seafloor. HSA periods are characterized by deeper events and the occurrence of a few higher magnitude events (ML > 1.0). In between HSA periods, the seismicity tends to align along the trace of an inward dipping fault that bounds the narrow axial graben to the west, at the top of the volcano. The HSA periods can thus be interpreted as periods of maximum heat extraction by the hydrothermal circulation, possibly obscuring the background fault-related seismicity that is detected in periods of lesser seismic activity.

How to cite: Bohidar, S., Crawford, W., and Cannat, M.: Seismic constraints on the hydrothermal circulation and magmato-tectonic interactions beneath Lucky Strike volcano, Mid-Atlantic Ridge, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8780, https://doi.org/10.5194/egusphere-egu22-8780, 2022.

Mantle melting at mid-ocean ridges is thought to strengthen residual mantle by extracting water (hydroxyl defects) thereby increasing its viscosity by over two orders of magnitude to create a “compositional” lithosphere. Although water is strongly partitioned into basaltic melt relative to olivine, mantle dehydration also requires that melt extraction be efficient. Otherwise, retained low-degree hydrous melts will rapidly reinfuse surrounding mantle with hydrogen on solidifying owing to its high diffusivity in mantle materials. The pattern of mantle melting at ridges varies strongly both within segments and with spreading rate. We examine these patterns along the northern Mid-Atlantic Ridge and the adjoining Reykjanes Ridge using mantle Bouguer anomalies (MBAs). The Reykjanes Ridge has a linear axis, no transform faults, and a continuous MBA low, indicating continuous axial mantle melting. In contrast the adjoining Mid-Atlantic Ridge is segmented with transform and non-transform discontinuities and has pronounced “bulls-eye” MBA lows indicating focused mantle melting beneath each segment. We hypothesize that the pattern of mantle melting explains the absence or occurrence of transform faults on these systems. Segmented mantle melting results in dry, depleted, and strong mantle beneath ridge segment interiors but at segment ends, low extents of melting and inefficient melt extraction preserve damp and weak mantle.  Since the rheological changes created by segmented melting develop rapidly near the ridge axis and extend from the Moho to the dry solidus depth, a pronounced rheological banding is formed in the mantle. The weak segment ends localize shear zones oriented in the spreading direction where transform faults may form whereas the ridges, flanked by strong compositional lithosphere, will be oriented orthogonally.  Our hypothesis also explains the variation of transform fault spacing with spreading rate or their absence. At ultra-slow ridges, overall melting is limited and irregular and melt extraction is inefficient so that no systematic rheological bands form and transform faults are not favored. At slow spreading rates, mantle melting forms three-dimensional diapiric instabilities at typical spacings of ~40-80 km so that transform faults also have this spacing. As spreading increases to fast rates mantle melting becomes two-dimensional and typical magmatic segment length and corresponding transform spacing increases to >100 km.  At ultra-fast ridges (>145 km/my) mantle melting is ubiquitous and melt extraction is everywhere efficient so that a systematic rheological banding does not form and transform faults are again not favored. Our model implies that beyond cooling and strengthening with age, the pattern of mantle melting shapes the rheological structure of oceanic lithosphere and the geometry of plate tectonics. Reference:  Martinez and Hey, 2022, https://doi.org/10.1016/j.epsl.2021.117351

How to cite: Martinez, F. and Hey, R.: Segmented mantle melting, lithospheric strength, and the origin of transform faults: Insights from the North Atlantic, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10702, https://doi.org/10.5194/egusphere-egu22-10702, 2022.

EGU22-11888 | Presentations | TS1.2

An intrusive complex imaged within the roots of an oceanic core complex using 3D full-waveform inversion 

Michele Paulatto, Toby Oxford, and Rory Bardner

3D full waveform inversion (FWI) has been applied to the seismic refraction data of the MARINER (Mid-Atlantic Ridge INtegrated Experiment at Rainbow) experiment to create a robust high-resolution model of the seismic velocity structure of the Rainbow massif. The Rainbow massif is an oceanic core complex located on a non-transform discontinuity (NTD) in a magma-starved region of the mid-Atlantic Ridge. Despite the low magmatic input, the core complex hosts a high-temperature hydrothermal vent field  (>340°C) that requires a long-lived magmatic heat source. The FWI results show that deep within the massif, ∼3-8 km below the seafloor, is a low-velocity body that represents a partially molten sill complex with >20% gabbro intrusions. The complex extends out north to the AMAR Minor N segment suggesting an increased magmatic input into this segment, forcing the NTD to migrate southwards. Extensive magmatic intrusion into the core complex was likely responsible for the termination of slip on the detachment fault. Above the sill complex, we image a channel of lower velocity material that cuts through the main hydration front to the deep sill region. Velocity values and micro-seismicity correlation suggests that this channel consists of 10-30% serpentinized peridotite and fracturing from serpentinization reactions create fluid pathways for fluids to exchange between the deeper partially molten heat source and the fluid network of the hydrothermal vents. A high-velocity chimney below the extinct vent sites of the massif may represent the abandoned stockwork of these extinct hydrothermal systems.

How to cite: Paulatto, M., Oxford, T., and Bardner, R.: An intrusive complex imaged within the roots of an oceanic core complex using 3D full-waveform inversion, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11888, https://doi.org/10.5194/egusphere-egu22-11888, 2022.

EGU22-12802 | Presentations | TS1.2

Dependencies of morphology and lithological variations on tectonics, thermal structure and ocean loading at ultra-slow and slow ridges. 

Leila Mezri, Javier Gracià-Pintado, Marta Pérez-Gussinyé, Zhonglan Liu, and Bach Wolfgang

Why do some mid-ocean ridges have morphology that expresses oceanic core complexes with large gabbro bodies, while others have smooth seafloors with large exposures of serpentinized mantle or rough seafloors, while lavas are observed almost everywhere?

Over the past few decades, numerical models have inferred that the fundamental mechanism controlling the wide diversity of lithology, crustal thickness, and ridge morphology is the balance between magmatism and tectonics. Key controls on this modeled equilibrium are the melt supply rate, which varies to account for the discontinuous volcanism observed on slow ridges, and the thermal structure, which depends on the balance between heat injected during magmatic accretion and heat removed by hydrothermal cooling, modulated by the spreading rate.

Based on this paradigm, it has been established that the fraction of melt that is accreted into the crust controls the formation of large oceanic core-complexes and flip-flop detachments, with the former being formed at fractions corresponding of half of spreading rate and the latter being formed when the melt supply is much smaller.

However, several fundamental questions remain poorly understood or unanswered. Why can slip on oceanic detachment faults continue and why does it stop? How do serpentinization and magmatic intrusions play a role in crustal growth and how do they interact? How and why do mechanisms related to magma supply switch from magmatic to detachment dominated mode during oceanic accretion?

Here we present self-consistent numerical simulations of the development of mid-ocean ridges, starting  from continental rifting and breakup. In our models melt supply varies dynamically with extension velocity and is affected by faulting. We focus on understanding how tectonism, melting, serpentinisation and hydrothermal cooling interact to form smooth-seafloor, core complexes and normal igneous seafloor, and their diverse crustal lithology.



How to cite: Mezri, L., Gracià-Pintado, J., Pérez-Gussinyé, M., Liu, Z., and Wolfgang, B.: Dependencies of morphology and lithological variations on tectonics, thermal structure and ocean loading at ultra-slow and slow ridges., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12802, https://doi.org/10.5194/egusphere-egu22-12802, 2022.

EGU22-13027 | Presentations | TS1.2

How Continents Break-up and New Ocean Ridges are Established 

Marta Pérez-Gussinyé, Javier García-Pintado, Zhonglan Liu, and Leila Mezri

The processes that lead to the transition from continental extension and break-up to steady-state mid-ocean ridge formation are not well understood. Particular unknowns are the paleo-water depths at which the continental lithosphere breaks up, the nature of the crust at the so-called continent-ocean transition and when and how a steady-state mid-ocean ridge is established. To understand these questions we use numerical models that couple tectonic deformation, sedimentation, hydrothermal cooling, serpentinisation and melting, as a virtual laboratory. We present results of models run with different velocities that simulate natural examples observed in nature such as the South China sea and the West Iberia-Newfoundland margins. We focus on the evolution of subsidence, heat-flow and nature of the basement as the rift transforms into a steady-state mid-ocean ridge and show how the interplay between tectonics and hydrothermal cooling lead to the different configurations observed in nature.

 

How to cite: Pérez-Gussinyé, M., García-Pintado, J., Liu, Z., and Mezri, L.: How Continents Break-up and New Ocean Ridges are Established, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13027, https://doi.org/10.5194/egusphere-egu22-13027, 2022.

EGU22-13304 | Presentations | TS1.2 | Marie Tharp Medal Lecture

Analogue modelling of subduction: yesterday, today and tomorrow. 

Francesca Funiciello

The use of experimental tectonics (also known as analogue-, laboratory, or physical modelling) to study tectonic processes is not a novelty in Earth Science. Following Sir James Hall’s pioneer work (1815), many modellers squeezed, stretched, pushed and pulled a wide range of materials – e.g., sand, clay, oil, painters’ putties, gelatins, wax, paraffin, syrups, polymers – to unravel a wide range of tectonic processes to determine parameters controlling their geometry, kinematics and dynamics. However, only recently experimental analogue modelling has definitively transformed from a qualitative to a quantitative technique, thanks to appropriate scaling relationships, the improvement in the knowledge of the rheology of both natural and analogue materials and the use of high-resolution monitoring techniques to quantify morphology, kinematics, stress, strain and temperature.

Here, I specifically review the experimental work performed to study one of the most intriguing aspects of plate tectonics: the subduction process. Subduction provides the dominant engine for plate tectonics and mantle dynamics. Moreover, it has also societal importance playing a key role on hazard at short (i.e., earthquakes and mega-earthquakes, tsunami, effusive and explosive volcanic activities with impact on aviation safety) and long time scales (i.e., local and global climate change). Over the last decades, a noteworthy advance in the quality and density of global geological, geophysical and experimental data has allowed us to provide systematic quantitative analyses of global subduction zones and to speculate on their behaviour. These constraints have been integrated into a mechanical framework through modelling.

I will bring you to a journey through the past, the present and the future of analogue modelling and related efforts, results and perspectives for the study of the subduction process. It will be shown how analogue models, with their inherent 3D character and behaviour driven by simple and natural physical laws, contribute to successfully unravelling the subduction process, inspiring new ideas. Challenging ongoing perspectives of analogue models imply the possibility to compare time and space scales, allowing to merge, within the same model, both short- and long-term and shallow and deep processes.

How to cite: Funiciello, F.: Analogue modelling of subduction: yesterday, today and tomorrow., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13304, https://doi.org/10.5194/egusphere-egu22-13304, 2022.

The Dayi seismic gap of the Longmenshan thrust belt is located between the ruptures of the 2008 Wenchuan Earthquake and the 2013 Lushan Earthquake, with a length of about 40 ~ 60 km. So far, it has been still a heated debate on whether the Dayi seismic gap has the hazard of strong earthquakes in the near future. The occurrence of a strong earthquake in the seismic gap is closely related to the existence of high stress accumulation and the most direct method is to measure the borehole stress in the field. In order to find out the present stress state, in-situ stress measurements were carried out at the hanging wall and footwall of Dachuan-Shuangshi fault zone in Dachuan Town. The results showed that the hanging wall and footwall of Dachuan-Shuangshi fault zone in Dayi seismic gap are in a high-stress state. Based on seismicity parameter b-value, crustal velocity structure, GPS deformation monitoring data and temperature data, etc., it can be learned that there is a positive correlation coupling relationship between near surface shallow stress and deep stress. In this paper, a response model of shallow stress to deep locking was established. It was speculated that Dayi seismic gap has the potential hazard of strong earthquakes. This research result not only deepens the understanding of the relationship between stress and earthquake preparation, but also provides an effective scientific method for identifying seismic hazards in other active fault seismic gaps.

How to cite: li, B., Huang, J., and Xie, F.: In situ stress state and earthquake hazard assessment in Dayi seismic gap of the Longmenshan thrust belt, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-648, https://doi.org/10.5194/egusphere-egu22-648, 2022.

EGU22-799 | Presentations | TS1.4

Machine Learning and Underground Geomechanics – data needs, algorithm development, uncertainty, and engineering verification 

Josephine Morgenroth, Usman T. Khan, and Matthew A. Perras

Machine learning algorithms (MLAs) are emerging as a powerful tool for forecasting complex and nuanced rock mass behaviour, particularly when large, multivariate datasets are available. In engineering practice, it is often difficult for geomechanical professionals to investigate all available data in detail, and simplifications are necessary to streamline the engineering design process. An MLA is capable of processing large volumes of data quickly and may uncover relationships that are not immediately evident when manually processing data. This research compares two algorithms developed for two mines representing end member behaviours of rock failure mechanisms: squeezing ground with high radial convergence, and spalling ground with high in situ stresses and seismicity. For the squeezing ground case study, a Convolutional Neural Network is used to forecast the yield of the tunnel liner elements using tunnel mapping images as the input. For the high stress case study, a Long Short Term Memory network is used to forecast the in-situ stresses that takes time series microseismic events and geomechanical properties as inputs. The two case studies are used to compare input data requirements and pre-processing techniques. Ensemble modelling techniques used to quantify MLA uncertainty for both case studies are presented. The development of the two MLAs is discussed in terms of their complexity, generalizability, performance evaluation, verification, and practical applications to underground rock engineering. Finally, best practices for MLA development are proposed based on the two case studies to ensure model interpretability and use in engineering applications.

How to cite: Morgenroth, J., Khan, U. T., and Perras, M. A.: Machine Learning and Underground Geomechanics – data needs, algorithm development, uncertainty, and engineering verification, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-799, https://doi.org/10.5194/egusphere-egu22-799, 2022.

EGU22-2742 | Presentations | TS1.4 | Highlight

Assessing the effect of mass withdrawal from a surface quarry on the Mw4.9 Le Teil (France) earthquake triggering 

Julie Maury, Théophile Guillon, Hideo Aochi, Behrooz Bazargan, and André Burnol

On November 11th 2019, the Le Teil, France earthquake occurred in the vicinity of a quarry. Immediately, the question was raised about the potential triggering of this earthquake by the quarry. However, another potential triggering source is a hydraulic effect related to heavy rainfall (Burnol et al, 2021). That’s why it is important to quantify precisely the mechanical effect of mass withdrawal. Results from different studies (Ampuero et al, technical report CNRS, 2019; De Novellis et al, Comm. Earth Env., 2021) agrees to a Coulomb stress variation of 0.15 to 0.2 MPa. However, these studies are based on Boussinesq solution supposing a homogeneous half-space that maximize the effect of the quarry. Here we used the distinct element method code 3DEC @Itasca in 3D to take advantage of an improved geological model and assess the impact of discontinuities as well as lithology. Our results show the maximum Coulomb stress change of 0.27 MPa at 1.4 km depth, a value of the same order as what is obtained with Boussinesq solution. A comparison between the location of the earthquake (Delouis et al, 2021) and the maximum Coulomb stress is realized. The maximum value is located at the intersection of the Rouviere fault with another local fault highlighting the interaction between these structures. However, the in situ stress field is not well-known, fault parameters are difficult to assess and there is some uncertainty on the volume of extracted material in the 19th century estimated by the quarry owner. Additionally, the presence of marl in the Hauterivian layer suggests it could have an elasto-plastic behavior. A parametric study has been realized to assess the effect on Coulomb stress change of these uncertainties taking plausible values for each parameter. We show that the uncertainty associated with our calculations affect the results within a range of less than 10%.

How to cite: Maury, J., Guillon, T., Aochi, H., Bazargan, B., and Burnol, A.: Assessing the effect of mass withdrawal from a surface quarry on the Mw4.9 Le Teil (France) earthquake triggering, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2742, https://doi.org/10.5194/egusphere-egu22-2742, 2022.

EGU22-3272 | Presentations | TS1.4

The stress memory in rocks: insight from the deformation rate analysis (DRA) and acoustic emission (AE) 

Zulfiqar Ali, Murat Karakus, Giang D. Nguyen, and Khalid Amrouch

Deformation rate analysis (DRA) and Acoustic Emission (AE) are popular methods of in-situ stress measurements from oriented cored rocks which take advantage of the rock stress memory also known as the Kaiser effect. These methods rely on the accurate measurement of a point of inflection in the characteristic DRA and AE curves, however, due to the complex geological stress history in rocks, locating point of inflection can be problematic. In order to better understand the stress memory experiments were performed on a combination of six different types of soft, and hard crystalline rocks including concrete with no stress history. The effect of loading modes, strain rates, and time delay were studied on preloaded rock specimens to investigate their influence on the stress memory. A fading effect was observed when the number of the cycles in the test were increased which led to the development of a new method of quantifying the preloads. Results show that the type of loading and the loading rate has little to no influence on the Kaiser effect, however, under faster loading rates the Kaiser effect is more distinct. Likewise, no time dependency was observed for time delays up to seven months.

How to cite: Ali, Z., Karakus, M., Nguyen, G. D., and Amrouch, K.: The stress memory in rocks: insight from the deformation rate analysis (DRA) and acoustic emission (AE), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3272, https://doi.org/10.5194/egusphere-egu22-3272, 2022.

A review of works is presented in which new models of continuum mechanics generalizing the classical theories of elasticity are being intensively developed. These models are used to describe composite and statistically inhomogeneous media, new structural materials, as well as complexly constructed massifs in mine and ground conditions; and in the study of phenomena occurring in permafrost under the influence of heating processes. A characteristic feature of the theory of media with a hierarchical structure is the presence of explicit or implicit scale parameters, i.e. explicit or implicit non-locality of the theory. This work focuses on the study of the non-locality effects and internal degrees of freedom reflected in internal stresses that are not described by the classical theory of elasticity, but can be potential precursors of the development of a catastrophic process in a rock mass.

How to cite: Hachay, O. and Khachay, A.: Geophysical research and monitorind within a block-layered model with inclusions of hierrchical structure, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4574, https://doi.org/10.5194/egusphere-egu22-4574, 2022.

EGU22-4738 | Presentations | TS1.4

Modeling principal stress orientations in the Arabian plate using plate velocities 

Santiago Pena Clavijo, Thomas Finkbeiner, and Abdulkader M. Afifi

The Arabian Peninsula is part of a small tectonic plate that is characterized by active and appreciable deformations along its boundaries. Knowledge of the present-day in situ stress field in the Arabian plate and its variability is critical for earth science disciplines that require an understanding of geodynamic processes. In addition, it is essential for a range of practical applications that include the production of hydrocarbons and geothermal energy, mine safety, seismic hazard assessment, underground storage of CO2, and more.

This project aims at modeling the stress orientation field in the Arabian Plate using advanced computational tools together with a plate velocity model. We built a three-layer 3D model of the Arabian crust using digital elevation, basement depth, and Moho depth maps. Based on these data, we built a 3D unstructured finite element mesh for the whole Arabian plate, including the offshore area, with finer resolution at critical locations. The latter is a novel approach to this work.  To capture the deformation caused by the water bodies in the Red Sea, Gulf of Aden, and the Arabian Sea areas, we set a hydrostatic boundary condition as a function of bathymetry. Along the Zagros fold and thrust belt, we pinned the plate boundary to capture continental collision. Finally, the partial differential equation of force equilibrium (a linear static analysis) is solved using plate displacements (inferred from plate velocities) as boundary conditions for several displacement conditions.

The modeling results suggest NE-SW SHmax azimuths in northeastern Saudi Arabia and Kuwait while the Dead Sea transform areas show NW-SE to NNW-SSE azimuths, and the rest of the plate is characterized by predominant N-S SHmax azimuth. Due to pinned boundary conditions at the Zagros Mountains, SHmax azimuth changes from N-S at the Red Sea basin to NE-SW at the Zagros fold and thrust belt. We also notice significant stress concentrations in the transition from the Arabian shield to the sedimentary basins in the Eastern parts of the plate. This is in response to associated changes in rock properties. Hence, the simulated stress orientations corroborate the ongoing tectonic process and deepen our understanding of regional and local in situ stress variation drivers as well as the current elastic deformation in the Arabian plate.

How to cite: Pena Clavijo, S., Finkbeiner, T., and Afifi, A. M.: Modeling principal stress orientations in the Arabian plate using plate velocities, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4738, https://doi.org/10.5194/egusphere-egu22-4738, 2022.

EGU22-5494 | Presentations | TS1.4 | Highlight

Stress characterization in the Canadian Shield: Complexity in stress rotation 

Wenjing Wang and Douglas Schmitt

NE-SW stress compression in the Western Canadian Sedimentary Basin was discovered in the pioneering borehole breakout observations of Bell and Gough (1979). However, all of these and subsequent stress direction indicators are from the Phanerozoic sediment veneer, while the state of stress in the underlying craton remains unexplored. With the emergent demands on geothermal energy and wastewater and CO2 disposal, however, the state of stress in the cratons can no longer be safely ignored. To address this problem, we analyze various vintages of geophysical logs obtained from a serendipitous wellbore-of-opportunity drilled to 2.4 km in NE Alberta.  The profile of breakout orientations inferred from image and caliper logs exhibits a distinct rotation in breakout orientations changing from N100°E at 1650-2000m to N173°E at 2000-2210m and, finally, to N145°E at the bottom from 2210-2315m. The deepest measurement is consistent with the many observations in the overlying sediments. The heterogeneous breakout orientations at different depth intervals possibly indicate a heterogeneous in-situ stress field in the Precambrian craton. In addition, however, there is a strong correlation between the metamorphic textures and the breakout orientations suggesting that anisotropic strength may play an important role.  Using a recently developed algorithm we show that these observations can indeed be explained by foliation-controlled failure patterns in such anisotropic metamorphic rocks (Wang & Schmitt, accepted).  Models demonstrate that the observed breakout rotations can be produced under uniform stress orientations with failure slip planes controlled by the textured metamorphic rocks with anisotropic strength. This modeled stress field indicates that the stress field in the Canadian Shield where the far-field SH azimuth is at N50°E and the region is under normal/strike-slip faulting regime, is coupled with that in the overlying sedimentary basin.

How to cite: Wang, W. and Schmitt, D.: Stress characterization in the Canadian Shield: Complexity in stress rotation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5494, https://doi.org/10.5194/egusphere-egu22-5494, 2022.

EGU22-6453 | Presentations | TS1.4

Can we afford fracture pressure uncertainty? Limit tests as a key calibration for geomechanical models 

Michał Kępiński, David Wiprut, and Pramit Basu

The Leak-Off Test (LOT) is one of the most common fracture pressure/Shmin calibration measurements conducted in wellbores. Well engineers rely on readings from LOTs to design safe drilling plans. The LOT results indicate the maximum mud weight or equivalent circulating density that can be used to drill the next hole section without causing fluid losses to the formation. Losses are one of the most expensive issues to mitigate in drilling operations. In more severe cases, losses may lead to subsequent drilling challenges such as hole collapse or kicks. Oftentimes, drillers choose not to pressurize the well up to the leak-off pressure due to the risk of weakening the rock beneath the casing shoe by creating a fracture. In these cases, a formation integrity test (FIT) is conducted. However, the FIT is inadequate for properly constraining the fracture gradient or for input to geomechanical models because it is possible for the FIT to terminate at pressures that are either above or below the far-field minimum stress.

Geomechanical modelling from several projects in Poland shows that insufficient LOT measurements introduce a wide range of fracture gradient uncertainty, complicating the analysis of optimal ECD values in narrow margin drilling sections. This leads to difficulty in determining the proper mud weight when a loss event occurs. Additionally, without reliable calibration of the minimum horizontal stress, the geomechanical model used to determine the lower bound of the mud window becomes more uncertain. An inadequately constrained mud window can result in further drilling complications such as tight hole, stuck pipe, poor hole condition, and compromised log quality.

How to cite: Kępiński, M., Wiprut, D., and Basu, P.: Can we afford fracture pressure uncertainty? Limit tests as a key calibration for geomechanical models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6453, https://doi.org/10.5194/egusphere-egu22-6453, 2022.

EGU22-8802 | Presentations | TS1.4

Stress state and patterns at the upper plate of Hikurangi Subduction Margin 

Effat Behboudi, David McNamara, and Ivan Lokmer

Quantifying the contemporary stress state of the Earth’s crust is critical for developing a geomechanical understanding of the behavior of brittle deformation (fractures and faults).In this study we characterize the shallow contemporary stress state of the active Hikurangi Subduction Margin (HSM), New Zealand, to better understand how it affects and responds to variable deformation and slip behavior documented along this plate boundary. The HSM is characterized by along-strike variations in megathrust slip behavior, ranging from shallow slow slip events (SSEs) and creep at the northern and central HSM to interseismic locking and stress accumulation in the southern HSM. We estimate the state of stress across the HSM utilizing rock strength estimates from empirical relationships, leak-off test data, wireline logs and borehole geology, and measurement of borehole wall failures such as borehole breakouts and drilling‐induced tensile fractures from eight boreholes. Stress magnitude constraints at depth intervals where BOs are observed indicate that the maximum principal stress (σ1) is horizontal along the shallow (<3 km) HSM and the stress state is predominantly strike-slip or contractional (barring localized areas where an extensional stress state is determined). Our results reveal a NE-SW (margin-parallel) SHmax orientation in the shallow central HSM, which rotates to a WNW- ESE/NW-SE (margin-perpendicular) SHmax orientation in the shallow southern HSM. The central NE-SW SHmax orientation is inconsistent with active, km-scale, NE-SW striking contractional faults observed across the central HSM. Considering both stress magnitude and orientation patterns at the central HSM, we suggest that long-term clockwise rotation of the Hikurangi forearc, over time, may transform motion on these km-scale central HSM faults from contractional dip-slip to a more contemporary strike/oblique-slip. The southern shallow WNW- ESE/NW-SE SHmax orientation is nearly perpendicular to focal-mechanisms derived NE-SW SHmax orientations within the subducting slab. This, combined with observed strike-slip and contractional faulting in the region and the NW-SE convergence direction, implies the overriding plate in the southern HSM is in a contractional stress state, potentially as deep as the plate interface, which is decoupled from that experienced in the subducting slab. Observed localized extensional stress states across the HSM may occur as a result of local extensions or reflect uncertainties in our estimations of SHmax magnitude which are sensitive to the UCS values used (unconstrained by laboratory testing). This UCS uncertainty and the potential errors it can introduce into a stress model highlights the importance of developing robust empirical relationships for UCS in regions where stress is a critical geological consideration for hazard and resource management.

How to cite: Behboudi, E., McNamara, D., and Lokmer, I.: Stress state and patterns at the upper plate of Hikurangi Subduction Margin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8802, https://doi.org/10.5194/egusphere-egu22-8802, 2022.

A series of numerical simulations of mantle convection in 3D spherical-shell geometry were performed to evaluate the intraplate stress regime from numerically obtained velocity and stress fields. The intraplate stress regime was quantitatively classified into nine types by analyzing the principal deviatoric stress axes and the “stress ratio,” which is a continuous parameter accounting for the stress regimes. From the viewpoint of global geodynamics, this study analyzed the depth profile of the stress ratio across the entire depth of the mantle. The results demonstrated that the radial viscosity structure of the mantle interior strongly affected intraplate stress regimes, and the combination of increased viscosity in the lower mantle and the low-viscosity asthenosphere enhanced the pure strike-slip faulting regime within moving plates as indicated using visco-plastic rheology. The temporally averaged toroidal-poloidal ratio (T/P ratio) at the top surface of mantle convection with surface plate-like motion and the mantle’s viscosity stratification may be comparable to the observed T/P ratio of present-day and past Earth. The normal faulting (or strike-slip) regime with a strike-slip (or normal faulting) component, as well as the pure strike-slip faulting regime, were broadly found in the stable parts of the plate interiors. However, the significant dominance of these stress regimes was not observed in the depth profile of the toroidal-poloidal ratio as a remarkable peak magnitude near the top surface of the lithosphere. This result implies that the strike-slip component analyzed in this study does not directly relate to the formation of strike-slip faults that are infinitely narrow plate boundaries compared with the finite low-viscosity boundary obtained from a mantle convection model with visco-plastic rheology. Nonetheless, this first analysis of the stress ratio may contribute to an improved understanding of the intraplate stress reproduced by future numerical studies of mantle convection with further realistic conditions.

How to cite: Yoshida, M.: New analyses of the stress ratio and stress regime in the Earth’s lithosphere from numerical simulation models of global mantle convection, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9132, https://doi.org/10.5194/egusphere-egu22-9132, 2022.

EGU22-11827 | Presentations | TS1.4

A kinematic model for observed surface subsidence above a salt cavern gas storage site in Northern Germany 

Henriette Sudhaus, Alison Larissa Seidel, and Noemi Schulze-Glanert

In nation-wide radar satellite time series data of Germany, a linear subsidence motion of several kilometer spatial wavelength shows up south-east of Kiel, northern Germany. The center region of this signal, showing line-of-sight displacement velocities of about 2 mm/a, coincides with the facilities of a gas storage site managing two in-service and one out-of-service caverns in the salt dome beneath. The three caverns have been water-drilled only a few hundred meters apart in 1971, 1996 and 2014 into a large halite salt dome, which has risen up there to depths of around 1000 m. Their sizes range within a couple of 100.000 m³. Above the salt body thick deposits of mainly chalk, silk and claystone below layers of clays, silts, sands and glacial marls in the upper 200 m form a relatively strong roof layer.

We hypothesize that despite a thick and competent cover layer, the long-term ductile behavior of halite, which evidently causes shrinking of the cavern volumes through time, results in the observed continuous surface subsidence across several square kilometers. We present an attempt to test the hypothesis by optimizing a simple kinematic model to fit the surface subsidence signal. Using equivalent body forces to represent an isotropic volume point source embedded in a viscoelastic host medium below a horizontally layered elastic roof medium, we estimate the horizontal position of a single cavern, its depth and the corresponding volume change at the cavern. The medium properties at the cavern sites are well known from borehole geophysical analyses, but likely vary strongly laterally. We use InSAR time series data from two ascending look directions and two descending.

Our results show that a cavern at about 1200 m depth and in very close proximity to above-ground facilities of the storage site can indeed be associated with the observed ground motion. The best-fit models pin the location to the known positions, also in depth. The estimated volume loss is slightly larger than 20.000 m³ per year and is in the same order of volume loss estimated from volume measurements inside the actual caverns.

The model approach we present, a single kinematic point source for three caverns and a one-dimensional medium model, is simple, the signal-to-noise ratio of the satellite data is rather small and furthermore there are considerable spatial gaps in the InSAR time series data in areas of agriculture and forests. However, with a computationally fast forward calculation of surface displacements we can afford to propagate data error statistics that account for spatially correlated errors to model parameter uncertainty estimates in a Bayesian way through model ensembles. We plan to add modeling errors of the medium to better grasp their potential influence on the volume loss estimations. The optimization code we use, Grond, is part of the seismological open-source software toolbox Pyrocko (pyrocko.org). The data is openly available at bodenbewegungsdienst.bgr.de.

How to cite: Sudhaus, H., Seidel, A. L., and Schulze-Glanert, N.: A kinematic model for observed surface subsidence above a salt cavern gas storage site in Northern Germany, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11827, https://doi.org/10.5194/egusphere-egu22-11827, 2022.

EGU22-11830 | Presentations | TS1.4

Geomechanical explanation of the Enguri power tunnel leakage 

Thomas Niederhuber, Birgit Müller, Thomas Röckel, Mirian Kalabegishvili, Frank Schilling, and Bernd Aberle

The Enguri Dam (Georgia) is one of the highest arch dams in the world, located at Enguri river in the Greater Caucasus. A 15 km long pressure tunnel with a slope of 1.1 % connects the reservoir to the power station. The tunnel was initially flooded in 1978 and takes a flow rate of up to 450 m³/s. Annual water level changes in the reservoir reach 100 m and generate variable internal water pressure, which places a considerable and dynamic strain on the structure. Water losses of more than 10 m³/s required extensive rehabilitation work in 2021.

The pressure tunnel is lined by upper and lower concrete parts separated by longitudinal construction joints. During the rehabilitation in spring 2021, an approximately 40 m long section of a construction joint with a gaping fissure and several smaller cracks were located.

To explain why only one of the construction joints was leaking, we combined field observations with numerical modelling of the stress state around the pressure tunnel. To infer the regional tectonic stress field various stress indicators have been used like borehole observations (borehole televiewer data) in the field, hydraulic fracturing and earthquake focal mechanisms. These different methods provide mean values with standard deviations. This enabled the estimation of uncertainties in the model input data (field data).

Our approach is based on a static linear-elastic 2D model of the tunnel at km 13.7 within a limestone of homogeneous material properties. The orientation of the profile section is parallel to the regional maximum horizontal stress (SH), which corresponds to maximum principal stress in a thrust faulting regime. SV is the vertical stress. To account for uncertainties, the model was calculated for different stress state scenarios e.g. variation of SH/SV-ratio from 2 to 6 and internal pressure from 0 to 1.6 MPa.

The results show a symmetrical distribution of tensile and compressive stresses around the tunnel, with the axis of symmetry tilted by ca. 30° clockwise (in flow direction) for all scenarios. This is due to the high topography. Therefore, in some calculations, tangential tensile stresses are observed on the downslope side in the region of the construction joint, while compressive stresses are expected for the upslope construction joint.

Therefore, it can be concluded:

(A) the initial stress state is an important parameter for the positioning of underground installation like pressure tunnels especially in areas of high topography.

(B) geomechanical numerical modelling can help to design and dimension safe constructions.

These kinds of investigations can help to omit leakage which can lead to a reduction of the capacity of the power plant and to prolongate the integrity of the tunnel statics. Further investigations could consider the hydraulic situation of the karst rock in the surrounding of the tunnel.

How to cite: Niederhuber, T., Müller, B., Röckel, T., Kalabegishvili, M., Schilling, F., and Aberle, B.: Geomechanical explanation of the Enguri power tunnel leakage, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11830, https://doi.org/10.5194/egusphere-egu22-11830, 2022.

EGU22-11879 | Presentations | TS1.4

Optimizing the use of InSAR observations in data assimilation problems to estimate reservoir compaction 

Samantha S.R. Kim, Femke C. Vossepoel, Marius C. Wouters, Rob Govers, Wietske S. Brouwer, and Ramon F. Hanssen

Hydrocarbon production may cause subsidence as a result of the pressure reduction in the gas-producing layer and reservoir compaction. To analyze the process of subsidence and estimate reservoir parameters, we use a particle method to assimilate Interferometric synthetic-aperture radar (InSAR) observations of surface deformation with a conceptual model of reservoir. As example, we use an analytical model of the Groningen gas reservoir based on a geometry representing the compartmentalized structure of the subsurface at the reservoir depth.

The efficacy of the particle method becomes less when the degree of freedom is large compared to the ensemble size. This degree of freedom, in turn, varies because of spatial correlation in the observed field. The resolution of the InSAR data and the number of observations affect the performance of the particle method.

In this study, we quantify the information in a Sentinel-1 SAR dataset using the concept of Shannon entropy from information theory. We investigate how to best capture the level of detail in model resolved by the InSAR data while maximizing their information content for a data assimilation use. We show that incorrect representation of the existing correlations leads to weight collapse when the number of observation increases, unless the ensemble size growths. However, simulations of mutual information show that we could optimize data reduction by choosing an adequate mesh given the spatial correlation in the observed subsidence. Our approach provides a means to achieve a better information use from available InSAR data reducing weight collapse without additional computational cost.

How to cite: Kim, S. S. R., Vossepoel, F. C., Wouters, M. C., Govers, R., Brouwer, W. S., and Hanssen, R. F.: Optimizing the use of InSAR observations in data assimilation problems to estimate reservoir compaction, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11879, https://doi.org/10.5194/egusphere-egu22-11879, 2022.

EGU22-640 | Presentations | SSP1.2

DeepStor-1 exploration well at KIT Campus North (Upper Rhine Graben, Germany) 

Schill Eva, Florian Bauer, Ulrich Steiner, Bernd Frieg, and Thomas Kohl

DeepStor-1 is the exploration well to the Helmholtz research infrastructure "DeepStor". DeepStor focuses on the investigation of high-temperature heat storage at the rim of the fromer oil-field „Leopoldshafen“. It is located about 10 km north of the city of Karlsruhe (Germany). The DeepStor-1 well is planned to reach the Pechelbronn group at 1‘460 m, i.e. it includes nearly the entire Oligocene sediments at the site. Seismic investigation reveal a structurally undisturbed section that below 200 m depth covers the Landau, Bruchsal, Niederrödern and Froidefontaine Formations. Cores will be taken from the entire section below 820 m. In addition to coring, the logging program is planned to include besides technical logging, a caliper-, self-potential-, temperature-, dual latero-, natural gamma spectrometry-, neutron-gamma porosity-, sonic-, elemental capture spectroscopy-, as well as image-logs in the sections 215-820 m as well as 820-1460 m. Drilling of DeepStor-1 is planned between 2022 and 2023.

How to cite: Eva, S., Bauer, F., Steiner, U., Frieg, B., and Kohl, T.: DeepStor-1 exploration well at KIT Campus North (Upper Rhine Graben, Germany), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-640, https://doi.org/10.5194/egusphere-egu22-640, 2022.

EGU22-1019 | Presentations | SSP1.2

Dating the serpentinite mud production of Fantangisña seamount using calcareous nannofossils and planktonic foraminifera biostratigraphy (IODP Expedition 366). 

Arianna Valentina Del Gaudio, Werner E. Piller, Gerald Auer, and Walter Kurz

The Izu-Bonin Mariana (IBM) convergent margin is located in the NW Pacific Ocean (12° N to 35° N) and represents, to the best of our knowledge, the only setting where recent episodes of serpentinite mud volcanism took place. The IBM arc-system started to form around 50-52 Ma when the Pacific Plate began to subside below the Philippine Plate and the eastern Eurasian Margin. On the Mariana forearc system, which constitutes the southward region of the IBM, a high number of large serpentinite mud volcanoes formed between the trench and the Mariana volcanic arc. Their origin is linked to episodic extrusion of serpentinite mud and fluids along with materials from the upper mantle, the Philippine plate, and the subducting Pacific plate to the sea floor, through a system of forearc faults. Among them, Fantangisña seamount was drilled during IODP Expedition 366. Cored material comprises serpentinite mud and ultramafic clasts that are underlain by nannofossil-rich forearc deposits and topped by pelagic sediments.

Integrated calcareous nannofossil and planktonic foraminifera biostratigraphy was performed on Sites U1497 and U1498, which are at the top of the serpentinite seamount and on its most stable southern flank, respectively. A total of nine bioevents were recorded in this study, permitting the establishment of a valid age-depth model for Site U1498A which allows for the definition of the latest phase of activity of Fantangisña serpentinite mud volcano. In particular, the emplacement of the mud production was detected between 6.10 (Late Miocene, Messinian) to 4.20 (Early Pliocene, Zanclean). This time interval is defined by nannofossil bioevents LO Reticulofenestra rotaria and FO of Discoaster asymmetricus. Furthermore, our analyses reveal that the latest stage of the serpentinite mud activity occurred 4 Ma later than the age proposed by a previous study (10.77 Ma) and is coeval with the initiation of the rifting in the Mariana Trough recorded at 7-6 Ma.

The age depth model also shows a rapid shift in sedimentation rates (11.80 to 94.71 m/Myr) during the Middle Pleistocene, which corresponds to a change in deposition of distinct serpentinite mud units, likely associated with the regional tectonic activity (different stages of seamount accretion and subduction and/or changes in the forearc extension related to the slab rollback).

How to cite: Del Gaudio, A. V., Piller, W. E., Auer, G., and Kurz, W.: Dating the serpentinite mud production of Fantangisña seamount using calcareous nannofossils and planktonic foraminifera biostratigraphy (IODP Expedition 366)., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1019, https://doi.org/10.5194/egusphere-egu22-1019, 2022.

EGU22-1277 | Presentations | SSP1.2 | Highlight

The Cenozoic Arctic Climate and Sea Ice History - Scientific objectives, challenges and implementation update of IODP Expedition 377 (ArcOP) 

Ruediger Stein, Kristen St.John, and Jeremy Everest

The Arctic is both a contributor to climate change and a region that is most affected by global warming. Despite this global importance, the Arctic Ocean is the last major region on Earth where the long-term climate history remains poorly known. Major advances in understanding were achieved in 2004 with the successful completion of IODP Expedition 302: Arctic Coring Expedition – ACEX – implemented by ECORD, marking the start of a new era in Arctic climate exploration. Although the ACEX results were unprecedented, key questions related to the Cenozoic Arctic climate history remain unanswered, largely due to a major mid-Cenozoic hiatus (or condensed interval) and partly to the poor recovery of the ACEX record. Building on ACEX and its cutting-edge science, IODP Expedition 377: Arctic Ocean Paleoceanography (ArcOP) has been scheduled for mid-August to mid-October 2022. The overall goal of ArcOP is the recovery of a complete stratigraphic sedimentary record on the southern Lomonosov Ridge to meet the highest priority paleoceanographic objective: the continuous long-term Cenozoic Arctic Ocean climate history with its transition from the early Cenozoic Greenhouse world to the late Cenozoic Icehouse world. Furthermore, sedimentation rates two to four times higher than those of ACEX will permit higher-resolution studies of Arctic climate change in the Neogene and Pleistocene. Key objectives are related to the reconstruction of the history of circum-Arctic ice-sheets, sea-ice cover, Siberian river discharge, and deep-water circulation and ventilation and its significance within the global climate system. Obtaining a geologic record of a 50-60 million year time span will provide opportunities to examine trends, pat­terns, rates, causes, and consequences of climate change that are important and relevant to our future. This goal can be achieved through (i) careful site selection, (ii) the use of appropriate drilling technology and ice management, and (iii) applying multi-proxy approaches to paleoceanographic, paleoclimatic, and age-model reconstructions.

In August 2022, a fleet of three ships, the drilling vessel “Dina Polaris” and the powerful icebreakers “Oden” and “Viktor Chernomyrdin”, will set sail for a location on Lomonosov Ridge in international waters far from shore (81°N, 140°E; 800-900 m of water depth). There, the expedition will complete one primary deep drill site (LR-11B) to 900 meters below seafloor (mbsf) which is twice that of the ACEX drill depth – certainly a challenging approach. Based on detailed site survey data, about 230 m of Plio‐Pleistocene, 460 m of Miocene, and >200 m of Oligocene‐Eocene sedimentary sequences might be recovered at this site. In addition, a short drill site (LR-10B) to 50 mbsf will be supplemented to recover an undisturbed uppermost (Quaternary) sedimentary section to ensure complete recovery for construction of a composite section spanning the full age range through the Cenozoic.

In this talk, background information, scientific objectives and an update of the status of planning and implementation of the ArcOP Expedition will be presented. For further details we refer to the ArcOP Scientific Prospectus (https://doi.org/10.14379/iodp.sp.377.2021).

How to cite: Stein, R., St.John, K., and Everest, J.: The Cenozoic Arctic Climate and Sea Ice History - Scientific objectives, challenges and implementation update of IODP Expedition 377 (ArcOP), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1277, https://doi.org/10.5194/egusphere-egu22-1277, 2022.

EGU22-1509 | Presentations | SSP1.2 | Highlight

A Campaign of Scientific Drilling for Monsoon Exploration in the Asian Marginal Seas 

Peter Clift, Christian Betzler, Steven Clemens, Beth Christensen, Gregor Eberli, Christian France-Lanord, Stephen Gallagher, Ann Holbourn, Wolfgang Kuhnt, Richard Murray, Yair Rosenthal, Ryuji Tada, and Shiming Wan

International Ocean Discovery Program (IODP) conducted a series of expeditions between 2014 and 2016 that were designed to address the development of monsoon climate systems in Asia and Australia. Significant progress was made in recovering Neogene sections spanning the region from the Arabian Sea to the Japan Sea and south to western Australia. High recovery by advanced piston core (APC) technology has provided a host of semi-continuous sections that have been used to examine monsoonal evolution. Use of half APC was successful in sampling sand-rich sediment in Indian Ocean submarine fans. The records show that humidity and seasonality developed diachronously across the region, although most regions show drying since the middle Miocene and especially since ~4 Ma, likely linked to global cooling. The transition from C3 to C4 vegetation often accompanied the drying, but may be more linked to global cooling. Western Australia, and possibly southern China diverge from the general trend in becoming wetter during the late Miocene, with the Australian monsoon being more affected by the Indonesian Throughflow, while the Asian Monsoon is tied more to the rising Himalaya in South Asia and to the Tibetan Plateau in East Asia. The monsoon shows sensitivity to orbital forcing, with many regions having a weaker summer monsoon during times of Northern Hemispheric Glaciation. Stronger monsoons are associated with faster continental erosion, but not weathering intensity, which either shows no trend or decreasing strength since the middle Miocene in Asia. Marine productivity proxies and terrestrial environmental proxies are often seen to diverge. Future work on the almost unknown Paleogene is highlighted, as well as the potential of carbonate platforms as archives of paleoceanographic conditions.

How to cite: Clift, P., Betzler, C., Clemens, S., Christensen, B., Eberli, G., France-Lanord, C., Gallagher, S., Holbourn, A., Kuhnt, W., Murray, R., Rosenthal, Y., Tada, R., and Wan, S.: A Campaign of Scientific Drilling for Monsoon Exploration in the Asian Marginal Seas, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1509, https://doi.org/10.5194/egusphere-egu22-1509, 2022.

EGU22-1679 | Presentations | SSP1.2

Direct evidence of high pore pressure at the toe of the Nankai accretionary prism 

Joshua Pwavodi and Mai-Linh Doan

The Nankai Trough is a locus of slow slip, low frequency earthquakes and Mw>8 classical earthquakes. It is assumed that high pore pressure contributes substantially to earthquake dynamics. Hence, a full understanding of the hydraulic regime of the Nankai accretionary prism is needed to understand this diversity of behaviors. We contribute to this understanding by innovatively integrating the drilling and logging data of the NanTroSEIZE project. We focus on the toe of the accretionary prism by studying data from Hole C0024A drilled and intersected the décollement at 813 mbsf about 3km away from the trench.

Down Hole Annular Pressure was monitored during drilling. We perform a careful quantitative reanalysis of its variation and show localized fluid exchange between the formation and the borehole (excess of 0.05m3/s), especially in the damage zones at the footwall of the décollement.

Pore pressure was estimated using Eaton’s method on both drilling and sonic velocity data. The formation fluids are getting significantly over-pressurized only a few hundred meters from the toe of the accretionary prism near the décollement with excess pore-pressure (P*≈0.04–4.79MPa) and lithostatic load (λ≈88-0.96 & λ*≈0.1-0.62 ) contributing to maximum 62% of the overburden stress.

The hydraulic profile suggests that the plate boundary acts as a barrier inhibiting upward fluid convection, as well as a lateral channel along the damage zone, favouring high pore pressure at the footwall. Such high pressure at the toe of the subsection zone makes high pressure probable further down in the locus of tremors and slow slip events.

How to cite: Pwavodi, J. and Doan, M.-L.: Direct evidence of high pore pressure at the toe of the Nankai accretionary prism, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1679, https://doi.org/10.5194/egusphere-egu22-1679, 2022.

EGU22-1729 | Presentations | SSP1.2

IODP Expedition 386 “Japan Trench Paleoseismology”: Mission Specific Platform Giant Piston Coring to track past megathrust earthquakes and their consequences in a deep-sea subduction trench. 

Michael Strasser, Ken Ikehara, Jeremy Everest, and Lena Maeda and the IODP Expedition 386 Science Party

International Ocean Discovery Program (IODP) Expedition 386, Japan Trench Paleoseismology (offshore period: 13 April to 1 June 2021; Onshore Science Party: 14 February to 14 March 2022) was designed to test the concept of submarine paleoseismology in the Japan Trench, the area where the last, and globally only one out of four instrumentally-recorded, giant (i.e. magnitude 9 class) earthquake occurred back in 2011. “Submarine paleoseismology” is a promising approach to investigate deposits from the deep sea, where earthquakes leave traces preserved in the stratigraphic succession, to reconstruct the long-term history of earthquakes and to deliver observational data that help to reduce uncertainties in seismic hazard assessment for long return periods. This expedition marks the first time, giant piston coring (GPC) was used in IODP, and also the first time, partner IODP implementing organizations cooperated in jointly implementing a mission-specific platform expedition.

We successfully collected 29 GPCs at 15 sites (1 to 3 holes each; total core recovery 831 meters), recovering 20 to 40-meter-long, continuous, upper Pleistocene to Holocene stratigraphic successions of 11 individual trench-fill basins along an axis-parallel transect from 36°N – 40.4°N, at water depth between 7445-8023 m below sea level. These offshore expedition achievements reveal the first high-temporal and high spatial resolution investigation and sampling of a hadal oceanic trench, that form the deepest and least explored environments on our planet.

The cores are currently being examined by multimethod applications to characterize and date hadal trench sediments and extreme event deposits, for which the detailed sedimentological, physical and (bio-)geochemical features, stratigraphic expressions and spatiotemporal distribution will be analyzed for proxy evidence of giant earthquakes and (bio-)geochemical cycling in deep sea sediments. Initial preliminary results presented in this EGU presentation reveal event-stratigraphic successions comprising several 10s of potentially giant-earthquake related event beds, revealing a fascinating record that will unravel the earthquake history of the different along-strike segments that is 10–100 times longer than currently available information. Post-Expedition research projects further analyzing these initial IODP data sets will (i) enable statistically robust assessment of the recurrence patterns of giant earthquakes, there while advancing our understanding of earthquake-induced geohazards along subduction zones and (ii) provide new constraints on sediment and carbon flux of event-triggered sediment mobilization to a deep-sea trench and its influence on the hadal environment.

 

How to cite: Strasser, M., Ikehara, K., Everest, J., and Maeda, L. and the IODP Expedition 386 Science Party: IODP Expedition 386 “Japan Trench Paleoseismology”: Mission Specific Platform Giant Piston Coring to track past megathrust earthquakes and their consequences in a deep-sea subduction trench., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1729, https://doi.org/10.5194/egusphere-egu22-1729, 2022.

EGU22-1917 | Presentations | SSP1.2

Operations and Initial Results from IODP Expedition 396: Mid-Norwegian Continental Margin Magmatism and Paleoclimate 

Sverre Planke, Christian Berndt, Ritske Huismans, Stefan Buenz, Carlos A. Alvarez Zarikian, and Expedition Scientists

The NE Atlantic conjugate volcanic rifted margins are characterized by extensive breakup-related magmatism recorded by basalt flows, volcanogenic sediments, magmatic underplates, and intrusive complexes in sedimentary basins and the crust. Onset of this voluminous magmatism is concomitant with the global hot-house climate in the Paleogene, and the injection of magma into organic-rich sedimentary basins is a proposed mechanism for triggering short-term global warming during the Paleocene-Eocene Thermal Maximum (PETM, ~56 Ma).

The aims of IODP Exp. 396 (August-September 2021) were to drill three transects on the mid-Norwegian continental margin to sample 1) hydrothermal vent complexes formed by eruption of hot fluids and sediments above sill intrusions (Modgunn Transect), 2) Paleogene sediments, with particular focus on the Paleocene-Eocene transition (Mimir Transect), and 3) basalt and sub-basalt sequences across the volcanic rifted margin and the initial oceanic crust (Basement Transect). A total of 21 boreholes were drilled, successfully coring all nine primary and one alternate sites. A comprehensive suite of wireline logs was collected in eight boreholes. Most of the sites were located on industry-standard 3D seismic reflection data, whereas additional high-resolution 2D and 3D P-Cable site survey data were acquired across six sites which were highly useful during the Mimir and Modgunn transect drilling. In total, more than 2000 m of core were recovered during 48 days of operations, including more than 350 m of basalt, 15 m of granite, and 900 m of late Paleocene to early Eocene sediments. Drilling was done using a combination of RCB, XCB, and APC drill bits, commonly with half-advances (c. 5 m) to optimize core recovery. Particularly high recovery (almost 100%) was obtained by half-length APC coring of Eocene sediments in two holes on the outer Vøring Margin, whereas basaltic basement recovery was above 60% in seven holes.

Expedition 396 probed the key elements of a typical volcanic rifted margin and the associated sedimentary archive. Of particular importance is the Modgunn Transect, where we drilled five holes through the upper part of a hydrothermal vent complex with a very expanded Paleocene-Eocene Thermal Maximum (PETM) interval dominated by biogenic ooze and volcanic ash deposits. The expedition also recovered an unprecedented suite of basalt cores across a volcanic rifted margin, including both subaerial and deep marine sheet flows with inter-lava sediments and spectacular shallow marine pillow basalts and hyaloclastites, as well as high-resolution interstitial water samples to assess sediment diagenesis and fluid migration in the region. Lastly, we recovered the first cores of sub-basalt granitic igneous rocks and upper Paleocene sediments along the mid-Norwegian continental margin. Collectively, this unique sample archive offers unprecedented insight on tectonomagmatic processes in the NE Atlantic, and links to rapid climate evolution across the Cenozoic.

How to cite: Planke, S., Berndt, C., Huismans, R., Buenz, S., Alvarez Zarikian, C. A., and Scientists, E.: Operations and Initial Results from IODP Expedition 396: Mid-Norwegian Continental Margin Magmatism and Paleoclimate, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1917, https://doi.org/10.5194/egusphere-egu22-1917, 2022.

EGU22-2525 | Presentations | SSP1.2

Biological sulfate reduction in deep subseafloor sediment of Guaymas Basin 

Toshiki Nagakura, Florian Schubert, and Jens Kallmeyer and the IODP Exp. 385 Scientists

Sulfate reduction is the quantitatively most important process to degrade organic matter in anoxic marine sediment and has been studied intensively in a variety of settings. Guaymas Basin, a young marginal ocean basin, offers the unique opportunity to study sulfate reduction in an environment characterized by organic-rich sediment, high sedimentation rates, and high geothermal gradients (100-958°C km-1). We measured sulfate reduction rates (SRR) in samples of the International Ocean Discovery Program (IODP) Expedition 385 using incubation experiments with radiolabeled 35SO42- carried out at in-situ pressure and temperature. Site U1548C, outside of a circular hydrothermal mound above a hot sill intrusion (Ringvent), has the highest geothermal gradient (958°C km-1) of all eight sampling sites. In near-surface sediment from this site, we measured the highest SRR (387 nmol cm-3 d-1) of all samples from this expedition. At Site U1548C SRR were generally over an order of magnitude higher than at similar depths at other sites. Site U1546D also had a sill intrusion, but it had already reached thermal equilibrium and SRR were in the same range as nearby Site U1545C, which is minimally affected by sills. The wide temperature range found in the stratigraphic section at each drill site leads to major shifts in microbial community composition with very different temperature optima. At the transition between the mesophilic and thermophilic range around 40 to 60°C, sulfate-reducing activity appears to be decreased, particularly in more oligotrophic settings but shows a slight recovery at higher temperatures.

How to cite: Nagakura, T., Schubert, F., and Kallmeyer, J. and the IODP Exp. 385 Scientists: Biological sulfate reduction in deep subseafloor sediment of Guaymas Basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2525, https://doi.org/10.5194/egusphere-egu22-2525, 2022.

EGU22-2909 | Presentations | SSP1.2 | Highlight

Microbial survival through high metabolic rates in a deep and hot subseafloor environment 

Florian Schubert, Felix Beulig, Rishi Ram Adhikari, Clemens Glombitza, Verena Heuer, Kai-Uwe Hinrichs, Kira Homola, Fumio Inagaki, Bo Barker Jørgensen, Jens Kallmeyer, Sebastian Krause, Yuki Morono, Justine Sauvage, Arthur Spivack, and Tina Treude

A fourth of the global seabed sediment volume is buried at depths where temperatures exceed 80 °C, a previously proposed thermal barrier for life in the subsurface. Here, we demonstrate, utilizing an extensive suite of radiotracer experiments, the prevalence of active methanogenic and sulfate-reducing populations in deeply buried marine sediment from the Nankai Trough subduction zone, heated to extreme temperature (up to ~120 °C). Sediment cores were recovered during International Ocean Discovery Program (IODP) Expedition 370 to Nankai Trough, off the cost of Moroto, Japan. The steep geothermal gradient of ~100 °C km-1 allowed for the exploration of most of the known temperature range for life over just 1 km of drill core. Despite the high temperatures, microbial cells were detected almost throughout the entire sediment column, albeit at extremely low concentration of <500 cells per cm³ in sediment above ~50 °C. In millions of years old sediment a small microbial community subsisted with high potential cell-specific rates of energy metabolism, which approach the rates of active surface sediments and laboratory cultures. Even under the most conservative assumptions, potential biomass turnover times for the recovered sediment ranges from days to years and therefore many orders of magnitude faster than in colder deep sediment.

Our discovery is in stark contrast to the extremely low metabolic rates otherwise observed in the deep subseafloor. As cells appear to invest most of their energy to repair thermal cell damage in the hot sediment, they are forced to balance delicately between subsistence near the upper temperature limit for life and a rich supply of substrates and energy from thermally driven reactions of the sediment organic matter.

How to cite: Schubert, F., Beulig, F., Adhikari, R. R., Glombitza, C., Heuer, V., Hinrichs, K.-U., Homola, K., Inagaki, F., Jørgensen, B. B., Kallmeyer, J., Krause, S., Morono, Y., Sauvage, J., Spivack, A., and Treude, T.: Microbial survival through high metabolic rates in a deep and hot subseafloor environment, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2909, https://doi.org/10.5194/egusphere-egu22-2909, 2022.

EGU22-3165 | Presentations | SSP1.2 | Highlight

Drilling Overdeepened Alpine Valleys (ICDP-DOVE): Age, extent and environmental impact of Alpine glaciations 

Flavio Anselmetti and Marius Buechi and the ICDP-DOVE Team

The sedimentary infill of glacially overdeepened valleys (i.e. eroded structures below the fluvial base level) are, together with glacial geomorphology, the best-preserved (yet underexplored) direct archives of extents and ages of past glaciations in and around mountain ranges. ICDP project DOVE (Drilling Overdeepened Alpine Valleys) Phase-1 investigates five drill cores from glacially overdeepened structures at several complementing locations along the northern front of the Alps and their foreland. Two of these drill sites, both in the former reaches of the Rhine Glacier, have been successfully drilled in 2021 with excellent core recovery of 95 %: i) The borehole in Basadingen in Northern Switzerland reached a depth of 253 m, and ii) The Tannwald site in Southern Germany consists of one cored borehole to 165 m and two nearby flush boreholes; all three sites will allow a series of crosshole geophysical experiments. Three previously drilled legacy cores from the Eastern Alps are included in the DOVE Phase-1: iii) a core from Schäftlarn, located in the Isar-Loisach glacier catchment, was drilled in 2017 down to a depth of 199 m; iv) the Neusillersdorf drill site, located in the southern German Salzach Foreland glacier area, recovered a sequence down to 136 m (incl. 116 m of Quaternary strata); and v) the drill site Bad Aussee in Austria is located in the area of the Traun Glacier at an inneralpine location. It recovered almost 900 m of Quaternary sediments.

All the sites will be investigated with regard to several aspects of environmental dynamics during the Quaternary, with focus on the glaciation, vegetation, and landscape history. For example, the geometry of overdeepened structures will be investigated using different geophysical approaches (e.g. seismic surveys) to better understand the process of overdeepening. Sedimentological analyses in combination with downhole logging, investigation of biological remains and state-of-the-art geochronological methods will allow to reconstruct the filling and erosion history of the troughs. We expect significant and novel data relating to the extent and timing of the past Alpine glaciations during the Middle-to-Late Quaternary glacial-interglacial cycles. Besides these basic scientific goals, this proposal also addresses a number of applied objectives such as groundwater resources, geothermal energy production, and seismic hazard assessment.

A successful DOVE Phase-1 will lay the ground for an upcoming Phase-2 that will complete the panalpine approach. This follow-up phase will investigate paleoglacier lobes from the western and southern Alpine margins through drilling sites in France, Italy and Slovenia.

How to cite: Anselmetti, F. and Buechi, M. and the ICDP-DOVE Team: Drilling Overdeepened Alpine Valleys (ICDP-DOVE): Age, extent and environmental impact of Alpine glaciations, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3165, https://doi.org/10.5194/egusphere-egu22-3165, 2022.

EGU22-3372 | Presentations | SSP1.2

Re–Os geochemistry of altered dacitic rock at Site U1527, IODP Expedition 376: Implications for the Re cycle in intraoceanic arcs 

Mizuki Ishida, Tatsuo Nozaki, Yutaro Takaya, Junichiro Ohta, Qing Chang, Jun-Ichi Kimura, Kentaro Nakamura, and Yasuhiro Kato

The Re–Os isotopic system is a powerful tool for both geochronology and tracing various geochemical processes. Because the Os isotopic ratio (187Os/188Os) distinctly differs between modern seawater (∼1.06) and hydrothermal fluid (∼0.13), the Re–Os isotopic system is potentially a sensitive tracer of subseafloor fluid flow and the release or uptake of hydrogenous/magmatic Re and Os. The effect of alteration on the Re–Os budget in oceanic crust has been examined for mid-ocean ridge basalt (MORB) and lower oceanic crustal gabbro. In contrast, applications of the Re–Os system in intraoceanic arc settings are limited mainly to fresh igneous rocks; the role of hydrothermal alteration has not yet been examined.

Here, we provide a depth profile of Re–Os geochemistry at Site U1527, located on the NW caldera rim of the Brothers volcano hydrothermal field in the Kermadec arc, which was drilled during International Ocean Discovery Program (IODP) Expedition 376 in 2018. Volcaniclastic rocks from Hole U1527C that had experienced various degrees of high- and low-temperature hydrothermal alteration were analyzed for bulk chemical composition as well as Re–Os concentrations and isotopes. The concentration of Re varied from 0.172 to 18.7 ppb, and that of Os ranges from 9.7 to 147.1 ppt. Hydrothermal alteration usually resulted in the Re uptake by rocks, but a part of Re was released into the ocean by later oxidative weathering. Compared with Re, Os mobility resulting from hydrothermal alteration was limited. Before alteration, our samples likely had homogenous 187Os/188Os of between 0.13 and 0.14, whereas alteration added hydrogenous Os to some drill core sections in two different ways. Elevated 187Os/188Os with Ba enrichment and abundant pyrite occurrence suggests Os precipitation induced by subseafloor mixing of seawater and high-temperature hydrothermal fluid. The highest Re and Os concentrations at Hole U1527C, found in the same interval, were associated with high concentrations of Bi, Sb, and Tl. In contrast, elevated 187Os/188Os without Ba and Os enrichment can be explained by adsorption of seawater-derived radiogenic Os onto Fe hydroxide during seawater ingress into volcaniclastic rocks with a high matrix volume.

Intense Re enrichment at Hole U1527 relative to the high-temperature alteration zone in altered MORB may be related to abundant pyrite precipitation and high Re content in primary arc magmas. We propose that degassed Re from shallow intraoceanic arc magmas may be sequestered by subseafloor high-temperature alteration. Part of the stored Re might also be released into the ocean by later oxidative seawater circulation and seafloor weathering, raising a question about the role of alteration zones in the Re cycle in subduction zones. This study is one of the first attempts to apply the Re–Os system to altered rocks in arc settings, and future research should provide more information about the fate of Re in intraoceanic arcs and the detailed role of hydrothermal alteration in the Re cycle on the Earth.

How to cite: Ishida, M., Nozaki, T., Takaya, Y., Ohta, J., Chang, Q., Kimura, J.-I., Nakamura, K., and Kato, Y.: Re–Os geochemistry of altered dacitic rock at Site U1527, IODP Expedition 376: Implications for the Re cycle in intraoceanic arcs, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3372, https://doi.org/10.5194/egusphere-egu22-3372, 2022.

EGU22-3428 | Presentations | SSP1.2

Hipercorig Hallstatt History (H3) reveals a high-resolution Late Pleistocene to Holocene sediment record at Lake Hallstatt (Salzkammergut, Austria) 

Marcel Ortler, Achim Brauer, Stefano C. Fabbri, Kerstin Kowarik, Jochem Kueck, and Michael Strasser

The innovative, new drilling technique of the Hipercorig platform (Harms et al., 2020, https://doi.org/10.5194/sd-28-29-2020) enables to recover undisturbed long cores of sediment archives, and hence allows us to study past environmental conditions and changes. Here we present initial results from the Hipercorig Hallstatt History (H3) lake drilling campaign 2021, which succeeded to recover two parallel cores (core A: 41m, core B: 51m) from 122 m water depth providing a high-resolution record, within the UNESCO World Heritage Cultural Landscape Hallstatt-Dachstein/Salzkammergut, Austria. The Hallstatt-Dachstein region has a history of over 7,000 years of human salt mining and is one of the oldest documented cultural landscapes worldwide.

We present physical- and litho-stratigraphy based on borehole logging (of hole B), non-destructive core logging data, visual core and lithofacies description, Core-Log-Seismic-Correlation and initial age modelling using 14C dating. The core logging covers (i) x-ray computed tomography, (ii) multi-sensor-core-logger data with Gamma-Ray attenuated bulk density, magnetic susceptibility and visible light photo spectroscopy. The upper ~15 m of the sediment profile can be unambiguously correlated with previous cores (Lauterbach et al., submitted) thus confirming that the sediments are truly representative for Lake Hallstatt. The entire stratigraphic succession comprises two major lithostratigraphic units: The Holocene unit (0-40 m below lake floor (mblf)) and the Late Pleistocene unit (> 40 m). The Holocene unit consists of variably laminated (sub-mm to 5 mm) dark gray clayey-silty carbonate mud interbedded with up to 5.5 m thick mass-movement deposits and thick turbidites. The Late Pleistocene sedimentary succession comprises very thin bedded (1-3 cm) medium gray silty clayey carbonate mud, with some laminated (<1 cm) intervals and multiple cm-thick light gray turbidites. Within the Late Holocene unit, there is a prominent yellowish gray clastic interval of ~4 m with faintly mm- to cm-scale laminated sediments. Another remarkable characteristic of the Holocene unit is the occurrence of at least four major mass-movement deposits containing pebbles (up to 3 cm in diameter) and six thick turbidite deposits >1 m with different sediment colors and compositions.

Detailed multi-proxy analyzes of the Lake Hallstatt cores will provide new insights into the early history of human settlement and salt mining in this Alpine region and their relation to environmental and climatic conditions and meteorological and geological extreme events.

How to cite: Ortler, M., Brauer, A., Fabbri, S. C., Kowarik, K., Kueck, J., and Strasser, M.: Hipercorig Hallstatt History (H3) reveals a high-resolution Late Pleistocene to Holocene sediment record at Lake Hallstatt (Salzkammergut, Austria), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3428, https://doi.org/10.5194/egusphere-egu22-3428, 2022.

EGU22-3534 | Presentations | SSP1.2

Reconstructing the moisture availability of Central Mexico over the past 500,000 years using borehole logging data 

Mehrdad Abadi, Christian Zeeden, Arne Ulfers, and Thomas Wonik

Assessing the moisture history of Central Mexico reveals the responses of tropical areas to variation in past climate. Central Mexico has several long-lived lakes, which are potentially important paleoclimate archives. Lake Chalco in Central Mexico contains a ~300 m lacustrine sequence, which were deposited over a period of ~500,000 years. We conducted Spectral Gamma Ray (SGR) measurements across the lacustrine deposits of Lake Chalco to reconstruct the moisture availability over the past. The SGR data reflect the presence of naturally occurring radioactive elements including potassium (40K) and the equilibrium decay series of uranium (U) and thorium (Th). Natural sources of gamma radiation in lacustrine deposits of Lake Chalco are from volcanic ash deposition and detrital input of eroded sediments containing radioactive elements. However, redox conditions in the lake water influence the mobility of soluble U through conversion to more stable reduced phases. To extract the primary non-volcanic signals, we detected and removed signals from embedded tephra layers in the lacustrine sediments of Lake Chalco. We developed a moisture proxy by calculating the probability of authigenic U distributed across the lake sediments. We expect that an increasing U content in proportion to the content of K and Th indicate redox conditions in lake bottom water as a result of rising lake level. To evaluate this moisture proxy, we examined differences in the percent of the diatom species that are indicative of a deeper lake from literature. Results suggest that Lake Chalco likely formed prior or within MIS13, and the lake level rose gradually over time until the interglacial period of MIS9. Moisture levels are higher during the interglacial than glacial periods and interglacial periods show higher moisture variability. While glacial periods have less moisture, two periods, MIS6 and MIS4, still have a higher likelihood of authigenic U and more moist conditions. In order to determine potential regulators of moisture, we compared models containing the drivers of Earth’s orbital cycles, carbon dioxide and sea surface temperature. Carbon dioxide, eccentricity, and precession are all key drivers of the moisture content of Lake Chalco over the past 500,000 years. High levels of atmospheric CO2 have a positive effect on the moisture in Mexico while eccentricity and precession consistently have negative effects on lake moisture. Obliquity and δ18O have weaker effects on moisture in Mexico, probably due to the equatorial high-altitude region far away from poles, oceans and ice sheets.

How to cite: Abadi, M., Zeeden, C., Ulfers, A., and Wonik, T.: Reconstructing the moisture availability of Central Mexico over the past 500,000 years using borehole logging data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3534, https://doi.org/10.5194/egusphere-egu22-3534, 2022.

EGU22-3538 | Presentations | SSP1.2 | Highlight

Deformation mechanisms along the Main Marmara Fault around the ICDP-site GONAF 

Magdalena Scheck-Wenderoth, Mauro Cacace, Oliver Heidbach, Marco Bohnhoff, Murat Nurlu, Naiara Fernandez Terrones, Judith Bott, and Ershad Gholamrezaie

The Main Marmara Fault (MMF) in NW Turkey south of Istanbul is a segment of the North Anatolian Fault Zone (NAFZ) that constitutes a right-lateral continental transform fault.  Several well-documented strong (M7+) earthquakes indicate that the MMF poses a great risk to the Istanbul metropolitan region. A 150 km long stretch of the MMF has not ruptured since 1766 and the recurrence time of 250 yrs for M7+ events derived from historical records indicate that the fault is overdue. We introduce a new project addressing how the rheological configuration of the lithosphere in concert with active fluid dynamics within the crust and mantle influence the present-day deformation along the MMF in the Marmara Sea region. We test the following hypotheses: (1) the seismic gap is related to the mechanical segmentation along the MMF which originates from the rheological configuration of the crust and lithosphere; (2) variations in deformation mechanisms with depth in response to variations in temperature and (fluid) pressure exert a first-order control on the mode of seismic activity along the MMF, and, (3) stress and strain concentrations due to strength and structural variability along the MMF can be used as an indicator for potential nucleation areas of expected earthquakes. To assess what mechanisms control the deformation along the MMF, we use data from the ICDP GONAF observatory (International Continental Drilling Programme – Geophysical Observatory at the North Anatolian Fault) and a combined work flow of data integration and process modelling to derive a quantitative description of the physical state of the MMF and its surrounding crust and upper mantle. Seismic and strain observations from the ICDP-GONAF site are integrated with regional observations on active seismicity, on the present-day deformation field at the surface, on the deep structure (crust and upper mantle) and on the present-day stress and thermal fields. This will be complemented by numerical forward simulations of coupled thermo-hydraulic-mechanical processes based on the observation-derived 3D models to evaluate the key controlling factors for the present-day mechanical configuration of the MMF and to contribute to a physics-based seismic hazard assessment.

How to cite: Scheck-Wenderoth, M., Cacace, M., Heidbach, O., Bohnhoff, M., Nurlu, M., Fernandez Terrones, N., Bott, J., and Gholamrezaie, E.: Deformation mechanisms along the Main Marmara Fault around the ICDP-site GONAF, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3538, https://doi.org/10.5194/egusphere-egu22-3538, 2022.

EGU22-3793 | Presentations | SSP1.2

Legacy DSDP and ODP data suggest a paradigm shift in methane hydrate stability in the Mediterranean Basin 

Cristina Corradin, Angelo Camerlenghi, Michela Giustiniani, Umberta Tinivella, and Claudia Bertoni

The global reservoir of submarine gas hydrates is favored by the cold temperature of oceanic bottom water and the generally low geothermal gradients along passive continental margins. The continental margins of the land-locked Mediterranean basin are a remarkable exception for the lack of evidence of extensive presence of gas hydrates. Using public data of the physics and chemistry of the subsurface available from 44 Deep Sea Drilling Project (DSDP) and Ocean Drilling Program (ODP) wells as lithologic logs, downhole temperature measurements, and pore water salinity values, and observed physical characteristics of bottom waters, we model the theoretical methane hydrate stability zone (MHSZ) below the seafloor and in the water column.

We find important positive pore water salinity anomalies in the subsurface indicating the pervasive presence of concentrated brines up to saturation concentration of halite and gypsum (> 300 ‰). The resulting sub-bottom MHSZ is thinner by up to 90-95% with respect to its thickness calculated assuming constant salinity with depth equal to bottom waters salinity. In the Eastern Mediterranean deep basins the thickness of the subsurface MHSZ is largest (up to ~ 350 m) and the anomaly induced by subsurface brines is highest (~ -300 m), while in the Alboran, Western Mediterranean, Tyrrhenian, Sicily Channel, Adriatic and Aegean basins the MHSZ, where present, thins to less than 100 m with mostly negligible anomaly induced by the presence of subsurface brines.

Modelling results suggest that subsurface brines can produce dramatic reductions of the thickness of the MHSZ only where the geothermal gradient is low (Eastern Mediterranean). We have modelled the same brine-induced limiting effect on the thickness of the MHSZ in synthetic cases of high and low heat flow to simulate Western and Eastern Mediterranean subsurface thermo-haline conditions. The salinity effect is attenuated by the thermal effect in the Western Mediterranean that produces the most relevant thinning of the MHSZ.

The distribution of the MHSZ resulting from the modelling coincides well with the distribution of the Late Miocene salt deposits which limit further the possibility of formation of gas hydrates acting as low permeability seal to the up-ward migration of hydrocarbon gases.

This modelling exercise provides a robust explanation for the lack of evidence of widespread gas hydrates on Mediterranean continental margins, with the exception of areas of local methane upward advection such as mud volcanoes, and it outlines a number of local hydrate-limiting factors that make this basin unfavorable to gas hydrate occurrence.

How to cite: Corradin, C., Camerlenghi, A., Giustiniani, M., Tinivella, U., and Bertoni, C.: Legacy DSDP and ODP data suggest a paradigm shift in methane hydrate stability in the Mediterranean Basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3793, https://doi.org/10.5194/egusphere-egu22-3793, 2022.

EGU22-4022 | Presentations | SSP1.2 | Highlight

Half-precession signals in marine an terrestrial records – connecting IODP/ICDP sites from the equatorial Atlantic to Greenland 

Arne Ulfers, Christian Zeeden, Silke Voigt, Mehrdad Sardar Abadi, and Thomas Wonik

The characteristics of half-precession (HP) cycles (~9,000 - 12,000 years) is still poorly understood, despite their appearance in numerous records. We analyse HP signals in a variety of different marine and terrestrial proxy records from Europe and the Atlantic Ocean, investigate the temporal evolution of the HP signal from the early/middle Pleistocene to the present, and evaluate the potential of the HP to reflect the connectivity of climate systems over time.

We apply filters on the datasets that remove the classical orbital cycles (eccentricity, obliquity, precession) and high frequency signals, and focus on the bandwidth of HP signals. Wavelet annalysis and correlation techniques are used to study the evolution of specific frequencies through the different records.

In addition to a connection of HP cycles with interglacials, we observe a more pronounced HP signal in the younger part of several proxy records. Besides, we observe a trend of more pronounced HP signals in low latitude records compared to high latitudes. This is in agreement with the assumption that HP is an equatorial signal and can be transmitted northward via various pathways. The appearance of HP signals in mid- and high-latitude records may thus be an indicator for the intensity of the transporting mechanisms. We suggest that the African Monsoon plays a major role in this context, as its magnitude directly influences the climate systems of the Mediterranean and Southern Europe. In order to better understand the African climate variability, both equatorial marine and terrestrial records will be examined with respect to HP.

How to cite: Ulfers, A., Zeeden, C., Voigt, S., Sardar Abadi, M., and Wonik, T.: Half-precession signals in marine an terrestrial records – connecting IODP/ICDP sites from the equatorial Atlantic to Greenland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4022, https://doi.org/10.5194/egusphere-egu22-4022, 2022.

Together with amphibole and garnet, epidote-group minerals are one of the three most important heavy minerals found in orogenic sediments (Garzanti and Andò, 2007). Their chemical composition and optical properties vary markedly with temperature and pressure conditions, and thus provide useful information in provenance analysis on the metamorphic grade of source rocks.

The aim of this study is to devise an efficient and quick method, with micrometric resolution to distinguish among the different species of the epidote group during routine point-counting of heavy-mineral slides, which can be applied on a vast ranges of grain-sizes from fine silt to medium sand.

The geochemical variability of epidote-supergroup minerals from different source rock collected in different sectors of the Alpine orogenic belt was first investigated by coupling Raman Spectroscopy, Scanning Electron Microscopy, and Energy-dispersed X-ray Spectroscopy (SEM-EDS). The geochemical composition, optical properties, and Raman fingerprints of these standard epidote grains were described and in-house database of Raman spectra was created, combining geochemical data and Raman response in the low wavenumbers region and OH stretching bands. A program, written in Matlab® language, has been established which allows to obtain a quick estimate of the amount of iron from the Raman spectra in the clinozoisite-epidote series.

Raman spectra of detrital epidotes contained in turbiditic sediments of the Bengal Fan (IODP Expedition 354) were next compared with Raman spectra of epidote-group standards to determine their composition. The identification and relative amount of detrital epidote, clinozoisite and zoisite in silt- and sand-sized deep-sea sediments contribute to constrain the metamorphic grade of Himalayan source rocks, reconstruct the erosional evolution of the Himalayan orogen, and provide information on climate change and strengthening of the Indian Ocean monsoon throughout the Neogene and Quaternary.

Key words: epidote, provenance, Himalaya, Raman spectroscopy, Microprobe analyses, optical microscope.

Garzanti, E., Andò S., 2007. Plate tectonics and heavy-mineral suites of modern sands. In: Mange, M.A., Wright, D.T. (Eds.), Heavy Minerals in Use, Developments in Sedimentology Series, 58. Elsevier, Amsterdam, pp. 741-763.

How to cite: Limonta, M., Andò, S., Bersani, D., France-Lanord, C., and Garzanti, E.: Raman identification of epidote-group minerals in turbiditic sediments from the Bengal Fan (IODP Exp. 354): a complementary tool to better constrain metamorphic grade of source rocks., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6161, https://doi.org/10.5194/egusphere-egu22-6161, 2022.

A 6-meter drill core from Merensky Reef, Bushveld Complex, South Africa, was scanned in detail with a drill core scanner based on Laser Induced Breakdown Spectroscopy (LIBS). The purpose of the investigation was to visualize variations in the chemical composition along the core, and following a mineral classification of the LIBS data, of variations in the mineral chemical composition, e.g. of Fe/Mg, Cr/Al, and Ca/Na ratios, as well.

The LIBS technology is based on atomic emission spectroscopy, in which the excitation of the atomic species occurs in-situ on the sample surface. The excitation source was a pulsed 50 mJ 1064 nm Nd:YAG laser, and the emitted light was collected with a high-resolution wide-range echelle spectrograph with CCD detector. This approach for measuring mineral chemical ratios such as Mg/Fe, Cr/Al, and Ca/Na, is based on the strength of LIBS in detecting chemical variations using intensity ratios within a single matrix, which in this application is one single particular type of mineral phase. For validation purposes, selected samples were analysed with bulk chemical analysis and electron probe microanalysis as well.

Distinct trends could indeed be extracted from the 6 m core section through the Merensky Reef. From a saw-cut core surface without further preparation, a continuous record could be extracted consisting of Mg/Fe of orthopyroxene, Ca/Na of plagioclase, bulk chemical patterns, modal composition, and direct neighbourhood. The data can be used to highlight the presence of unusual patterns and to relate them to Ni, Cu, PGE or other mineralization. When applied to different core sections, it may become an important tool for comparing lateral variability of diagnostic horizons in vertical sequences in layered intrusions such as Merensky Reef and UG-2.

How to cite: Meima, J., Rammlmair, D., Junge, M., and Nikonow, W.: Continuous measurement of Mg/Fe and Ca/Na ratios with scanning Laser Induced Breakdown Spectroscopy in 6 meter of drill core through Merensky Reef, Bushveld Complex, South Africa, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7513, https://doi.org/10.5194/egusphere-egu22-7513, 2022.

EGU22-8339 | Presentations | SSP1.2

How was the Bushveld Complex assembled? A search for cryptic layering in ICDP drillcores from the Main Zone 

Robert B. Trumbull, Ilya V. Veksler, Wilhelm Nikonov, and Dieter Rammlmair

The Main Zone of the Bushveld Complex in South Africa is the most voluminous but least studied part of the world’s largest igneous intrusion. Modal layering is poorly developed compared with the units above and below (Upper and Critical Zones, resp.), and most of the ca. 3000 meter-thick Main Zone consists of monotonous gabbronorite, occasionally grading into norite and anorthosite. An exception is the ultramafic “Pyroxenite Marker” near the top of the Main Zone, which is present regionally in the complex and represents a major event of magma recharge into the chamber. However, studies of drillcore through the Main Zone in the Bushveld Northern limb (Ashwal et al., 2005; Hayes et al., 2017) found evidence for layering by periodic variations in rock density at vertical length-scales of 40 to 170 m. This implies there were many more episodes of magma recharge than previously thought.

Our study in the Eastern Limb of the complex tests if cryptic layering in the Main Zone is a local phenomenon or is regionally developed like the Pyroxenite Marker. The first step, reported here, was a vertical profile of bulk density data (Archimedes method) for a 1450 m section of the upper Main Zone below the Pyroxenite Marker. Samples were taken at 1 to 5 m intervals and the results show several intervals of density variations at length-scales of 30 to 120 m, comparable to those previously described in the Northern Limb. Periodicity in density changes is not so well developed as in the earlier study, and we identified several 50 to 75 m intervals where density variations are below 0.05 g/cm3. The second step of the study will use multispectral and laser-induced breakdown spectroscopy (LIBS) scanning to provide modal mineralogy profiles of the same drillcore samples used for density measurement. After cryptic modal layering is documented in this way, follow-up petrologic-geochemical studies at the layer boundaries will aim to characterize the composition and temperature of the magmas involved.

For this project the Bushveld Complex Drilling Project (BVDP) provided access to the BH7771 borehole, donated by Impala Platinum’s Marula mine.

References:

Ashwal, L..D., Webb, S.J. and Knoper, M.W. (2005) S. Afr. Jour. Geol., 108, 199-232.

Hayes, B., Ashwal, L.D., Webb, S.J. and Bybee, G.M. (2017) Contrib. Mineral. Petrol., 172, 13.

How to cite: Trumbull, R. B., Veksler, I. V., Nikonov, W., and Rammlmair, D.: How was the Bushveld Complex assembled? A search for cryptic layering in ICDP drillcores from the Main Zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8339, https://doi.org/10.5194/egusphere-egu22-8339, 2022.

EGU22-8952 | Presentations | SSP1.2

‘SaltGiant’ drilling in the Sorbas Basin: Structural, Petrophysical and Geochemical characterization of the Messinian Salinity Crisis deposits 

Fadl Raad, Philippe Pezard, Cesar Viseras, Francisco J. Sierro, Luis M. Yeste, Javier J. Aguila, Paula Jerez, Andrea Schleifer, Fabio Meneghini, Cinzia Bellezza, Johanna Lofi, Angelo Camerlenghi, and Giovanni Aloisi

The Late Miocene deposits in the Sorbas Basin (Spain) have been of an extreme importance in the understanding of the Messinian Salinity Crisis (MSC) events (5.97-5.33 Ma). They consist of four formations. The pre-crisis Abad marls topped by the evaporitic Yesares gypsum member, followed by two non-evaporitic units known as the Sorbas and Zorreras members. Those deposits have been widely explored and studied thanks to the numerous outcropping sections in the basin.


The ‘SaltGiant’ European Training Network held a training school in October 2021 in the Sorbas Basin, where four boreholes (named SG0, 1, 2 and 3) covering most of the Messinian Salinity Crisis sequence, were drilled, cored and logged in this context along an overall thickness of about 175 m. The drillings took place inside and in the vicinity of the Torralba gypsum mine. It allowed for the first time in the scientific non-industrial domain, access to a continuous and non-outcropping succession of the Messinian deposits in the Sorbas basin. In addition to the recovered cores, borehole geophysical data were obtained from the four holes and digital images of the area were collected with a drone. Prior to the drilling, an OBO (Outcrop / Behind Outcrop) workflow was followed, which will allow integrating the outcrop and subsurface data by combining the 3D geometry of geobodies with geophysical information.


Optical borehole wall images provide mm-scale images of the borehole walls, highlighting the sedimentological and structural characteristics of the deposits. Downhole geophysical measurements included acoustic velocity, electrical resistivity and natural spectral gamma ray, which allowed determining the petrophysical characteristics of the penetrated lithologies. In addition to the petrophysical logs, a Vertical Seismic Profiling was performed in holes SG2 and SG3, including a multi-offset VSP survey in hole SG3.


The petrophysical characterization of the Messinian deposits will provide a reference case study for the lithologic characterization of MSC deposits in the subsurface elsewhere. VSP analysis provided an in-field preliminary seismic velocity evaluation in the encountered formations. Preliminary results confirm the astronomical precession-driven cyclicity observed elsewhere in the Messinian gypsum. Further processing and analyses of the large amount of acquired data will lead to identifying the astronomical and possibly higher-frequency cyclicity in the post-evaporitic deposits in the Sorbas member.

How to cite: Raad, F., Pezard, P., Viseras, C., Sierro, F. J., Yeste, L. M., Aguila, J. J., Jerez, P., Schleifer, A., Meneghini, F., Bellezza, C., Lofi, J., Camerlenghi, A., and Aloisi, G.: ‘SaltGiant’ drilling in the Sorbas Basin: Structural, Petrophysical and Geochemical characterization of the Messinian Salinity Crisis deposits, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8952, https://doi.org/10.5194/egusphere-egu22-8952, 2022.

EGU22-10040 | Presentations | SSP1.2

A profile through fast-spreading oceanic crust in the Oman ophiolite: reference frame for the crustal drillings within the ICDP Oman Drilling Project 

Jürgen Koepke, Dieter Garbe-Schönberg, Dominik Mock, and Samuel Müller

The Oman Ophiolite is the largest and best-investigated piece of ancient oceanic lithosphere on our planet. This ophiolite was target of the Oman Drilling Project (OmanDP) within the frame of ICDP (International Continental Scientific Drilling Program) which aimed to establish a comprehensive drilling program in order to understand essential processes related to the geodynamics of mid-ocean ridges, as magmatic formation, cooling/alteration by seawater-derived fluids, and the weathering with focus on the carbonatisation of peridotites.

Over two drilling seasons, the OmanDP has sampled the Samail Ophiolite sequence from crust to basal thrust. The total cumulative drilled length is 5458 m, with 3221 m of which was at 100% recovery. These cores were logged to IODP standards aboard the Japanese drilling vessel Chikyu during two description campaigns in summer 2017 and 2018. 

Here we present the main results of the working groups of the Universities Hannover and Kiel, focusing on the magmatic accretion of the Oman paleoridge. During 5 field campaigns these groups established a 5 km long profile through the whole crust of the Oman ophiolite by systematic outcrop sampling, providing the reference frame for the 400 m long OmanDP drill cores. The profile contains 463 samples from the mantle, through gabbros up to the dike/gabbro transition. Identical samples have been analyzed by several methods (bulk rock geochemistry, mineral analysis, Isotope geochemistry, EBSD analysis).

The results allow implication on the mechanism of accretion of fast-spreading lower oceanic crust. Depth profiles of mineral compositions combined with petrological modeling reveal insights into the mode of magmatic formation of fast-spreading lower oceanic crust, implying a hybrid accretion mechanism. The lower two thirds of the crust, mainly consisting of layered gabbros, formed via the injection of melt sills and in situ crystallization. Here, upward moving fractionated melts mixed with more primitive melts through melt replenishments, resulting in a slight but distinct upward differentiation trend. The upper third of the gabbroic crust is significantly more differentiated, in accord with a model of downward differentiation of a primitive parental melt originated from the axial melt lens located at the top of the gabbroic crust. Our hybrid model for crustal accretion requires a system to cool the deep crust, which was established by hydrothermal fault zones, initially formed on-axis at very high temperatures.

How to cite: Koepke, J., Garbe-Schönberg, D., Mock, D., and Müller, S.: A profile through fast-spreading oceanic crust in the Oman ophiolite: reference frame for the crustal drillings within the ICDP Oman Drilling Project, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10040, https://doi.org/10.5194/egusphere-egu22-10040, 2022.

EGU22-10406 | Presentations | SSP1.2

Assessing the well logging data from the Lake Bosumtwi (Ghana) 

Christian Zeeden, Mathias Vinnepand, Stefanie Kaboth-Bahr, William Gosling, Jochem Kück, and Thomas Wonik

Insights into the climate variability of western Africa during the Pleistocene epoch have thus far been limited by the lack of well-dated, high-resolution terrestrial climate archives. The missing information on the climate evolution of western African hampers our understanding of the proposed pan-African evolution of our species. The ~294 m lacustrine sedimentary sequence raised from Lake Bosumtwi by the International Continental Drilling program in 2004, encompassing the last ~1.1 Ma, offers the best opportunity provide a climatic benchmark record in western Africa. However, the establishment of a chronology for this record has proven challenging. To try and improve our understanding of the climatic evolution during the last ~1.1 Ma in western Africa, we will use the high-resolution downhole logging data (natural gamma ray, GR) and magnetic susceptibility data from core logging from Site 5, which is situated in the centre of Lake Bosumtwi. To maximise the robustness of this record we will try to correlate data from downhole logs with core data. This approach has help improve interpretation of logging signals and environmental reconstructions for other long lake records, such as e.g. Lake Ohrid.

How to cite: Zeeden, C., Vinnepand, M., Kaboth-Bahr, S., Gosling, W., Kück, J., and Wonik, T.: Assessing the well logging data from the Lake Bosumtwi (Ghana), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10406, https://doi.org/10.5194/egusphere-egu22-10406, 2022.

EGU22-11265 | Presentations | SSP1.2

Heterogeneous deformation across the Papaku fault, Hikurangi accretionary prism 

Rebecca Kühn, Annika Greve, Rüdiger Kilian, Marcel Mizera, and Michael Stipp

At the Hikurangi convergent margin the Pacific plate is subducted westward beneath the Australian plate. This margin has been the location of major earthquakes as well as slow slip events related to the ongoing subduction. Drill site U1518 which was drilled during IODP Expedition 375, 73 km offshore Gisborne (New Zealand), targeted the Papaku fault, a splay fault of the major decollement in sediments of the frontal accretionary prism. We selected samples from the mostly hemipelagic, weakly consolidated mudstones in the fault zone, as well as from hangingwall and footwall. In order to investigate localized and distributed deformation in the fault zone, we analysed composition, microstructure and crystallographic preferred orientation (CPO). For that we applied µXRF measurements and optical microscopy, as well as synchrotron texture analysis at DESY in Hamburg.

The samples from hanging- and footwall sediments show a relatively homogeneous microstructure with local compositional layering. While CPO strength in the hangingwall is slightly increasing with depth for all analysed clay mineral phases, the CPO in the footwall samples is in general lower and does not show a clear trend with depth. This might be interpreted as different deformation histories in hangingwall and footwall which is in accordance with previous studies. Fault zone samples show a variety of microstructures, such as mingling of different sedimentary components, locally overprinted by microfaults. CPO strength in the faulted sediments is also variable, with zones showing strong alignment of phyllosilicates and zones showing weak alignment of phyllosilicates. Variations in CPO and variable distribution of sedimentary components indicate a heterogeneous deformation within the fault zone which might be due to local compositional variations.

How to cite: Kühn, R., Greve, A., Kilian, R., Mizera, M., and Stipp, M.: Heterogeneous deformation across the Papaku fault, Hikurangi accretionary prism, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11265, https://doi.org/10.5194/egusphere-egu22-11265, 2022.

TS2 – Deformation mechanisms and rheology

EGU22-407 | Presentations | TS2.1

Strain localization along a detachment system: Deformation of natural dolomitic and calcitic mylonites (Mt. Hymittos, Attica, Greece) 

Mark Coleman, Bernhard Grasemann, David Schneider, Konstantinos Soukis, and Riccardo Graziani

Carbonate rocks can be thick, mineralogically-homogeneous packages, which accomodate strain in orogenic belts. Despite its contribution to rock strength, the deformation of dolomite as a major rock forming mineral is understudied in comparison to calcite, quartz, and feldspar. We use field, petrographic, and electron back scatter diffraction (EBSD) analyses of dolomitic and calcitic marbles to investigate the response of these rocks to different degrees of strain under greenschist facies. Mt. Hymittos, Attica, Greece, preserves a pair of Miocene top-SSW ductile-then-brittle low-angle normal faults dividing a tripartite tectonostratigraphy. The bedrock of the massif comprises sub-greenschist facies phyllites and marbles in the uppermost hanging wall unit, and high-pressure greenschist facies schists and marbles of the Cycladic Blueschist Unit in the lower two packages. Ductile mylonites in the footwalls of both detachments grade into brittle-ductile mylonites and finally into cataclastic fault cores. The dolomitic and calcitic marbles of the lower units deformed under greenschist facies conditions and their fabrics reflect the relative differences in strengths between these two minerals. In the middle tectonostratigraphic unit, dolomitic rocks are brittlely deformed and calcitic marbles are mylonitic to ultramylonitic with recrystallized grain sizes ranging from 55 to 8 μm. Within the lower package, dolomitic and calcitic rocks are both mylonitic to ultramylonitic with previous P-T data suggesting metamorphism at ~470 °C and 0.8 GPa. EBSD analysis of six dolomitic marbles of the lower unit reveals a progressive fabric evolution from mylonites to ultramylonites reflecting the magnitude of strain and decreasing temperature of deformation. In mylonitic domains, average grain diameters range from 70 to 25 μm. The mylonitic dolomite exhibits low-angle grain boundaries, internal misorientation zones and textures suggestive of subgrain-rotation recrystallization. This mylonitic fabric is crosscut by ultramylonite bands of dolomite with grain diameters of 15 to 5 μm, which overlaps with the dominant grain size of the subgrains formed within the mylonitic domains. In samples closer to the fault core, the ultramylonite fabric is predominant though boudinaged veins, and relict mylonite zones with coarser grains may still be observed. Uniformly ultramylonitic dolomitic marbles exhibit grain diameters of 40 to 5 μm; the majority of grain diameters are less than 15 μm. The ultramylonite bands have low degrees of internal misorientation and an absence of low-angle grain boundaries that, along with correlated misorientation diagrams, suggest the ultramylonitic dolomite grains are randomly oriented and deforming via grain-boundary sliding. Interstitial calcite grains within these samples may reflect creep-cavitation processes interpreted to have occurred syn-kinematically with grain-boundary sliding. The change from subgrain-rotation recrystallization to grain-boundary sliding is interpreted to reflect the interplay of grain-size sensitive and insensitive processes. Following grain size reduction, subsequent deformation was dominantly accommodated by grain boundary sliding. The dolomitic marbles of the lower unit deformed on the retrograde path from the high-pressure, mid-temperature portion of the greenschist facies. The position of the dolomitic ultramylonites immediately below the cataclastic detachment fault suggest these ultramylonites were deforming very close to the brittle-ductile transition suggesting ductile deformation at lower temperatures than might be predicted by deformation experiments.

How to cite: Coleman, M., Grasemann, B., Schneider, D., Soukis, K., and Graziani, R.: Strain localization along a detachment system: Deformation of natural dolomitic and calcitic mylonites (Mt. Hymittos, Attica, Greece), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-407, https://doi.org/10.5194/egusphere-egu22-407, 2022.

EGU22-2627 | Presentations | TS2.1

Constraining transformation weakening in plagioclase-pyroxene mixtures 

Amicia Lee, Holger Stünitz, Mathieu Soret, and Jacques Précigout

Mafic rocks are a key constituent of the oceanic and lower continental crust. Strain localisation and fabric development in these rocks is controlled by the active deformation mechanisms. From studies of natural rocks it has been established that strain localisation and weakening in mafic rocks is directly related to fluid availability and resultant mineral reactions. Understanding the interplay between reactions, fluid availability, and deformation aids in quantifying the stresses and rates of deformation processes. We have conducted an experimental investigation to constrain the weakening mechanisms in gabbro. Shear experiments were performed in a Griggs-type apparatus at 800-900°C, and 1.2-1.5 GPa with a shear strain rate of 10⁻⁵s⁻¹. The starting material consists of mixed powders with <100 µm sized grains of plagioclase and clinopyroxene from an undeformed sample of the Kågen Gabbro in Northern Norway. Experiments have been conducted with ‘as is’ (dried at 110°C) starting material and with 0.1% added water. The experiments at 800°C are very strong with a peak shear stress ~0.8 GPa whilst the 900°C experiments are weaker, reaching peak stresses of ~0.35 GPa. The 800°C experiments show evidence of mineral reactions with newly formed phases making up 10-25% of the sample. In these reaction zones, plagioclase and clinopyroxene have reacted to produce amphibole and garnet. Additionally S-C’ mylonitic fabrics have developed in these samples. The 900°C samples show minimal evidence for mineral reactions (2-5% new material) or crystal-plastic deformation mechanisms. The lack of mineral reactions in the rheologically weak experiments (900°C) and abundance of reaction products in the mechanically strong experiments (800°C) is conflicting to our inferences of natural studies. However, if partial melting takes place in the higher temperature experiments, it may account for the pronounced strength decrease. We plan to conduct EBSD and TEM analysis to determine crystallographic properties and accurate grain size and shape parameters in the fine grained reaction zones. Future experiments will use fully dried natural starting material (dried at 700-800°C) and An60 and end-member diopside, these experiments will be compared with our current experiments and be used to determine the exact weakening properties from impurities in the natural starting material.

How to cite: Lee, A., Stünitz, H., Soret, M., and Précigout, J.: Constraining transformation weakening in plagioclase-pyroxene mixtures, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2627, https://doi.org/10.5194/egusphere-egu22-2627, 2022.

EGU22-2816 | Presentations | TS2.1

Cracking induced by dislocation creep in pure quartz shear bands of granitoids 

Jacques Précigout, Estelle Ledoux, and Laurent Arbaret

The production of micro-pores during viscous creep is a driving mechanism for fluid circulation in deep environments. However, strain-induced cracking in nature is nowadays attributed to grain boundary sliding (GBS), restricting this process to fine-grained ductile shear zones where rocks deform by diffusion creep. Here we give natural evidence of micro-cracking induced by dislocation creep, which is by far the dominant deformation mechanism in lithospheric rocks. Focusing on pure quartz shear bands across the Naxos western granite (Aegean Sea, Greece), we first document sub-micron pores that arise at grain and sub-grain boundaries. Their shape and location emphasize sub-grain rotation as a source of cracking. We then confirm that quartz is dominated by dislocation creep with evidence of a moderate to strong lattice preferred orientation (LPO) and many sub-grain boundaries, including at the margin of the pluton where the brittle/ductile transition was reached. These features coincide with (1) quartz grains located as inclusion into quartz porphyroclasts and (2) a dependency of the LPO strength on grain size. Our findings suggest that creeping cavities act as pumping sites for fluid to penetrate the crystal lattice and nucleate randomly oriented grains along sub-grain boundaries, accounting for (1) shear localization by enhancing hydrolytic weakening and (2) rock embrittlement through growth and interlinkage of cavities where phase nucleation is limited.

How to cite: Précigout, J., Ledoux, E., and Arbaret, L.: Cracking induced by dislocation creep in pure quartz shear bands of granitoids, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2816, https://doi.org/10.5194/egusphere-egu22-2816, 2022.

EGU22-3268 | Presentations | TS2.1

Diffusion creep of a Na-Ca-amphibole-bearing blueschist 

Leif Tokle, Lonnie Hufford, Luiz Morales, Claudio Madonna, and Whitney Behr

Blueschists are a major constituent rock type along the subduction zone interface and therefore critical to our understanding of subduction zone dynamics. Previous experimental work on natural blueschists focus on either seismic anisotropy or on the process of eclogization of a blueschist aggregate; however, little is known about the mechanical properties of blueschist rocks. We have conducted a suite of general shear deformation experiments in the Griggs apparatus to constrain the rheology of a blueschist aggregate. The sample material derives from a natural blueschist that was crushed into a powder. The powder consists of ~55% sodic amphibole, ~30% epidote, ~8% quartz, ~5% titanite, ~2% ilmenite, and <1% mica. Deformation experiments were conducted at 1.0 GPa confining pressure, temperatures of 650, 675, 700, and 750°C, and no water added. All of the deformation experiments were strain rate stepping experiments with either 4 or 5 strain rate steps per experiment with strain rates ranging from ~2.7e-5 to 5.2e-7 s-1. Based on the mechanical data we determine a stress exponent of 1.9 +/- 0.3. Microstructural and EDS analysis shows the initial Na-amphibole grains transform into a fine-grained aggregate of new Na-Ca-amphibole with lower Na and Si and higher Fe and Ca plus albite and ilmenite. The fine-grained aggregates accommodate the majority of the strain while epidote deforms by rigid body rotation or brittle deformation. Based on both the mechanical and microstructural observations, we interpret the fine-grained aggregates to be deforming by diffusion creep. Additional analyses will be conducted to constrain the grain size to develop flow law parameters to estimate the rheology of the subduction zone interface.

How to cite: Tokle, L., Hufford, L., Morales, L., Madonna, C., and Behr, W.: Diffusion creep of a Na-Ca-amphibole-bearing blueschist, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3268, https://doi.org/10.5194/egusphere-egu22-3268, 2022.

The presence of large volumes of eclogite in collision and subduction zones makes their formation and deformation highly relevant for the dynamics of convergent zones. There is however no consensus on the deformation behavior of eclogite. On the one hand, mylonitic eclogite shear zones showing evidence of dominant deformation by dislocation creep have frequently been reported. On the other hand, fluid supported formation and deformation has been recently suggested as a potential mechanism in eclogite whereby the main accommodating mechanism is dissolution-precipitation creep. This raises the question of the factors controlling the deformation behavior of eclogite.

In this contribution, we present microstructural, petrographical and chemical data from a series of eclogite samples derived from low Mg – high Ti gabbro collected at the eclogite type locality (Saualpe-Koralpe Complex, Eastern Alps, Austria). The rocks are characterized by a pronounced foliation defined by the shape preferred orientation of the major minerals (omphacite, amphibole, epidote and garnet). Minor quartz is observed at dilation sites. Overall, grains show rather straight grain boundaries and a uniform extinction. These features are interpreted as evidence of diffusion and dissolution-precipitation dominated formation and strain accommodation. Thermodynamic forward modelling indicates that eclogitization occurred at around 2 GPa and 640–680°C and was supported by fluid. Locally, the eclogite fabric is crosscut by veins showing a similar paragenesis as the host eclogite. However, they are enriched in quartz and epidote, depleted in garnet and show overall a coarser grain size. Depending on their initial orientation, the veins were either reactivated as flanking structures or foliation sub-parallel shear zones. The reactivated veins are characterized by undulatory extinction, twinning and subgrain formation, all being indicative of dislocation creep. The identical paragenesis and similar mineral chemistry indicates that reactivation occurred at conditions close to those of eclogitization. The investigated samples therefore testify that eclogite can deform by two different mechanisms at similar pressure-temperature conditions. Our investigations document that dissolution-reprecipitation is bound to the process of eclogitization and low strain rate whereas post-eclogitization strain localization is accommodated by dislocation creep.

How to cite: Rogowitz, A., Huet, B., and Schorn, S.: How to creep and when? Deformation mechanisms at the eclogite type locality (Saualpe-Koralpe Complex, Eastern Alps, Austria)., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3477, https://doi.org/10.5194/egusphere-egu22-3477, 2022.

EGU22-3889 | Presentations | TS2.1

Feasibility of the mobile-lid regime controlled by grain size evolution 

Antonio Manjón-Cabeza Córdoba, Tobias Rolf, and Maëlis Arnould

One of the most discussed issues of whole-mantle geodynamic models is the need of an 'ad hoc' yield stress which is lower than any strength measurement of natural samples in the brittle or plastic regimes. It is commonly believed that grain size evolution, in particular grains size reduction due to dynamic recrystallization, may decrease the strength of the lithosphere and therefore aid the onset and persistence of the mobile-lid regime. In this work, we carry out an investigation of 2D whole-mantle annulus models with varying yield stress. We compare cases with different grain growth and grain reduction parameters to cases with constant grain size to make inferences on the feasibility of a plate-like convective regime as a function of the yield strength of the lithosphere.

Our results show that viscosity profiles of models with dynamic grain-size evolution are inherently different to those with constant grain size, and that those profiles vary little when changing grain-size evolution parameters. In this context, the lower mantle shows greater variations in viscosity than the upper mantle: with viscosity contrasts between upper and lower mantle and plume widths comparable to those of the Earth, in particular in models with enhanced grain growth. Furthermore, our models show that, while enhancing grain size reduction reduces episodicity and increases mobility up to some point, increasing grain growth favors mobile-lid convection even more. This is at odds with previous conceptions of the grain-size-evolution-induced mobile-lid regime, where grain groth should promote healing of the lithosphere and therefore inhibit subduction. We hypothesize that increased stiffness of the bottom of the lithosphere, together with a more viscous lower mantle, are the main reasons for the grain-grouth-favored mobile-lid regime.

How to cite: Manjón-Cabeza Córdoba, A., Rolf, T., and Arnould, M.: Feasibility of the mobile-lid regime controlled by grain size evolution, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3889, https://doi.org/10.5194/egusphere-egu22-3889, 2022.

EGU22-4606 | Presentations | TS2.1

Strain localization in quartz-rich fault gouge at subseismic slip rates 

Chien-Cheng Hung and André Niemeijer

Understanding strain localization and development of shear fabrics within brittle fault zones at subseismic slip rates is crucial as they have critical implications for the mechanical strength and stability of faults and for earthquake physics. We performed direct shear experiments on ~1 mm thick layers of simulated quartz-rich fault gouge at an effective normal stress of 40 MPa, pore fluid pressure of 15 MPa, and temperature of 100°C. Microstructures were analyzed from strain hardening state (~1.3 mm displacement) to strain softening (~3.3 mm displacement) to steady-state (~5.6 mm) at different imposed shearing velocities of 1 µm/s, 30 µm/s, and 1 mm/s. We performed X-ray Computed Tomography (XCT) on sheared samples with a strain marker to analyze slip partitioning. To analyze and quantify localization from few hundreds to thousands of cross-section images, we used machine learning and developed an automatic boundary detection method to identify the type of shear fabrics and quantify the amount of them. Our results reveal that R1 and Y (or boundary) shears are the two major localization features that developed in a repeatable manner. Slip on R1 shears shows little dependency on both shear displacement and slip velocity and amounts to ~5 to ~30% of slip through the entire frictional sliding. On the other hand, Y and boundary shears show a strong correlation with displacement and velocity where more than 40% of strain was accommodated at steady-state for all velocities. However, Y and boundary shears become less prominent with increasing velocity, suggesting that velocity-weakening and the associated nucleation of unstable sliding are less likely to occur at higher slip rates as the overall friction behavior would be controlled by a thicker gouge layer. In other words, this suggests that Y shear development by grain size reduction is less efficient at high slip velocities which has important implications for the amount of heat generated during accelerating slip.

How to cite: Hung, C.-C. and Niemeijer, A.: Strain localization in quartz-rich fault gouge at subseismic slip rates, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4606, https://doi.org/10.5194/egusphere-egu22-4606, 2022.

Seismic rupture in strong, anhydrous lithologies of the lower continental crust requires high failure stress, in the absence of high pore fluid pressure. Several mechanisms proposed to generate high stresses at depth imply transient loading driven by a spectrum of stress changes, ranging from highly localised stress amplifications to crustal-scale stress transfers. High transient stresses up to GPa magnitude are proposed by field and modelling studies, but the evidence for transient pre-seismic stress loading is often difficult to extract from the geological record due to overprinting by coseismic damage and slip. However, the local preservation of deformation microstructures indicative of crystal-plastic and brittle deformation associated with the seismic cycle in the lower crust offers the opportunity to constrain the progression of deformation before, during and after rupture, including stress and temperature evolution.


Here, detailed study of pyroxene microstructures characterises the short-term evolution of high stress deformation and temperature changes experienced prior to, and during, lower crustal earthquake rupture. Pyroxenes are sampled from pseudotachylyte-bearing faults and damage zones of lower crustal earthquakes recorded in the exhumed granulite facies terrane of Lofoten, northern Norway. The progressive sequence of microstructures indicates localised high-stress (at the GPa level) preseismic loading accommodated by low temperature plasticity, followed by coseismic pulverisation-style fragmentation and subsequent grain growth triggered by the short-term heat pulse associated with frictional sliding. Thus, up to GPa-level transient high stress leading to earthquake nucleation in the dry lower crust can occur in nature, and can be preserved in the fault rock microstructure.

How to cite: Menegon, L. and Campbell, L.: High stress deformation and short-term thermal pulse preserved in exhumed lower crustal seismogenic faults (Lofoten, Norway), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4692, https://doi.org/10.5194/egusphere-egu22-4692, 2022.

EGU22-5108 | Presentations | TS2.1

Different mechanical behavior at the same P-T conditions in biotite-quartz assemblage: interconnectivity and composition effect of experimentally deformed mica 

Khadija Alaoui, Laura Airaghi, Holger Stünitz, Hugues Raimbourg, and Jacques Précigout

The effect of composition on microstructural development and mechanical strength was tested using mica-quartz-aggregates during deformation experiments.

This study used two chemically different biotite minerals mixed with quartz: (1) high F-phlogopite and (2) intermediate biotite in order to investigate the role of biotite-bearing systems for the development of shear zones and strain accommodation. Shear experiments (Griggs-type apparatus) were performed using mica (30 vol. %) and quartz (70 vol. %) assemblages at 750 and 800°C, 1000 MPa and a shear strain rate of ~10-5 s-1.

Mechanical results for the F-phlogopite-bearing assemblage indicate strong samples, approximately equivalent to pure quartz samples (Richter et al., 2018), deforming at differential stresses of 764-1097 MPa). F-phlogopite flakes are preferentially oriented parallel to the main shear direction, but poorly interconnected. Most of the strain is accommodated by quartz behaving as an interconnected network. Cathodoluminescence imaging reveals that quartz recrystallizes mainly by local pressure-solution and its strength controls the overall strain accommodation.

In contrast, intermediate biotite assemblages are significantly weaker and deform for lower differential stresses of 290-327 MPa, as expected for natural rocks. Biotite flakes form an interconnected network accommodating most of strain.

The interconnectivity of biotite grains thus plays a major role in weakening quartz-biotite assemblages. However, at similar P-T-strain and grain size conditions, the capacity of biotite grains to interconnect may also depend on its chemical composition, particularly considering the effect of trace elements incorporation (as fluorine) on the strength of the biotite interlayer bounds (Dahl et al., 1996, Figowy et al., 2021). This led us to conclude that different types of mica, behaving differently, strongly affect strength, deformation mechanism, and microstructure of the rock due to their structure, composition and stability fields.

How to cite: Alaoui, K., Airaghi, L., Stünitz, H., Raimbourg, H., and Précigout, J.: Different mechanical behavior at the same P-T conditions in biotite-quartz assemblage: interconnectivity and composition effect of experimentally deformed mica, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5108, https://doi.org/10.5194/egusphere-egu22-5108, 2022.

EGU22-5127 | Presentations | TS2.1

Experimental strain localization in granitoid ultramylonites: Pre-fracturing vs. viscous strain localization 

Natalia Nevskaya, Weijia Zhan, Holger Stünitz, Alfons Berger, and Marco Herwegh

Rheological models of Earth’s granitoid mid- to upper crust are commonly based on the physico-chemical properties of the most abundant rock forming minerals quartz and feldspar. However, there is increasing field evidence that deformation in these rocks localizes in ultrafine-grained polymineralic shear zones, which are weaker than any of the end member minerals. Especially at the brittle to viscous transition, the localization and deformation mechanisms, i.e. the role of incipient brittle deformation vs. continuous viscous strain localization, is not yet fully understood.

To fill this gap in knowledge, ultramylonite samples with granitic composition from the Central Aar Granite (Aar Massif, Central Switzerland) were deformed using a Griggs type apparatus. The foliation of the ultramylonitic starting material was oriented 45° to the compression direction, to investigate the influence of grain size and composition on strain localization in the different mylonite bands. Two types of coaxial experiments were conducted at 650°C, and 1.2 GPa confining pressure: A) Discrete fractures were created before the shear deformation starts; B) No fractures were induced during an early stage of the experiment.

All experiments have in common that strain is accommodated in 20-100 µm wide viscous shear zones with elongated grains and minor grain size reduction. In these shear zones, most strain is further localized in 10-20 µm wide zones, showing dramatic grain size reduction down to few tens of nanometres. In the experimentally generated shear zones, both, brittle and viscous processes are active. In terms of overall rock strength, all newly formed ultrafine-grained shear zones are up to three times weaker than comparable experiments on pure quartz or coarser grained granites – which agrees well with field observations. Furthermore, pre-fractured type A) is up to two times weaker than the non-fractured type B), and the orientation and number of shear zones is also fundamentally different between the two experiment types.

This study confirms two weakening factors promoting different types of strain localization at the brittle to viscous transition: 1) The existence of fractures and their interconnectivity – facilitating highly-localized grain size reduction; 2) Initial sample heterogeneity by polymineralic composition and ultrafine grain size – generating grain size reduction along strain gradients by activating viscous processes. Further quantitative microstructural analyses will reveal the role of chemistry and the deformation mechanisms on the localization behaviour.

How to cite: Nevskaya, N., Zhan, W., Stünitz, H., Berger, A., and Herwegh, M.: Experimental strain localization in granitoid ultramylonites: Pre-fracturing vs. viscous strain localization, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5127, https://doi.org/10.5194/egusphere-egu22-5127, 2022.

EGU22-5371 | Presentations | TS2.1

Implementing 3D anisotropic viscosity calculations into ASPECT 

Ágnes Király, Menno Fraters, and Rene Gassmoeller

Olivine, the main rock-forming mineral of Earth's mantle, responds to tectonic stress by deforming viscously over millions of years. This deformation creates an anisotropic (direction-dependent) texture that typically aligns with the mantle flow direction. According to laboratory experiments on olivine, we expect this texture to also exhibit anisotropic viscosity (AV), with deformation occurring more easily when it is parallel to, rather than across, the texture. However, the direction dependency of lithospheric and asthenospheric viscosity is rarely addressed in geodynamic models.

 The open-source modeling package ASPECT can address AV in a 2D setting using the director method, where AV is present due to shape preferred orientation created by dike intrusions (Perry-Houts and Karlstrom, 2019). We have adapted this implementation for current versions of ASPECT and benchmarked it against similar Rayleigh-Taylor instability models by Lev and Hager (2008).

Unfortunately, a 2D method is inappropriate to address AV related to olivine crystallographic preferred orientation (CPO or texture), as, by default, olivine has three independent slip systems on which deformation can occur. Integrating anisotropic viscosity into 3D models would also allow us to use the actual laboratory-based parametrizations of the olivine slip system activities and texture parameters when describing the evolution of CPO and AV. One of the biggest challenges in addressing AV in a 3D setting is to find the full, rank 4, viscosity tensor, which can be done with a method similar to the one for the fluidity tensor in Király et al., (2021).

Here, we present the initial results of simple geodynamic setups (shear box, corner flow), where 3D olivine CPO develops, based on the D-Rex method (Fraters and Billen, 2021), and this CPO creates AV based on the micromechanical model described in Hansen et al., (2016).

Our goal is to create a tool within ASPECT that allows for CPO to develop and affect the asthenospheric or lithospheric mantle’s viscosity to improve modeling a wide range of geodynamic problems.

 

References listed:

Fraters, M.R.T., and Billen, M.I., 2021, On the Implementation and Usability of Crystal Preferred Orientation Evolution in Geodynamic Modeling: Geochemistry, Geophysics, Geosystems, doi:10.1029/2021GC009846.

Hansen, L.N., Conrad, C.P., Boneh, Y., Skemer, P., Warren, J.M., and Kohlstedt, D.L., 2016, Viscous anisotropy of textured olivine aggregates: 2. Micromechanical model: Journal of Geophysical Research: Solid Earth, doi:10.1002/2016JB013304.

Király, Á., Conrad, C.P., and Hansen, L.N., 2020, Evolving Viscous Anisotropy in the Upper Mantle and Its Geodynamic Implications: Geochemistry, Geophysics, Geosystems, v. 21, p. e2020GC009159, doi:10.1029/2020GC009159.

Lev, E., and Hager, B.H., 2008, Rayleigh-Taylor instabilities with anisotropic lithospheric viscosity: Geophysical Journal International, doi:10.1111/j.1365-246X.2008.03731.x.

Perry-Houts, J., and Karlstrom, L., 2019, Anisotropic viscosity and time-evolving lithospheric instabilities due to aligned igneous intrusions: Geophysical Journal International, doi:10.1093/gji/ggy466.

How to cite: Király, Á., Fraters, M., and Gassmoeller, R.: Implementing 3D anisotropic viscosity calculations into ASPECT, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5371, https://doi.org/10.5194/egusphere-egu22-5371, 2022.

EGU22-5979 | Presentations | TS2.1

Quartz grain fabric in shales and sandstones: Some contrasting behaviors 

Charles Aubourg, Hugo Saur, Peter Moonen, and Rebecca Stokes

Many processes are at work when a sedimentary rock deforms. Quartz grains, for example, can rotate rigidly in the matrix, or on the contrary, undergo processes of dissolution and crystallization. Microtomography allows us to image the 3D geometry of minerals at the micron scale and quantify their fabric. Here, we use the quartz shape fabric extracted from microtomography data to evaluate the mechanisms active during burial and deformation of several sedimentary rocks systems.

Our first examples are of shales developing a slaty cleavage oblique to bedding. For shales that have undergone moderate burial (Tburial max ~200°C) (Sigues locality, Pyrenees), we show that the quartz grains rotate very little in the clay matrix. Even with the development of a slaty cleavage, a significant proportion of quartz grains remain parallel to the bedding plane. This surprising result implies that the rigid rotation of quartz grains, even in a ductile clay matrix, is not effective. 

In shales having undergone deeper burial and temperatures approaching the lower greenschist facies (Tburial max ~280°C) (Lehigh Gap locality, Appalachian mountains), we show that the average short-axis of the grains is orthogonal to the cleavage plane.  We suggest that this shape preferred orientation results from preferential dissolution of quartz faces oriented perpendicular to sigma 1, thus resulting in a shape preferred orientation without significant grain rotation.

Our last example concerns fine-grained sandstones, slightly deformed and buried at a shallow depth. If we refer to the example of shales with little burial, we would expect a very strong control of the bedding on the quartz fabric, since at these P-T conditions we expected dissolution-precipitation processes to be sluggish, and grain rotation to be ineffective.  However, surprisingly, the quartz in this rock is well oriented in the fabric which is oriented perpendicular to the bedding.

How the quartz grains were reoriented in the fine-grained sandstone suggests relations still not well understood with the deformation of a porous rock and the cementing processes of the rock. The microtomography approach in fine-grained rocks opens a door to this understanding of the behavior of quartz grains in sedimentary rocks.

How to cite: Aubourg, C., Saur, H., Moonen, P., and Stokes, R.: Quartz grain fabric in shales and sandstones: Some contrasting behaviors, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5979, https://doi.org/10.5194/egusphere-egu22-5979, 2022.

EGU22-6124 | Presentations | TS2.1

Shape Preferred Orientation at scale. From grain-scale aggregates to global mantle convection 

Albert de Montserrat, Manuele Faccenda, and Giorgio Pennacchioni

Earth's mantle rocks are poly-aggregates where different mineral phases coexist. These rocks may often be approximated as two-phase composites with a dominant phase and less abundant one (e.g. bridgmanite-ferropericlase composites in the lower mantle). Severe shearing of these rocks leads to a non-homogeneous partitioning of the strain between the different phases, with the composite developing a laminar fabric of weak and thin material where strain localizes. The resulting bulk rock is a mechanically anisotropic media that is hardened against normal stress, while significantly weakened against fabric-parallel shear stress.

Due to the large scale difference between the laminar gran-scale fabrics and regional-to-global geological processes, Earth’s rocks are idealised as homogeneous materials instead of multi-phase bodies in numerical models. Thus, a characterization of the rheology evolution of the bulk composite is necessary to better understand large-scale geological processes in which anisotropy may play a fundamental role. Recent three-dimensional numerical (de Montserrat et al. 2021) studies have shown that the degree of lateral interconnectivity of the weak and thin layers is rather limited, thus estimating the rheology of a composite with laminar fabrics by the idealized Voigt and Reuss averages for fibres yield a strong underestimation of the strength of the composite. Instead, we use a combination of numerical results and micro-mechanics to develop an empirical framework to estimate the evolution of the (anisotropic) rheology of such composites.

We apply this rheology framework to study the effects of fabric-induced directional-weakening/hardening on global mantle convective patterns. First order effects of extrinsic anisotropy of lower mantle material observed in our two-dimensional models are a decrease of the wavelength of convective cells, and up to a ~50% increase in the average mantle flow velocity caused by the weakening of the flow-parallel component of the viscosity tensor. The latter is particularly evident in mantle plumes, where the ascent and transfer of hot lower mantle material to lower depths is enhanced by the near-alignment of the weak  fabrics with the plume channel.  

How to cite: de Montserrat, A., Faccenda, M., and Pennacchioni, G.: Shape Preferred Orientation at scale. From grain-scale aggregates to global mantle convection, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6124, https://doi.org/10.5194/egusphere-egu22-6124, 2022.

Quaternary deformation in the northern Chile coastal forearc is mainly accommodated by ubiquitous upper-plate faults cataloged as weak fault zones, however, the deformation mechanisms and the internal structure of these reactivated faults remain poorly understood. To solve this problem, we selected seven study sites from reactivated upper-plate faults of the northern Chile forearc (23-25°S). These faults formed during the Early Cretaceous and reactivated during the Quaternary forming conspicuous fault-scarps. Here we present a new characterization of the internal structure at the outcrop and microscopic scale. Samples for thin-sections and XRD were collected in several cross-sections across faults. We define 4 units conforming the internal structure: (1) A decimetric well-defined principal slip zone, referred here as active fault core (AFC), consisting of a gouge layer subunit bounded by a fault breccia subunit, (2) a metric inactive fault core (IFC), surrounding the AFC, composed mostly of cataclasites and in some cases, mylonites, (3) a host-rock unit corresponds mainly to Jurassic-Cretaceous dioritic-granitic intrusives and Jurassic andesites, and (4) a decametric damage zone affecting both the IFC and the host rock. Near the topographic surface, the gouge layer subunit consists of a grey/green ultrafine matrix (40-80%) partially to completely replaced by massive iron oxides. In some sites, the gouge layers are partially foliated or/and exhibit millimetric bands of chaotic microbreccia. Porphyroclasts correspond mainly to (1) highly quartz and plagioclase intracracked individual crystals (<0.4mm), (2) larger fragments (<1mm) generally sigmoidal-like of the IFC (cataclasites) indicating different degrees of cataclastic-flow. Transgranular microfractures are densely propagated through the boundaries of larger porphyroclasts, breaking grains into ever-finer fragments (constrained communition) and generating chaotic microbreccia halos in the boundaries that grade into an ultrafine gouge matrix. (3) Another portion of large porphyroclasts (>1mm) grade from S-C cataclasite at its cores to S-C ultra-cataclasites at its boundaries. Frictional sliding is propagated through this S-C fabric formed by the ultracataclasite boundaries, generating well-defined and smoothened surfaces between large porphyroclasts and gouge layers. Microfractures -commonly filled with quartz>calcite>albite>chlorite-epidote veins- propagate mostly through the gouge layers, which are in turn displaced by microfaults affecting the entire subunit. The IFC composition changes markedly along-strike but multiple-fault cores are ubiquitous. In Jurassic andesites, the IFC is defined by protocataclasites with layers of red gouge, In Jurassic to Cretaceous diorite-metadiorite protoliths the IFC is defined by S-C cataclasites with microstructures showing undulating extinction, subgrains, and bulging recrystallization of quartz, and ultracataclasite bands and green gouge layers developed under low greenschist facies conditions. The IFC formed in mylonitic rocks derived from Jurassic to Cretaceous granitoid includes bands of hydrothermally-altered green and red mylonites. The complex overprinted microtextures indicate a progressive exhumation and shearing of the IFC. The microtexture analysis reflects the evolution of this unit from high temperature-low stain rates formed at deep structural levels to low temperature-high strain rates near-surface. We interpret the highly accumulated strain in S-C ultracataclastic bands and S-C gouge layers of the IFC (constrained communition) reduces the fault frictional strength and promote the frictional slip of the quaternary reactivations of the AFC.

How to cite: González, Y., Jensen, E., and González, G.: Internal Structure and Microtextures of a Quaternary Upper-plate Fault Zone: A Case Study from the Atacama Fault System, Northern Chile., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6742, https://doi.org/10.5194/egusphere-egu22-6742, 2022.

EGU22-6926 | Presentations | TS2.1

Pulverized rock and episodic hydrothermal brecciation along the Median Tectonic Line, Japan 

Geri Agroli, Masaoki Uno, Atsushi Okamoto, and Noriyoshi Tsuchiya

The Median Tectonic Line is a major east-west-trending arc-parallel fault that separates Sanbagawa metamorphic rock and Ryoke granite. We present the novel field observation of possibly pulverized rock and its evolution toward the fault cataclasite/breccia in the Ichinokawa antimony deposit in Central Shikoku. Ichinokawa was considered as largest stibnite mine in the world with a huge stibnite aggregate in which occurs in the brecciated-pelitic schist of the Sanbagawa belt. Based upon the texture in the outcrop and particle size distribution (PSD), this breccia is classified into two types. Breccia-1 (bx-1) is characterized by a centimeter-meter (up to 5m) angular breccia-clast with minimum to no shear displacement and rotational block. This bx-1 subsequently grows to be highly comminuted to produce breccia-2 (bx-2) which appear to have chaotic-polymict clast with matrix-supported texture within the fault zone with variable width and cut the bx-1 by recognizable breccia margin. Both of these breccia are cemented by reddish rock-flour matrix consist of dolomite, quartz, mica, ± pyrite. In addition, bx-2 has a more rounded shape with most of the clast size being less than 50mm and it shows orientation nearly parallel to the fault plane under a thin section. Based on this macro and micro-scale observation breccia in Ichinokawa is more likely to form under different mechanisms. Pulverization is plausible to rupture the pelitic schist and generate bx-1 without rotating the fragment. Hydrothermal activity in this area can’t be neglected which is responsible to create bx-2 as a result of fluid injection and transporting comminuted-fragment of bx-1 into the damage/fault zone. This breccia also underpins the formation of stibnite deposits that mark the latest fluid activity in this area where quartz-stibnite±pyrite±kaolinte vein truncate both pelitic schists of bx-1 as well as bx-2.

How to cite: Agroli, G., Uno, M., Okamoto, A., and Tsuchiya, N.: Pulverized rock and episodic hydrothermal brecciation along the Median Tectonic Line, Japan, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6926, https://doi.org/10.5194/egusphere-egu22-6926, 2022.

EGU22-7175 | Presentations | TS2.1

Weakening effect of grain-size reduction in granitoid shear zones 

Jonas B. Ruh, Leif Tokle, and Behr Whitney

Localization of strain during deformation of crustal rocks to form narrow shear zones requires some form of strain weakening. Bulk weakening of a deforming shear zone may for example result from geometric reorganization and interconnection of weak phases, from concentration of fluids or fluid-rich mineral phases, or from local temperature increase due to shear heating. A further potential weakening effect is work-related grain size reduction driven by dislocation creep, and the consequent activation of grain-size-sensitive diffusion creep in recrystallized zones.

To test the importance of grain size reduction for mechanical weakening of granitoid crustal shear zones, a numerical model of initially undeformed granitoid texture was set up and sheared to a total shear strain of 10. The numerical finite difference code solves for the conservation of momentum (Stokes) and mass with a visco-elasto-plastic rheology. The model setup outlines a naturally constrained multi-phase granitoid texture including quartz, plagioclase, and biotite. The domain measures 5x5 cm with top and bottom velocities describing simple shear, while the left and right prescribe periodic boundaries. For both quartz and plagioclase (anorthite), flow laws for dislocation and diffusion creep are implemented and act in parallel. Grain size evolution is implemented in the form of the paleowattmeter with mineral-specific grain growth laws. The 2D numerical setup of a complex multi-phase initial texture allows us to investigate grain size evolution in a progressively evolving system with a spatially and temporally varying stress field and with simultaneous geometric weakening associated with interconnection of weak phases, neither of which can be analyzed using analytical calculations.

Results show a reduction of grain sizes of quartz and plagioclase during shearing with quartz deforming dominantly under dislocation creep. Plagioclase behaves brittlely at low temperatures, with dominant diffusion creep at intermediate temperatures, switching to dislocation creep at high temperatures. Purely textural weakening of >60% occur at 550 °C. At lower temperatures, anorthite strength reduces given the brittle yield envelope and at higher temperatures, dislocation creep strength of quartz and anorthite converge, resulting in bulk shear and less textural weakening. Additional weakening related to grain size reduction relies on the activation of diffusion creep as the dominant deformation mechanism for anorthite. At 350 °C, anorthite strength is limited by brittle yield and no grain-size-induced weakening is detectable. For higher temperatures, additional grain-size-induced weakening ranges between 12–30 %, and thus represents an important factor for the initiation of granitoid crustal shear zones. The presented numerical study underlines the importance of grain size-related weakening of crustal shear zones, particularly at intermediate temperatures above the brittle-ductile transition (400–450°C) and below the activation of dislocation creep in plagioclase (>650°C).

How to cite: Ruh, J. B., Tokle, L., and Whitney, B.: Weakening effect of grain-size reduction in granitoid shear zones, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7175, https://doi.org/10.5194/egusphere-egu22-7175, 2022.

EGU22-7406 | Presentations | TS2.1

Correlative, cross-platform microscopy application reveals deformation mechanisms during seismic slip along wet carbonate faults 

Markus Ohl, Helen King, Andre Niemeijer, Jianye Chen, and Oliver Plümper

Faults in the upper crust are considered major fluid pathways, raising the need for deformation experiments under wet conditions that focus on the nanoscale interaction between gouge material and pore fluid. Friction experiments on calcite at seismic slip velocities show strong dynamic weakening behaviour attributed to a combination of grain-size reduction and nanoscale diffusion. The resulting syn-deformational physico-chemical interactions between fluid and calcite are key in deciphering deformation mechanisms and rheological changes during and after (seismic) faulting in the presence of a fluid phase. We conducted rotary shear deformation experiments (1 m/s, σn = 2 and 4 MPa) on calcite gouge with water enriched in 18O (97 at%) as pore fluid to track and quantify potential fluid – mineral interaction processes. With our correlative, cross-platform workflow approach, we integrate Raman spectroscopy, nanoscale, and Helium-Ion secondary ion mass spectrometry (nanoSIMS, HIMSIMS), focused ion beam – scanning electron microscope (FIB-SEM) and transmission electron microscopy (TEM) to characterise the nanostructure and analyse isotope distribution. Raman analyses confirm the incorporation of 18O into the calcite crystal structure, as well as the presence of amorphous carbon. We identify three new band positions relating to the possible isotopologues of CO32- (reflecting 16O substitution by 18O). In addition, we detect portlandite (Ca(OH)2), pointing to a hydration reaction of lime (CaO) with water. Raman and NanoSIMS maps reveal that 18O is incorporated throughout the deformed volume, implying that calcite isotope exchange affected the entire fault gouge. Based on oxygen self-diffusion rates in calcite we conclude that solid-state 18O – isotope exchange cannot explain the observed incorporation of 18O into the calcite crystals during wet, seismic deformation. Hydration of portlandite and calcite containing 18O, implies breakdown and decarbonation of the starting calcite and the nucleation of new calcite grains. Our results question the state and nature of calcite gouges during seismic deformation and challenge our knowledge of the rheological properties of wet calcite fault gouges at high strain rates. The observations suggest that the physico-chemical changes are a crucial part of hydrous calcite deformation and have implications for the development of microphysical models that allow us to quantitatively predict crustal fault rheology.

How to cite: Ohl, M., King, H., Niemeijer, A., Chen, J., and Plümper, O.: Correlative, cross-platform microscopy application reveals deformation mechanisms during seismic slip along wet carbonate faults, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7406, https://doi.org/10.5194/egusphere-egu22-7406, 2022.

EGU22-8484 | Presentations | TS2.1

Constraining wet quartz rheology from constant-load experiments 

Subhajit Ghosh, Holger Stünitz, Hugues Raimbourg, and Jacques Précigout

Quartz rheology in the presence of H2O is crucial for modelling (numerical and geophysical) the deformation behavior of the continental crust and gives important insights into crustal strength. Experimental studies in the past have determined stress exponent (n) values for flow law between ≤ 2 to 4, while the values for activation energy (Q) vary from ~120 to 242 kJ/mol. Here, we investigated the quartz rheology under high-pressure and high-temperature conditions, using a new generation hydraulically-driven Griggs-type apparatus. In order to develop a robust flow law for quartzite, we performed constant-load coaxial deformation experiments of natural coarse-grained (~ 200 μm) high purity (> 99 % SiO2) quartzite from the Tana quarry (Norway). Our creep tests were carried out at 750 to 900 °C on the as-is (no added H2O) and 0.1 wt.% of H2O added samples under 1 GPa of confining pressure. In contrast to earlier strain rate stepping experiments, the constant-load procedure needs lower strain at each step (≤1−2%) to achieve steady-state conditions. As a consequence, there is a very low amount of recrystallization. Importantly, we can determine the Q-value independently of the stress exponent (n). Microstructures from the deformed samples were characterized using polarized light microscopy (LM), SEM-cathodoluminescence (CL), and Electron backscatter diffraction (EBSD).

Our creep results for both the as-is and 0.1 wt.% H2O-added samples yield Q = 110 kJ/mol and n = 2. Our microstructural analysis suggests that the bulk sample strain is accommodated by grain-scale crystal-plasticity, i.e., dislocation glide (dominantly in prism <a>) with minor recovery by sub-grain rotation, accompanied by grain boundary migration and micro-cracking. It is inferred that strain incompatibilities induced by dislocation glide are accommodated by grain boundary processes, including dissolution precipitation and grain boundary sliding. These intra-grain and grain-boundary processes together resulted in a lower n-value of 2 for the quartzite.

Our new flow law predicts strain rates that are in much better agreement with the inferred natural values than the earlier flow laws. It further suggests that the strength of the continental crust considering quartz rheology is significantly lower than previously predicted.  

How to cite: Ghosh, S., Stünitz, H., Raimbourg, H., and Précigout, J.: Constraining wet quartz rheology from constant-load experiments, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8484, https://doi.org/10.5194/egusphere-egu22-8484, 2022.

EGU22-9089 | Presentations | TS2.1

Experimental Investigation of Glaucophane Rheology Through General Shear Deformation Experiments 

Lonnie Hufford, Leif Tokle, Claudio Madonna, and Whitney Behr

Glaucophane is a major constituent mineral associated with subducted mafic oceanic crust at blueschist facies conditions. Viscous deformation of glaucophane has been documented in natural blueschists; however, no experimental study has characterized the specific deformation mechanisms that occur in glaucophane nor the flow law parameters. We are conducting a suite of general shear deformation experiments in a Griggs apparatus to investigate crystal-plastic deformation mechanisms and microstructures of deformed glaucophane over a range of experimental conditions. Experimental samples consist of glaucophane powder separated from natural MORB blueschists  from Syros Island, Greece. Our experimental suite thus far includes temperatures and pressures ranging from 650° to 750°C and 1.0 to 1.5 GPa, strain rates ranging from ~3x10-6/s to ~8x10-5/s (both constant-rate and strain-rate stepping), and different grain size populations from 75-90 µm, 63-125 µm , and 63-355 µm. The lowest temperature and the strain-rate-stepping experiments exhibit evidence for combined frictional-viscous deformation and provide constraints on the brittle-ductile transition in glaucophane at laboratory conditions. The constant-rate experiments conducted at higher temperatures show greater evidence for viscous deformation by dislocation creep, including kinked grains, deformation lamellae, undulose extinction, and bulging via bulge recrystallisation. Mechanical data from the strain-rate stepping experiments allow us to interpret what parameters have the largest effect on peak stress. When comparing experiments conducted at 1 GPa and initial powder grain sizes of 63-355 µm, we find temperature having the largest effect on peak stresses. The 700°C experiment with an initial deformation speed 5 times faster (LH038) than another 700°C strain-rate stepping experiment (LH042) has a ~90 MPa higher peak shear stress, whereas the 750°C strain-rate stepping experiment with an initial deformation speed 4 times faster than LH042 has a ~115 MPa lower peak shear stress. At the time of abstract submission, further constant-rate experiments are planned at slower strain-rates to continue exploring the laboratory conditions necessary to activate glaucophane crystal-plastic deformation mechanisms. These data will be used with further strain-rate stepping experiments to develop flow law parameters from mechanical data.

How to cite: Hufford, L., Tokle, L., Madonna, C., and Behr, W.: Experimental Investigation of Glaucophane Rheology Through General Shear Deformation Experiments, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9089, https://doi.org/10.5194/egusphere-egu22-9089, 2022.

   Plate boundary dynamics remain incompletely understood in the context of thermo-chemical convection. Strain-localization is affected by weakening in ductile shear zones, and a change from dislocation to diffusion creep caused by grain-size reduction is one of the mechanisms that has been discussed. However, the causes and consequences of strain localization remain debated, even though tectonic inheritance and strain localization appear to be critical features in plate tectonics.

   Frictional-plastic faults in nature and brittle shear zones in the lithosphere may be weakened by high transient, or static, fluid pressures, or mechanically by gouge, or mineral transformations. Weakening in ductile shear zones in the viscous domain may be governed by a change from dislocation to diffusion creep caused by grain-size reduction. In mechanical models, strain weakening and localization in the shallow parts of the lithosphere has mainly been modeled by an approximation of brittle behavior using a pseudo visco plastic rheology in combination with a linear decrease of the yield strength of the lithosphere with increasing deformation (plastic-strain (PSS) softening). Strain weakening in viscous shear zones, on the other hand, may be described by a linear dependence of the effective viscosity on the accumulated deformation (viscous-strain (VSS) softening). These different types of strain weakening are further explored and compared to the predictions from different laboratory-based models of grain-size evolution for a range of temperatures and a step-like variation of total strain rate with time. Such a parameterized, apparent-strain, or “damage”, dependent weakening (SDW) rheology (mainly PSS) can successfully mimic more complex weakening processes in global mantle convection computations. While we focus on GSS rheology to constrain the parameters of SDW, the analysis is not limited to grain-size evolution as the only possible microphysical mechanism.

   The SDW weakening rheology allows for memory of deformation, which weakens the fault zone as well as the lithosphere for a longer period and allows for a self-consistent formation and reactivation of inherited weak zones. In addition, the memory effect and weakening of the fault zone allows for a more frequent reactivation at smaller strain rates, depending on the strain-weakening parameter combination. Reactivation within the models occurs in two different ways: a), as a guide for laterally propagating convergent and divergent plate boundaries, and b), formation of a new subduction zone by reactivation of weak zones. A longer rheological memory results in a decrease in the dominant period of the reorganization of plates due to less frequently formed new plate boundaries. In addition, the low frequency content of velocity and heat transport spectra decreases with a decreasing dominant period. This indicates a more sluggish reorganization of plates due to the weaker and thus more persistent active plate boundaries. These results show the importance of a rheological memory for the reorganization of plates, potentially even for the Wilson cycle.

How to cite: Fuchs, L.: Plate-boundary maintenance – formation, preservation, and reactivation in global plate-like mantle convection models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9584, https://doi.org/10.5194/egusphere-egu22-9584, 2022.

EGU22-9765 | Presentations | TS2.1

In-situ mechanical testing and characterization of olivine grain boundaries 

Diana Avadanii, Lars Hansen, Ed Darnbrough, Katharina Marquardt, David Armstrong, and Angus Wilkinson

The mechanics of olivine deformation play a key role in long-term planetary processes, such as the response of the lithosphere to tectonic loading or the response of the solid Earth to tidal forces, and in short-term processes, such as the evolution of roughness on oceanic fault surfaces or postseismic creep within the upper mantle. Many previous studies have emphasized the importance of grain-size effects in the deformation of olivine. However, most of our understanding of the role of grain boundaries in the deformation of olivine is inferred from comparison of experiments on single crystals to experiments on polycrystalline samples.

To directly observe and quantify the mechanical properties of olivine grain boundaries, we use high-precision mechanical testing of synthetic forsterite bicrystals with well characterised interfaces. We conduct in-situ micropillar compression tests at high-temperature (700°C) on low-angle (13° tilt about [100] on (015)) and high-angle (60° tilt about [100] on (011)) grain boundaries. In these experiments, the boundary is contained within the micropillar and oriented at 45° to the loading direction to promote shear along the boundary. In these in-situ tests, we observe differences in deformation style between the pillars containing the grain boundary and the pillars in the crystal interior. In-situ observations and analysis of the mechanical data indicate that pillars containing the grain boundary consistently support elastic loading to higher stresses than pillars without a grain boundary. Moreover, only the pillars without a grain boundary display evidence of sustained plasticity and slip-band formation. Post-deformation advanced microstructural characterization (STEM) confirms that under the conditions of these deformation experiments, sliding did not occur along the grain boundary. These observations support the hypothesis that grain boundaries are stronger than the crystal interior. 

These experiments on small deformation volumes allow us to qualitatively explore the differences between the crystal interior and regions containing grain boundaries. Overall, the variation in strain and temperature in our small scale experiments allows fundamental investigation of the response of well characterised forsterite grain boundaries to deformation. 

How to cite: Avadanii, D., Hansen, L., Darnbrough, E., Marquardt, K., Armstrong, D., and Wilkinson, A.: In-situ mechanical testing and characterization of olivine grain boundaries, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9765, https://doi.org/10.5194/egusphere-egu22-9765, 2022.

EGU22-9842 | Presentations | TS2.1

Revisiting stylolites as a gage of overburden pressure – insights from fractal analysis 

Christoph von Hagke, Simon Hirländer, Kevin Frings, and Herfried Madritsch

Stylolites are ubiquitous structures generated by pressure solution primarily found in limestones. They and have been used as indicator for maximum stress a rock has suffered. This is commonly done by characterizing the fractal dimensions of stylolites. The current canon is the expectation from the theory that stylolites form through two physical pressure-driven regimes: low-frequency and higher-energetic - dominated by elastic forces and high-frequency lower-energetic dominated by surface tension. The so-called characteristic length separates both regimes, analytically marked by a kink in the power spectrum, which relates the energy contributions to the frequency.

However, determining this kink is not straightforward, and requires additional assumptions. We present a data set of stylolites recovered from a drill hole in the Alpine foreland basin. We mapped stylolites from different depths at sub-mm resolution semi-automatically and analyzed them using new methods of fractal analysis.

Excitingly, our preliminary studies did not identify the expected kink’s position from several different images of probes of drill cores, despite satisfactory reliability of laboratory preparation. Standard methods such as power spectral density, averaging wavelet coefficients, RMS, min/max, and rescaled range-based approaches revealed variations in their results, generally without evidence for a kink in the corresponding graphs. Implementing more recently developed methods such as adaptive fractal analysis could not improve the results. This finding challenges the classic interpretation of fractal characteristics of stylolites. 

How to cite: von Hagke, C., Hirländer, S., Frings, K., and Madritsch, H.: Revisiting stylolites as a gage of overburden pressure – insights from fractal analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9842, https://doi.org/10.5194/egusphere-egu22-9842, 2022.

EGU22-10101 | Presentations | TS2.1

The role of grain boundaries for the deformation and grain growth of olivine at upper mantle conditions 

Filippe Ferreira, Marcel Thielmann, and Katharina Marquardt

Crystal defects such as vacancies, dislocations and grain boundaries are central in controlling the rheology of the Earth’s upper mantle. Their presence influences element diffusion, plastic deformation and grain growth, which are the main microphysical processes controlling mass transfer in the Earth’s lithosphere and asthenosphere. Although substantial information exists on these processes, there is a general lack of data on how these defects interact at conditions found in the Earth’s interior. A better understanding of processes occurring at the grain scale is necessary for increased confidence in extrapolating from laboratory length and time scales to those of the Earth. We examined the evolution of olivine grain boundaries during experimental deformation and their impact on deformation in the dislocation-accommodated grain- boundary sliding (disGBS) regime. This may be the main deformation mechanism for olivine in most of Earth’s upper mantle. Our results suggest that grain boundaries play a major role in moderating deformation in the disGBS regime. We present observational evidence that the rate of deformation is controlled by assimilation of dislocations into grain boundaries. We also demonstrate that the ability for dislocations to transmit across olivine grain boundaries evolves with increasing deformation. Lastly, we show that dynamic recrystallization of olivine creates specific grain boundaries, which are modified as deformation progresses. This might affect electrical conductivity and seismic attenuation in the upper mantle. The effective contribution of grain-boundary processes (such as disGBS) on the rheology of the upper mantle is correlated to the amount of grain boundaries in upper mantle rocks, that is, their grain-size distribution and evolution. The grain-size distribution in the Earth’s mantle is controlled by the balance between damage (recrystallization under a stress field) and healing (grain growth) processes. However, grain growth, one of the main processes controlling grain size, is still poorly constrained for olivine at conditions of the upper mantle. To evaluate the effects of pressure on grain growth of olivine, we performed grain growth experiments at pressures ranging from 1 to 12 GPa using piston-cylinder and multi-anvil apparatuses. We found that the olivine grain-growth rate is reduced as pressure increases. Our results suggest that grain-boundary diffusion is the main process of grain growth at high pressure. Based on extrapolation of our experimental results to geological time scales, we suggest that at deep upper-mantle conditions (depths of 200 to 410 km), the effect of pressure on inhibiting grain growth counteracts the effect of increasing temperature. We present estimations of viscosity as a function of depth considering the grain-size evolution predicted here. Our estimations suggest that viscosity is almost constant at the deep upper mantle, which corroborates postglacial-rebound observations.

How to cite: Ferreira, F., Thielmann, M., and Marquardt, K.: The role of grain boundaries for the deformation and grain growth of olivine at upper mantle conditions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10101, https://doi.org/10.5194/egusphere-egu22-10101, 2022.

EGU22-10153 | Presentations | TS2.1

Does porosity really matter? A first model for dissolution-enabled deformation bands in low porosity rocks based on microstructural analysis of calcarenite from Cotiella Basin, Spain. 

Maria Eleni Taxopoulou, Nicolas E. Beaudoin, Charles Aubourg, Elli-Maria Charalampidou, and Stephen Centrella

We report for the first time deformation features functionally described as deformation bands developed in low porosity rocks. This observation contradicts existing knowledge that deformation bands develop only in highly porous rocks. The studied formation is a bioclastic calcarenite of the Upper Cretaceous Maciños Unit in the Cotiella Massif. It is part of a megaflap adjacent to a salt diapir that has experienced extensional tectonics before the Pyrenean contraction. The bands present thickness variations, and in places they imitate the appearance of stylolites. This observation raises the question: how do deformation bands form in low porosity rocks?

To answer the question, we combine field observations with microstructural analysis to identify the occurring processes for the formation of deformation bands within low porosity rocks. After using optical microscopy and cathodoluminescence spectroscopy to conduct a petrographic study, we observe that the rock underwent multiple diagenetic cycles before the deformation stage, confirming that its porosity was significantly reduced before the deformation stage. Subsequently, we characterized the quartz grains inside the host rock and the dissolution-enabled deformation bands, using non-destructive imaging techniques. Three-dimensional image analysis from X-ray microtomography scans shows low grain size variations between the quartz grains in the host rock and in the bands, suggesting minor grain fracturing along the bands. However, grain reorientation has been reported for the quartz grains inside the bands, in relation to those in the host rock. Strain analysis was performed from Electron Backscattered Diffraction measurements, revealing higher strain along the quartz grain contacts inside the deformation band, compared to those in the host rock and stylolites. Our current data suggest that new porosity was created from local dissolution of the matrix, so the less soluble quartz grains were placed in contact. By wrapping-up the above observations, we propose a conceptual model that demonstrates the genesis and evolution of dissolution-enabled deformation bands in low porosity rocks, through local dissolution of the micritic matrix and transient porosity increase.

How to cite: Taxopoulou, M. E., Beaudoin, N. E., Aubourg, C., Charalampidou, E.-M., and Centrella, S.: Does porosity really matter? A first model for dissolution-enabled deformation bands in low porosity rocks based on microstructural analysis of calcarenite from Cotiella Basin, Spain., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10153, https://doi.org/10.5194/egusphere-egu22-10153, 2022.

EGU22-10404 | Presentations | TS2.1

Influence of a yield stress on lower mantle dynamics: filtering and changing morphology of plumes and slabs 

Anne Davaille, Thibaut Chasse, Neil Ribe, Philippe Carrez, and Patrick Cordier

When a fluid can experience a "jammed" state, it will flow only when the local deviatoric stress becomes greater than a critical stress, the so-called  "yield-stress". Jamming can be caused by entangled dislocations in a mineral, or by the existence of a hard skeleton in a two-phase fluid. According to recent numerical modeling, a Bridgmanite lower mantle would predominantly deform by pure dislocation climb; and due to dislocations interactions, it would flow only for local deviatoric stress greater than a critical yield stress which depends on dislocation density. In a first set of fluid mechanics experiments in such a visco-plastic fluid, we showed that hot plumes would develop with a much thicker morphology than in newtonian fluids. Scaling laws derived from the experiments tightly relate the buoyancy and diameter of the hot plumes to the value of the yield-stress, as well as to the mantle microstructure (such as dislocation density and vacancy concentration). Yield stress values between 1 and 10 MPa, implying dislocation densities between 108 and 1010 m−2, would be sufficient to explain the thick plumes morphology observed in seismic tomography images; while low vacancy concentrations could explain the 1000 km-depth horizon also seen in tomography. 

In a second set of experiments, we show that the existence of a yield stress in a Bridgmanite lower mantle will also act as a filter regarding slab penetration in the lower mantle. Given slab buoyancy, a typical slab, 100 km-thick, could not overcome the lower mantle yield stress. So most of single slabs would be expected  to stagnate in the transition zone. However a pile of folded slab with a typical thickness around 400 km would have sufficient buoyancy and would penetrate into the lower mantle. This could explain the seismic tomographic observations regarding slabs in the transition zone and in the lower mantle, without the need to invoke a compositional stratification there.

How to cite: Davaille, A., Chasse, T., Ribe, N., Carrez, P., and Cordier, P.: Influence of a yield stress on lower mantle dynamics: filtering and changing morphology of plumes and slabs, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10404, https://doi.org/10.5194/egusphere-egu22-10404, 2022.

EGU22-11133 | Presentations | TS2.1

Exploring the effect of mantle composite rheology on surface tectonics and topography 

Maelis Arnould, Tobias Rolf, and Antonio Manjón-Cabeza Córdoba

Earth’s surface dynamics and topography are tied to the properties and dynamics of mantle flow. In particular, upper mantle rheology controls the coupling between the lithosphere and the asthenosphere, and therefore partly dictates Earth’s surface tectonic behaviour and topographic response to mantle convection (dynamic topography). The presence of seismic anisotropy in the uppermost mantle suggests the existence of mineral lattice-preferred orientation (LPO) caused by the asthenospheric flow. Together with laboratory experiments of mantle rock deformation, this indicates that Earth’s uppermost mantle can deform in a non-Newtonian way, through dislocation creep. Although several studies suggest the potentially significant effect of upper-mantle non-Newtonian rheology on mantle convection (e.g. Schulz et al., 2020) and topography (e.g. Asaadi et al., 2011, Bodur and Rey, 2019), it is usually not considered in whole-mantle models of mantle convection self-generating plate tectonics.

 

Here, we investigate the effects of using a composite rheology (with both diffusion and dislocation creep) on surface tectonics and dynamic topography in 2D-spherical annulus models of mantle convection with plate-like tectonics and continental drift. We systematically vary the amount of dislocation creep by changing the activation volume for dislocation creep and the reference transition stress between diffusion and dislocation creep. We show that for low yield stresses promoting plate-like behavior in diffusion-creep-only models, modeling a composite rheology in the mantle favors more surface mobility while for large yield stresses which still generate plate-like motions in diffusion-creep-only models, a progressive increase in the amount of dislocation creep leads to stagnant-lid convection. We then compare the amplitudes and spatio-temporal distribution of dynamic topography in models with and without dislocation creep, in light of observed Earth present-day residual topography characteristics.

 

References:

Schulz, F., Tosi, N., Plesa, A. C., & Breuer, D. (2020). Stagnant-lid convection with diffusion and dislocation creep rheology: Influence of a non-evolving grain size. Geophysical Journal International, 220(1), 18-36.

Asaadi, N., Ribe, N. M., & Sobouti, F. (2011). Inferring nonlinear mantle rheology from the shape of the Hawaiian swell. Nature, 473(7348), 501-504.

Bodur, Ö. F., & Rey, P. F. (2019). The impact of rheological uncertainty on dynamic topography predictions. Solid Earth, 10(6), 2167-2178.

How to cite: Arnould, M., Rolf, T., and Manjón-Cabeza Córdoba, A.: Exploring the effect of mantle composite rheology on surface tectonics and topography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11133, https://doi.org/10.5194/egusphere-egu22-11133, 2022.

EGU22-11488 | Presentations | TS2.1

Ilmenite transformations in suevites from the Ries meteorite impact structure, Germany 

Fabian Dellefant, Claudia A. Trepmann, Stuart A. Gilder, Iuliia V. Sleptsova, and Melanie Kaliwoda

Glass fragments (Flädle) in suevites from Zipplingen within the Ries (Germany) meteorite impact structure contain round aggregates of polycrystalline ilmenite with various amounts of rutile, ferropseudobrookite (FeTi2O5), armalcolite ((Fe,Mg)Ti2O5) and titanite (CaTi[OSiO4]). The 10-100s µm sized aggregates often have a thin rim of µm-sized magnetite grains. The ilmenite grains are 5-10 µm in diameter and form an equilibrium fabric with 4-6-sided grains with smoothly curved grain boundaries and 120° angles at triple junctions, i.e. a so-called foam structure. The ilmenite grains have random crystallographic orientations and do not show any internal misorientations. Rutile, typically a few µm in diameter, is associated with similarly fine-grained ilmenite and a high amount of pores. Coarser polygonal ilmenite grains can also show a marked grain boundary porosity. Only rarely in the center of the aggregates, a deformed single ilmenite crystal occurs, indicating that the aggregates originated from shocked coarse ilmenite crystals from the target gneisses. Ferropseudobrookite is intergrown with remnants of original ilmenite grains or secondary ilmenite grains without foam structure. A vermicular intergrowth of ilmenite, rutile, and magnetite can be present at the rim, where armalcolite can be enriched in Mg.

We interpret that ferropseudobrookite formed at high temperatures (>1010°C) and reducing conditions from coarse ilmenite crystals originating from the target gneisses according to the following reaction: 2FeTiO3 → FeO + FeTi2O5. Some FeO migrated towards the rim due to the low oxygen fugacity, resulting in the observed porosity. Upon cooling, FeO migration caused ferropseudobrookite to disintegrate resulting in the formation of rutile and ilmenite: FeTi2O5 → FeTiO3 + TiO2. Silicate melt at the contact of the FeTi-oxides provided magnesium to form armalcolite from ferropseudobrookite and calcium to form titanite within fractures. Rapid cooling resulted in a shift in redox-conditions with the formation of pure Fe magnetite from FeO at the rim of the aggregates. Quenching of the system can explain the local preservation of ferropseudobrookite and armalcolite, whereas the ilmenite foam structure formed during back reaction of ferropseudobrookite at relatively slower cooling rates. The different cooling rates in the aggregates can be explained by the locally varying amount of surrounding superheated melt forming the Flädle-structure.

How to cite: Dellefant, F., Trepmann, C. A., Gilder, S. A., Sleptsova, I. V., and Kaliwoda, M.: Ilmenite transformations in suevites from the Ries meteorite impact structure, Germany, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11488, https://doi.org/10.5194/egusphere-egu22-11488, 2022.

EGU22-12327 | Presentations | TS2.1

Strain localization and weakening during eclogite-facies transformation in experimentally deformed plagioclase-pyroxene mixtures 

Mathieu Soret, Holger Stünitz, Jacques Précigout, Amicia Lee, and Hugues Raimbourg

The rheology of mafic rocks buried at high to ultra-high-pressure conditions remains enigmatic. Minerals stable at these conditions are mechanically very strong (garnet, omphacite, glaucophane, zoisite, kyanite). In the laboratory, they show plastic deformation only at very high temperature (e.g. > 1000°C for pyroxene and garnet). Yet, viscous shear zones in mafic rocks metamorphosed at amphibolite and eclogite-facies conditions are commonly reported in fossil collisional and subduction zones. These shear zones localize and accommodate large amounts of strain by weakening of the host rocks. This weakening is interpreted as being induced by a transition from grain size insensitive to grain size sensitive creep, in particular with the activation of the dissolution–precipitation creep. However, the exact interplay between deformation, mineral reaction and fluid/mass transfer remains poorly-known.

We have conducted a first series of deformation experiments at eclogite-facies conditions on a 2-phase aggregate representative of mafic rocks. Shear experiments were performed in a new generation of Griggs-type apparatus (Univ. Orléans) at 850°C, and 2.1 GPa with a shear strain rate of 10⁻6 s⁻¹. The starting material consists of mixed powders with < 100 µm sized grains of plagioclase and clinopyroxene from an undeformed sample of the Kågen Gabbro in Northern Norway. Experiments have been conducted with ‘as is’ (dried at 110°C) starting material and with 0.2% added water.

The mechanical data indicate that the samples are first very strong with a peak differential stress at 1.4 GPa. Then, a significant weakening is observed with a stress decrease by 0.5 GPa. The high-strain sample is characterized by a strain gradient increasing toward the center of the shear zone. Metamorphic reactions occur throughout the sample, but the high-strain areas contain considerably more reaction products than the low-strain areas. The nucleation of new phases leads to a drastic grain size reduction and phase mixing, whose intensities are positively correlated with the strain intensity. The nature, distribution and fabric of the mineral products vary also progressively with the strain intensity.

  • In the low-strain areas, dissolution-precipitation processes mainly occur along grain boundaries: plagioclase is rimmed by zoisite and a secondary plagioclase more albitic in composition while clinopyroxene is rimmed by amphibole.
  • In the mid-strain areas, dissolution-precipitation processes are more pervasive: amphibole and a secondary more sodic clinopyroxene occurs in pressure shadows of primary clinopyroxene, while primary plagioclase is completely replaced by a fine-grained mixture of zoisite and quartz. Reaction products show a strong shape-preferred orientation parallel to the shear direction.
  • In the high-strain areas, dissolution-precipitation leads to the nucleation of a fine-grained mixture of garnet and secondary clinopyroxene, quartz and kyanite. Most reaction products have subhedral shape with no clear preferred orientation. Hydrous minerals (amphibole and zoisite) are not observed.

Our preliminary results indicate that strain at eclogite-facies conditions is preferentially accommodated and localized by dissolution-precipitation processes. Further micro-structural and geochemical analyses are required to quantify the exact interplay between the physical and chemical processes controlling the dissolution-precipitation creep.

How to cite: Soret, M., Stünitz, H., Précigout, J., Lee, A., and Raimbourg, H.: Strain localization and weakening during eclogite-facies transformation in experimentally deformed plagioclase-pyroxene mixtures, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12327, https://doi.org/10.5194/egusphere-egu22-12327, 2022.

EGU22-12964 | Presentations | TS2.1 | Highlight | TS Division Outstanding ECS Award Lecture

Crustal stress across spatial scales 

Mojtaba Rajabi and Oliver Heidbach

The study of crustal stress examines the causes and consequences of in-situ stress in the Earth’s crust. Stress at any given point has several geological sources, including ‘short-term and local-scale’ and ‘long-term, ongoing and wide-scale’ source. In order to better characterise the crustal stress state, the analyses of both local- and wide-scale sources, and the consequences of their superposition are required. The global compilation of stress data in the World Stress Map database has increased significantly since its first release in 1992 and its analysis revealed large rotations of the stress tensor in several intraplate settings.

Large-scale stress analysis, so called first-order, (> 500 km) provides information on the key drivers of the stress state that result from large density contrasts and plate boundary forces. The analyses of stress at smaller-scales (< 500 km) have numerous applications in reservoir geomechanics, geo-storage sites, civil engineering and mining industry. To date, numerous studies have investigated the stress analysis from different perspectives. However, the stress, in geosciences, is still enigmatic because it is a scale-dependant parameter. It means, stress variations can be studied at both the ‘spatial-scale’ and ‘temporal-scale’. This paper aims to investigate the crustal stress pattern with a particular emphasis on the orientation of maximum horizontal stresses at various spatial-scales, ranging from continental scales down to basin, field and wellbore scales, to better evaluate the role of various stress sources and their applications in the Earth’s crust. The stress analyses conducted in this work shows that stress pattern at large-scales do not necessarily represent the in-situ stress pattern at smaller-scales. Similarly, analysis of just a couple of borehole measurements in one area might not yield a good representation of the regional stress pattern.

How to cite: Rajabi, M. and Heidbach, O.: Crustal stress across spatial scales, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12964, https://doi.org/10.5194/egusphere-egu22-12964, 2022.

The rheology and mechanisms of strain localisation in the middle and lower crust is yet to be fully constrained, but advances in analytical techniques mean we can revisit previously studied areas and build upon understanding already gained.

A strain profile across a Laxfordian-age (2300-1700 Ma) amphibolite-facies shear zone at Upper Badcall, NW Scotland, provides an excellent backdrop to investigate the hydration-strain-deformation mechanism relationship in the granulite-facies garnet-pyroxene quartzofeldspathic gneiss host rock and cross-cutting 25 m wide isotropic dolerite Scourie dyke. Both the granulite faces gneissic banding and mafic dyke are initially oriented at a high angle to the shear zone boundary. With increasing proximity to the shear zone centre the host rocks become progressively rotated, more deformed and hydrated. Increasing strain results in new foliation development, general grain size reduction and full or partial replacement of pre-existing pyroxene and hornblende by lower-temperature hornblende.

Tatham and Casey (2007) showed the 65 m wide shear zone has an estimated maximum shear strain of 15, which drops to ~7 towards the edge of the shear zone, and falls to < 1 at distances ≥ 40 m from the shear zone centre. We present data from four new transects, taken at 50-100 m intervals along the mafic dyke, which detail the change in deformation style and patterns of strain localisation and intensity. Localised anastomosing high strain zones envelop lenses of undeformed dolerite, with 65-70% of protolith undeformed in the dyke 350 and 230 m from shear zone centre. This decreases to 30 and 0% of undeformed protolith 100 m from and within the shear zone, respectively. Mylonite sensu stricto makes up 10% of dyke at distances ≥ 100 m from the shear zone, which increases to 70% within the shear zone, while the remaining dyke forms a weak fabric evidenced by the shape change of mafic grain aggregates.

Microstructural analyses show a switch in dominant deformation mechanisms from dynamic recrystallisation 350 m from the shear zone, to dissolution-precipitation creep inside the shear zone, identified by a change in crystallographic and shape preferred orientation, and distinct microstructural observations. An introduction of ~10 area % quartz and a loss of feldspar in the mafic dyke inside the shear zone accompanies this switch in dominant deformation mechanisms. We outline microstructural observations characteristic of dissolution-precipitation creep within the shear zone, and propose localised infiltration of quartz-rich fluid facilitates a switch from dislocation creep to pervasive dissolution-precipitation creep resulting in rheological weakening and local strain localisation. Our results suggest that strain localisation in the mid crust may be highly dependent on local fluid availability as fluid presence may trigger a switch in deformation mechanism and, with that, significant localised rheological weakening.

Tatham, D.J. and Casey, M., 2007. Inferences from shear zone geometry: an example from the Laxfordian shear zone at Upper Badcall, Lewisian Complex, NW Scotland. Geological Society, London, Special Publications, 272(1), pp.47-57.

How to cite: Carpenter, M., Piazolo, S., Craig, T., and Wright, T.: The link between water infiltration, deformation mechanisms and strain localisation in the mid crust – an example from the Badcall shear zone, NW Scotland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13366, https://doi.org/10.5194/egusphere-egu22-13366, 2022.

EGU22-13371 | Presentations | TS2.1

Glaucophane plasticity and scale-dependent yield strength from nanoindentation experiments 

Alissa Kotowski, James Kirkpatrick, Christopher A. Thom, Sima A. Alidokht, and Richard Chromik

Subduction interface shear zones localize deformation and sustain plate-boundary weakness on million-year timescales, as well as host a variety of enigmatic seismicity and slow slip transients. A physical understanding of the steady-state and transient mechanics of subduction shear zones requires quantitative constraints of the plastic yield strength and deformation mechanism(s) of metamorphic rocks and minerals that occupy the plate interface. However, very little is known about the rheology of many hydrous minerals that occupy the plate interface, such as glaucophane (end-member sodic amphibole). This is partly because conventional deformation experiments meet technical challenges when trying to measure plasticity in the laboratory due to the stability field of glaucophane, the confining pressure needed to suppress fracture, and the limited range of trade-off between temperature and strain rate in experiments.

 

Here, we present preliminary results from room-temperature nanoindentation experiments on thin sections of glaucophane-rich rocks that produced crystal plasticity by dislocation glide under high-stress conditions. Nanoindentation produces in-situ confining pressure that typically inhibits brittle fracture during loading in favor of plastic deformation. Since the volume of deformation beneath the tips is very small compared to the grain size, each indent is essentially a single-grain mechanical test (i.e., effects of grain boundaries can be ignored). We convert load-depth data from two spheroconical tips of different radii to stress-strain curves to quantify the elastic-plastic transition and characterize post-yield behavior. We measure yield stress as a function of grain orientation. Both post-yield weakening and post-yield hardening occur, which likely reflect brittle fracture along micro-faults/cleavage planes, and dislocation bursts and pile-ups, respectively. Glaucophane hardness decreases with increasing length scale of deformation (i.e., indentation radius), capturing a “size effect” that may reflect an effective decrease in dislocation density as the volume of plastic deformation increases beneath the indent tip. This effect is well-constrained for many metals and some geologic materials, including olivine.

 

The mechanical tests provide a basis for interpreting microstructures of naturally-deformed blueschists, which suggest that glaucophane exhibits recovery-limited dislocation glide and dynamic recrystallization. Low-temperature plasticity may provide a micro-physical framework for long-term strain localization and transient brittle shear when meta-mafic rocks are deformed to high strain.

How to cite: Kotowski, A., Kirkpatrick, J., Thom, C. A., Alidokht, S. A., and Chromik, R.: Glaucophane plasticity and scale-dependent yield strength from nanoindentation experiments, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13371, https://doi.org/10.5194/egusphere-egu22-13371, 2022.

EGU22-669 | Presentations | TS2.2

Structural analysis of the alpine orogeny in the western High Atlas, Morocco: New insights through a multiscale approach 

Salih Amarir, Mhamed Alaeddine Belfoul, Khalid Amrouch, Yousef Attegue, and Hamza Skikra

The Moroccan Atlas is an intracontinental chain resulted from an aborted rifting during the Mesozoic time, by an uplifting and moderate shortening during the Late Cretaceous-Cenozoic period. Several studies have highlighted the role of tectonic inversion in the evolution of the High Atlas Range, where strike-slip faults are commonly been considered as a main component of the alpine signature within the High Atlas belt. However, more recent works have focused on the geodynamic model of the evolution of the Atlas Range using different approaches. The structural history and chronology of events are still matter of debates. To contribute to the later, a combined meso and microstructural study was conducted in the western part of the chain. It provided an attempt to quantify paleo-stresses from structural analysis of the Permo-Triassic extensional phase to the tectonic reversal phases, acting from Cenozoic to present days.
This work highlighted two major tectonic phases: (1) the first represented by an extensive regime, with a sub-horizontal minimal stress σ3 oriented NE-SW and linked to the Central Atlantic occurrence. This stage is characterized by pull apart basins genesis in horst and graben morphology. (2) the second phase represented by a weakly tilted compression with a maximum stress σ1 oriented in set NNE-SSW to NNW-SSE. This compression began in the Tertiary, contemporary with the Africa and Europe collision. the related inversions are printed at the paleozoic basement/mesozoic cover interface from the Eastern area to the Jurassic-Cretaceous and Cenozoic plateaus in the West, passing through the Triassic detrital formations of the Argana corridor.
Keywords: Paleo-stress, Structural analysis, Tectonic inversion, Western high Atlas, Morocco, Alpine orogeny.

How to cite: Amarir, S., Belfoul, M. A., Amrouch, K., Attegue, Y., and Skikra, H.: Structural analysis of the alpine orogeny in the western High Atlas, Morocco: New insights through a multiscale approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-669, https://doi.org/10.5194/egusphere-egu22-669, 2022.

EGU22-1008 | Presentations | TS2.2

Deciphering the tectonic complexity of the Central High Atlas Mountains using brittle deformation mesostructures and calcite mechanical twinning analysis 

Hamza Skikra, Khalid Amrouch, Abderrahmane Soulaimani, Mustapha Hdoufane, and Salih Amarir

Located in the western segment of the intracontinental Atlas system, the Moroccan Central High Atlas is a NE-SW to ENE-WSW-trending Fold-and-Thrust Belt that is formed during the Cenozoic Alpine orogeny by a positive inversion of Triassic-Jurassic basin. It is structurally distinguished from the other segments of the Moroccan High Atlas orogenic belt by the occurrence of S-shaped ENE-WSW oriented tight anticlinal ridges bounding wider synclines. The elongated ridges core disordered association of plutonic rocks, Liassic carbonate and Late Triassic arigilites, whilst the wider synclines are filled by thick Jurassic series with minor magmatic manifestations expressed by mafic and felsic dikes. The origin of these structures has been ascribed to pre-inversion wrench tectonics with significant compressive component whereas they have been attached to post-rift rift block tilting and or salt tectonics in an alternative view. Characterizing the paleostress history is thereby a crucial matter to unravel the structural evolution of these structures. In order to bring new insights into the actual understanding of the Central High Atlas post-rift structural history, we reconstruct the paleostress tensors preserved in the folded Jurassic series of Anemzi and Tirrhist regions based on brittle deformation structures together with calcite twins stress inversion. The preliminary results highlight the presence of pre-folding layer parallel maximum horizontal stress during three stages: E-W to ENE-WSW, NNE-SSW and NW-SE compressions. Local extensional stress features are observed essentially near diapiric structures and the exhumed magmatic intrusions. The latest structural stage is featured by a post-folding NW-SR compression likely related to the recent phases of the Alpine orogeny.

How to cite: Skikra, H., Amrouch, K., Soulaimani, A., Hdoufane, M., and Amarir, S.: Deciphering the tectonic complexity of the Central High Atlas Mountains using brittle deformation mesostructures and calcite mechanical twinning analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1008, https://doi.org/10.5194/egusphere-egu22-1008, 2022.

EGU22-1324 | Presentations | TS2.2

Stochastic mechanical analysis of the stress field in a 3D thrust fold 

Anthony Adwan, Bertrand Maillot, Pauline Souloumiac, Christophe Barnes, and Pascale Leturmy

Knowledge of the in-situ stress state is a key factor for any subsurface site characterization and for safe underground geotechnical exploitations. Despite the huge progress in estimating the stress field, understanding the state of stress is still a tedious and challenging endeavor due to incomplete data and sparse information. Moreover, the cost of performing stress measurements is quite elevated while the procedure is delicate and time consuming. Thus, the importance of utilizing geomechanical models for a wider stress evaluation.

We conduct a sensitivity analysis of the stress field with respect to rheological parameters in a kilometric scale thrust fold using a 3D numerical implementation of the theory of Limit Analysis (LA). LA searches for the exact loading force at the onset of failure by bounding it through optimization using a kinematic (upper bound) and a static (lower bound) approach. Elastic parameters are not required, and we only adopt the Coulomb failure criterion characterized by a friction angle and a cohesion.

The 3D geological prototype created, is inspired from the north eastern Jura setting, northern Switzerland, and corresponds to the lateral termination of a partially buried fault cored anticline. It is formed by five material layers with different Coulomb parameters and two different décollement levels. We perform a parametric study by varying the friction angle of the bulk materials, the faults and the shallow décollement.

Our simulations, show various stress distribution patterns depending on the uncertainties related to fault and decollement friction angles. This implies different model behaviors and distinct rupture geometries. However, we identify in particular a stress shielded layer presenting low stress values independently of the parametric variations. Comparing our results with a 2D approach consolidates our findings and highlights the importance of 3D modeling. Finally, we perform a stress analysis of several boreholes taken at various locations. We represent each borehole by an average stress profile with its respective standard deviation. In doing so, we are transforming the parametric variations into stress logs reflecting our uncertainties. This process reveals in particular a counter-intuitive vertical stress decrease with depth near activated blind faults. We argue that this observation is related to material uplift in a compression regime and is only possible for a restricted blind fault.

The aim of this study is to evaluate the possibility of performing real stress data inversion in order to both predict stresses away from the measurements, and determine ranges of compatible rock parameters.

How to cite: Adwan, A., Maillot, B., Souloumiac, P., Barnes, C., and Leturmy, P.: Stochastic mechanical analysis of the stress field in a 3D thrust fold, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1324, https://doi.org/10.5194/egusphere-egu22-1324, 2022.

EGU22-1572 | Presentations | TS2.2 | Highlight

Effects of regional and local stresses on fault slip tendency in the southern Taranaki Basin, New Zealand 

Cecile Massiot, Hannu Seebeck, Andrew Nicol, David D. McNamara, Mark J.F. Lawrence, Angela G. Griffin, Glenn P. Thrasher, and G. Paul D. Viskovic

Determining the potential for faults to slip is widely employed for evaluating fault slip potential and associated earthquake hazards, and characterising reservoir properties. Here we use borehole and 3D seismic reflection data to estimate stress orientations and magnitudes, fault geometries and slip tendency in the southern Taranaki Basin, New Zealand. We highlight uncertainties in maximum horizontal stress (SHmax) magnitude calculations from borehole breakout width and rock strength. As in other settings, breakout width is uncertain on resistivity images because one of the breakout edges often lies in-between the resistivity imager pads, so only a subset of borehole breakouts can be used with confidence. The main uncertainty on SHmax magnitude is the rock strength at the borehole depth at which breakouts form. Given the rarity of basin-specific rock mechanical data, we rely on equations used to convert downhole acoustic compressional wave slowness into rock strength defined in sandstone and mudstones. However, lithologies in the southern Taranaki Basin are commonly muddy sandstones and sandy mudstone that can be interlayered. In addition, we show an example where breakouts are confined to moderately cemented carbonate units without change in acoustic compressional wave slowness. Using a range of rock strength equations based on sandstones and mudstones provides a possible SHmax magnitude range. With only one focal mechanism available in the study area, constraints on SHmax magnitudes from borehole data remain valuable and inform on stresses in the shallow crust.

Although the southern Taranaki basin is undergoing active deformation at plate tectonic scales, the stress magnitudes appear insufficiently high to reactivate the faults assuming a classic coefficient of friction. SHmax azimuths and SHmax:Sv magnitude ratios vary locally between boreholes and with depth. A borehole that intersects an inactive seismic-scale fault and borehole-scale faults over a 150-m interval shows SHmax to rotate by up to 30° proximal to the faults, which are favourably orientated for slip in both strike-slip and normal regimes. The small borehole-scale faults may, however, be active within the inactive seismic scale fault's damage zone. We highlight changes of slip tendency along faults resulting from local variations in the stress field and non-planar fault geometries that could not be resolved using only seismic reflection data and regional stress tensor.

How to cite: Massiot, C., Seebeck, H., Nicol, A., McNamara, D. D., Lawrence, M. J. F., Griffin, A. G., Thrasher, G. P., and Viskovic, G. P. D.: Effects of regional and local stresses on fault slip tendency in the southern Taranaki Basin, New Zealand, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1572, https://doi.org/10.5194/egusphere-egu22-1572, 2022.

EGU22-1823 | Presentations | TS2.2

Tectonic evolution of the northern Verkhoyansk fold-and-thrust belt based on paleostress analysis and U-Pb calcite dating 

Elena A. Pavlovskaia, Andrey K. Khudoley, Jonas B. Ruh, Artem N. Moskalenko, Marcel Guillong, and Sergey V. Malyshev

The formation of the Verkhoyansk fold-and-thrust belt (FTB) is traditionally interpreted as a result of Late Mesozoic subduction and consequent closure of the Oimyakon Ocean, followed by the collision of the Kolyma-Omolon microcontinent with the Siberian Craton. In particular, the northern Verkhoyansk FTB reflects the complex tectonic history and interaction of the Arctic and Verkhoyansk orogens. Although previous studies documented several Cretaceous deformation events, the details of the northern Verkhoyansk evolution are still poorly understood.

A combined structural and geochronological study was carried out to identify the tectonic evolution of the northern Verkhoyansk FTB. Fault and fold geometries and kinematics were used for paleostress reconstruction in the central and western parts of the northern Verkhoyansk FTB. The multiple inverse method was used to separate individual stress fields from heterogeneous fault-slip data and three different stress fields (thrust, normal and strike-slip faulting) were identified. Thrust and normal faulting stress fields were found throughout the study area, whereas a strike-slip faulting stress field was only found in Neoproterozoic rocks in the westernmost part of the northern Verkhoyansk FTB. Furthermore, U-Pb LA-ICP-MS dating of calcite fibers on slickensides was performed to obtain a first-order time constraint on fault activity.

The study reveals the following succession of major deformation events across the northern Verkhoyansk: i) The oldest tectonic event corresponding to the strike-slip faulting stress field with NE-SW-trending compression axis is Early Permian (284±7 Ma) and likely represents a far-field response to the Late Palaeozoic collision of the Kara terrane with the northern margin of the Siberian Craton. ii) A slickenfibrous calcite age of 125±4 Ma is attributed to the most intense Early Cretaceous compression event, when the modern fold and thrust structure developed. Dykes in the eastern part of the northern Verkhoyansk FTB cutting N-S trending folds with 90-85 Ma U-Pb zircon ages mark the end of this event. iii) U-Pb slickenfiber calcite ages of 76-60 Ma estimate the age of a Late Cretaceous–Palaeocene compression event, when thrusts were reactivated. Slickensides related to both (ii) and (iii) compressional tectonic events formed by similar stress fields with W-E trending compression axes. iv) From Palaeocene onwards, extensional tectonics with approximately W-E extension predominated. Within the northern Verkhoyansk FTB, extension settings are supported by the formation of a set of grabens and a clearly recognizable normal faulting stress field.

How to cite: Pavlovskaia, E. A., Khudoley, A. K., Ruh, J. B., Moskalenko, A. N., Guillong, M., and Malyshev, S. V.: Tectonic evolution of the northern Verkhoyansk fold-and-thrust belt based on paleostress analysis and U-Pb calcite dating, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1823, https://doi.org/10.5194/egusphere-egu22-1823, 2022.

In November 2017, an Mw 5.4 earthquake with a shallow (~ 4 km) hypocenter occurred in Pohang, South Korea. Seismotectonics of this region is highlighted by ENE-WSW compression, the dominant stress field in the Korean peninsula, belongs to the Himalayan tectonic domain (HTD), and WNW-ESE or NW-SE compression belongs to the Philippine Sea tectonic domain (PSTD). Here we analyzed the aftershocks, involving focal mechanism of 38 events, to understand the characteristics of the earthquake sequence. Our results show that the mainshock sequence occurred on four ruptures showing a NE-SW trend and in February 2018, one another earthquake (or aftershock) occurred on a NNW-SSE trending rupture at 3.5 km west of the epicenter of the mainshock. Note that aftershocks mainly occurred between two NNE-SSW trending faults: Seonggok Fault and Gokgang Fault.

We analyzed the focal mechanism data as done by fault tectonic analysis. We classified them into several clusters following locations and depths and by whether a population shows a strike-slip faulting type or reverse faulting type. They were classified into several different clusters in the central main area, the northeastern area, and the southwestern area. In the central main area, focal mechanism data of strike-slip faulting type show that the WNW-ESE compression prevails in the depth between 2.0 to 4.0 km and 5.6 to 5.8km, while ENE-WSW compression is dominant between 4.3 and 5.0 km. Those of reverse faulting type display the ENE-WSW compression between 4.7 and 5.7 km deep. This implies that the intermediate depth was affected by the HTD and the upper and lower depths by the PSDT, showing a kind of stress layering.

In the northeastern area, roughly E-W compression prevails between 3.7 and 6.5 km deep, and NW-SE compression between 6.0 and 6.7 km deep. In the southwestern area, roughly E-W compressions were induced in the depth of 4.0 to 5.0 km. E-W compression seems to belong to the combinatory stress state of the HTD and PSTD, and NW-SE compression in the lower part might belong to the stress of PSDT.

The phenomenon of stress layering during the Pohang earthquake reveals that the intervention between the HDT and PSDT resulted in the mainshock and aftershocks of 2017 Pohang earthquake, as in the 2016 Kumamoto, Japan, earthquake.

How to cite: Choi, P., Son, M., and Choi, J. H.: Fault tectonic analysis of focal mechanism data of aftershocks of 2017 Pohang, Korea, earthquake of Mw = 5.4: Stress layering phenomenon between Himalayan and Philippine Sea tectonic domains, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2282, https://doi.org/10.5194/egusphere-egu22-2282, 2022.

EGU22-2969 | Presentations | TS2.2

Determination of the six unknowns of the paleostress tensor from vein data 

Christophe Pascal, Luís Jaques, and Atsushi Yamaji

The quantification of tectonic forces or, alternatively, stresses represents a significant step towards the understanding of the natural processes governing plate tectonics and deformation at all scales. However, paleostress reconstructions based on the observation and measurement of natural fractures are traditionally limited to the determination of four out of the six parameters of the stress tensor. In the present study, we attempt to reconstruct full paleostress tensors by extending the methodologies advanced by previous authors. We selected Panasqueira Mine, Central Portugal, as natural laboratory, and focused on the measurement of sub-horizontal quartz veins, which are favourably exposed in three dimensions in the underground galleries of the mine. Inversion of the vein data allowed for quantifying the respective orientations of the stress axes and the shape ratio of the stress ellipsoid. In order to reconstruct an additional stress parameter, namely pressure, we extensively sampled vein material and combined fluid inclusion analyses on quartz samples with geothermometric analyses on sulphide minerals. Finally, we adjusted the radius of the obtained Mohr circle with the help of mechanical parameters, and obtained the six parameters of the paleostress tensor that prevailed during vein formation. Our results suggests a NW-SE reverse stress regime with a shape ratio equal to ~0.6, lithostatic pore pressure of ~250 MPa and differential stress between ~40 and ~90 MPa.

How to cite: Pascal, C., Jaques, L., and Yamaji, A.: Determination of the six unknowns of the paleostress tensor from vein data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2969, https://doi.org/10.5194/egusphere-egu22-2969, 2022.

Semi-brittle flow occurs when crystal plasticity and cataclastic mechanisms operate concurrently and may be common in the middle Earth’s crust. To better constrain the characteristics of semi-brittle deformation, we performed triaxial tests up to 12% strain on dry samples of Carrara marble, spanning a wide range of temperature (T = 20 - 800°C), confining pressures (PC = 30 – 300 MPa), and strain rates (ε'= 10-3 - 10­-6 s-1). The (differential) stress (Δσ = σ1 - PC) and the hardening coefficient (h = ∂Δσ/∂ε ) depend on the applied conditions. At most conditions, Δσ increases with strain, whereas h decreases with increasing strain. At 5% strain, stress and the hardening coefficient increase as T decreases and PC increases: Remarkably, both are relatively insensitive to temperature and to rate in the range of ≈ 200 < T < 400°C. At T ≲ 400°C, the mechanical behavior of the marble is very similar to that exhibited by high-strength, high-ductility, hexagonal metals that deform by processes called twinning induced plasticity (TWIP). Qualitative microstructural observations show that twinning, dislocation motion, and inter- and intra-crystalline micro-fractures are abundant in the deformed samples over the entire range of conditions. The interplay of these deformation mechanisms leads to complex relationships of Δσ and h with the applied ε'  - T ‑ PC  conditions. Models for TWIP behavior suggest that hardening increases with decreasing twin spacing and increasing dislocation density. The low sensitivity of Δσ and h to T at 200 to 400°C may be explained by the relatively low temperature sensitivity of the critical resolved shear stress for twinning and dislocation slip in calcite in this range. None of the existing models for the brittle-ductile transition or the brittle-plastic transition are able to fully predict our experimental results, and micro mechanism-based constitutive laws for semi-brittle deformation are missing so far. Nevertheless, our observations suggest that peak strengths for calcite rocks deforming by semi-brittle processes will occur at PC ‑ T conditions of the middle crust, but that the strengths are probably more strongly influenced by total strain rather than by strain rate.

How to cite: Rybacki, E., Niu, L., and Evans, B.: Semi-brittle Deformation of Carrara Marble: A Complex Interplay of Strength, Hardening and Deformation Mechanisms, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3901, https://doi.org/10.5194/egusphere-egu22-3901, 2022.

Crustal scale low-angle normal faults are typical tectonic features in orogenic post-collisional setting driving the exhumation of deep portions of the orogenic wedge. These extensional structures are commonly active at mid to upper crustal levels within quartz- and feldspar-rich rocks. As deformation localizes along these large-scale shear zones, the understanding of mechanisms controlling their development could provide invaluable insights on the rheology of the continental lithosphere. PT ambient conditions, differential stress, pore fluid pressure and time duration of activity are all factors that could significantly operate on how a shear zones develops in space and time.

We investigated by means of a quantitative approach the evolution of the Simplon Fault Zone (Western Alps, N Italy – Switzerland). We took into account: (i) meso- and microstructures distribution across the shear zone, (ii) its time of activity by 40Ar/39Ar dating of syn-shearing micas, (iii) vorticity distribution across the shear zone and its correlation with mylonite ages, (iv) the estimates of magnitude and variation of differential flow stress and strain rates during shear zone evolution obtained through EBSD-assisted quantitative microstructural analysis. All these data have been combined to reconstruct the structural evolution of the shear zone as the result of the rheological response of involved rocks to changing PT and stress conditions.

The Simplon Fault Zone formed as an extensional detachment accommodating E-W directed lateral extrusion after the collision between Adria and Europe. Several tens of kilometres of extension were accommodated by this structure, allowing the exhumation of the deepest portions of the Central Alps. The shear zone evolved from epidote-amphibolite to greenschist facies and then brittle conditions during shearing. A decrease of simple shear component from c. 90% to c. 40% towards the top of the shear zone is observed, with mylonites displaying ages within the 12-8 Ma time interval. Calculated  differential stress (60-80 MPa) and strain rate (10-11-10-12 s-1) estimates are in agreement with values displayed by several others crustal-scale low-angle normal faults developed at medium to shallow crustal levels.

The quantitative approach used at different scales pointed out that the Simplon Fault Zone experienced a complex evolution, with shear strain that was heterogeneously distributed across the fault zone. Despite this heterogeneity, a general decrease of the simple shear component and increase of the differential flow stress toward the top of the shear zone is clearly defined.

How to cite: Montemagni, C. and Zanchetta, S.: How middle and upper continental crust reacts to prolonged extension: some clues from the Simplon Fault Zone (Central Alps), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5040, https://doi.org/10.5194/egusphere-egu22-5040, 2022.

EGU22-5556 | Presentations | TS2.2

Fast stress-loading and -unloading during faulting and shock indicated by recrystallized grains along quartz cleavage cracks 

Lisa Marie Brückner, Fabian Dellefant, and Claudia A. Trepmann

Recrystallized quartz grains are localized along cleavage cracks in coarse original quartz grains within pseudotachylyte-bearing gneisses from the Silvretta basal thrust, Austria, and in shock-vein-bearing gneisses from the Vredefort meteorite impact structure, South Africa.

In the fault rocks of the Silvretta nappe, the recrystallized grains along two sets of {10-11} cleavage cracks at an angle of about 90° occur in rounded quartz clasts with a diameter of several tens of mm to cm embedded within pseudotachylytes. No evidences of shear offset were found in relation to the cleavage cracks. The fine-grained recrystallized grains have diameters of about 10 ± 6 µm or less and are slightly elongated parallel to the cleavage planes. These new grains have similar but also deviating crystallographic orientations to that of the host. As these quartz microstructures occur exclusively in spatial relation to pseudotachylytes, they are interpreted to result from the associated high stress/high strain-rate deformation. Mechanical (-101) twins in amphibole revealed stresses on the order of 400 MPa during formation of the pseudotachylytes. Yet, the new quartz grains do not show evidence of deformation after their growth, i.e., no internal misorientation, no crystallographic preferred orientation related to dislocation glide. Therefore, we suggest that the secondary quartz grains formed during annealing after the pseudotachylyte-forming event localized at the damage zone surrounding the cleavage cracks at quasi-isostatic stress conditions.

Very similar microstructures are found in Archean gneisses of the Vredefort impact structure, South Africa. There, the recrystallized grains with diameters of few µm along {10-11} and (0001) cleavage planes occur in shocked quartz grains related to mm-sized shock veins, characterized by Schlieren-microstructure of secondary feldspar. Also here, no major shear offset of the cleavage cracks is obvious and the secondary quartz grains do not show evidence of deformation. The observation that quartz shock effects are spatially related to both, the shock veins and secondary quartz grains, suggests that they formed during shock loading and subsequent pressure release with high strain rates (ca. 106 s-1) but minor shearing. Analogous to the Silvretta fault rocks, growth of quartz grains is suggested to occur restricted to the damage zone of the cleavage cracks at quasi-isostatic stresses during post-shock annealing.

In both, the Silvretta fault rocks and shocked gneisses from the Vredefort dome, quartz grains fractured without major shearing at high stresses and subsequently recrystallized localized to the damage zone of cleavage cracks at quasi-isostatic stress conditions. Damage in the process zone surrounding the cleavage cracks must have been large enough for effective grain boundary migration, i.e., growth of grains in orientations weakly controlled by the host orientation. Recrystallization ceased because of the missing driving force during subsequent quasi-isostatic stress conditions. These microstructures indicate quasi-instantaneous loading to high differential stresses of a few hundred MPa and fast unloading to quasi-isostatic stress conditions.

How to cite: Brückner, L. M., Dellefant, F., and Trepmann, C. A.: Fast stress-loading and -unloading during faulting and shock indicated by recrystallized grains along quartz cleavage cracks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5556, https://doi.org/10.5194/egusphere-egu22-5556, 2022.

EGU22-6673 | Presentations | TS2.2

Using surface velocities and subsurface stressing rate tensors to resolve interseismic deep slip distribution on closely spaced faults 

Jack Loveless, Hanna Elston, Michele Cooke, and Scott Marshall

Inversions of interseismic surface velocities alone often struggle to uniquely resolve the 3D fault slip rate distribution along systems with branching or closely spaced faults, such as the southern San Andreas Fault (SAF) in California, USA. Local stress states inferred from microseismic focal mechanisms may provide additional constraints on interseismic deep slip because they contain information about stress at depth and closer to the interseismic deep slip than GPS surface velocities. Here, we invert forward-model generated stressing rate tensors and surface velocities, individually and jointly, to assess how well the inverse approach estimates the distribution of slip rates along both simple and complex fault systems. The inverse approach we present can constrain both the interseismic deep slip rates that reveal fault locking depths and the relative activity of faults. 

We assess the inverse approach by inverting forward model-generated stressing rate tensors and surface velocities to recover fault slip distribution for two models. Forward models that include either a single, planar strike-slip fault or the 3D complex geometry of the southern SAF simulate interseismic loading in a two-step back-slip like approach. The forward models produce surface velocities with a 15 km spacing, which is similar to the GPS station density near the southern SAF, or at GPS station locations in southern California. We utilize the planar fault model to determine the smoothing parameters and stressing rate tensor spacing (>10 km) that minimize the misfit. The 10 km minimum spacing samples crustal volumes that are likely to have >39 focal mechanisms needed to robustly determine a stress tensor. The planar fault model inversions and the availability of focal mechanisms along the southern SAF inform the stressing rate tensor locations that we use to assess the complex model inversion performance. Because focal mechanisms provide normalized deviatoric stress tensors, we invert the full forward-model generated stress tensor as well as the deviatoric and normalized deviatoric stress tensors; this allows us to assess the impact of removing stress magnitude from the inversion.  

The inversions of the forward model-generated stressing rate tensors and surface velocities recover the slip rate distribution well with the exception of the normalized deviatoric stressing rate tensor inversion, which struggles to resolve the fault slip rates in both models. The inversions recover the locking depth with a broader transition zone than prescribed in the forward model due to the smoothing-based regularization within the inversion. The full stressing rate tensor inversion resolves slip rates better than the surface velocity inversions. The deviatoric stressing rate tensor inversion resolves slip rates better than the surface velocity inversion in the complex fault model but not in the planar fault model. Inverting stress and surface velocity information jointly improves the fit to the forward model slip distribution for both models. Joint inversions of both surface velocities and local stress states derived from focal mechanisms may improve constraints on the interseismic deep slip rates and locking depths in regions of complex faulting.

How to cite: Loveless, J., Elston, H., Cooke, M., and Marshall, S.: Using surface velocities and subsurface stressing rate tensors to resolve interseismic deep slip distribution on closely spaced faults, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6673, https://doi.org/10.5194/egusphere-egu22-6673, 2022.

EGU22-6855 | Presentations | TS2.2

Can the crustal strength in the brittle-plastic transition zone be estimated from the flow stress of calcite mylonite? 

Hiroaki Yokoyama, Jun Muto, and Hiroyuki Nagahama

Quantifying crustal strength is essential to understanding lithosphere strengths and tectonic processes, such as long-term fault movements caused by plate motions. In this study, we estimated the strength of granitic upper crust using recrystallized grain size piezometer of calcite mylonite intercalated in the Cretaceous granitic Abukuma Mountains. In addition, Raman carbonaceous material thermometer was used to constrain the deformation temperature. Calcite mylonites are originated from Late Carboniferous Tateishi Formation and locate along Shajigami shear zone at eastern margin of Abukuma Mountains, Northeastern Japan. Shajigami shear zone is a strike-slip shear zone active during the Middle Cretaceous. Along Shajigami shear zone, calcite mylonite and granitic cataclasites expose.

Calcite grains are well recrystallized, and the grain size are determined by electron backscattered diffraction (EBSD) mapping with the step sizes of 2-2.5µm. The mean grain sizes are 17-26 µm. The differential stress estimated by recrystallized grain size piezometer of calcite aggregate (Platt and De Bresser, 2017) is 35-80 MPa. The estimated metamorphic temperature using the Raman carbonaceous material thermometer (Kouketsu et al., 2014) is 340-250 ˚C. The difference in estimated metamorphic temperature is attributed to the thermal effects of the Cretaceous granitoids that penetrated along the calcite mylonite. This is because the estimated metamorphic temperature is higher the closer to the granitoid. Because well dynamically recrystallized calcite grains indicate that the deformation temperature exceeding 200˚C, the estimate by Raman carbonaceous material thermometer is the upper bound for the deformation temperature.

The calcite mylonite and the granitic cataclasite are thought to have formed at the same time in the Shajigami shear zone (Watanuki et al., 2020). Although there is a slight temperature gradient near the granite, widespread deformation has occurred in this area. The deformation temperature obtained in this study is the deformation around the brittle-plastic transition zone of the upper crust. Hence, the collecting flow stress estimated from calcite mylonite intercalated in brittle granitic shear zone may be possible to constrain the stress magnitude of the shear zone data near the brittle-plastic transition at 200-300°C.

 

References

Platt and De Bresser, 2017, J. Struct. Geol., 105, 80-87.

Kouketsu et al., 2014, Island arc, 23, 33-50.

Watanuki et al., 2020, J. Struct. Geol., 137, 104046.

How to cite: Yokoyama, H., Muto, J., and Nagahama, H.: Can the crustal strength in the brittle-plastic transition zone be estimated from the flow stress of calcite mylonite?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6855, https://doi.org/10.5194/egusphere-egu22-6855, 2022.

EGU22-7253 | Presentations | TS2.2

Paleostress and paleoburial history of a post-rift, supra-salt, carbonate reservoir offshore Congo (Atlantic): Insights from calcite twinning and stylolite roughness paleopiezometry. 

Anies Zeboudj, Boubacar Bah, Olivier Lacombe, Nicolas E. Beaudoin, Claude Gout, Nicolas Godeau, and Jean-Pierre Girard

Our understanding of the temporal variation of past stress in the crust is usually pictured in relation to tectonic contexts, where it helps decipher the evolution of deformation of rocks at different scales. The paucity of paleostress reconstructions in passive margins makes the knowledge of the origin of stress and of its evolution very incomplete, especially in poorly accessible offshore parts. Moreover, in salt-rich passive margins like the offshore Congo margin, one may question whether the state of stress in supra-salt formations is mainly controlled by salt tectonics, since the salt usually acts as a decoupling level that prevents the transmission and record of far-field crustal stresses. This study focuses on the analysis of an offshore wellbore core of the Albian, post-rift carbonates of the Sendji Fm that directly overlies the salt of the Aptian Loeme Fm in the Lower Congo Basin. Paleopiezometry based on stylolite roughness and mechanical twins in calcite was combined with fracture analysis, laser U-Pb dating of calcite cement, and burial modeling to unravel the tectonic and burial evolution of the Sendji Fm over time. The results of bedding-parallel stylolite roughness inversion constrain the range of depth over which the Sendji Fm strata deformed under a vertical principal stress s1 to 650-2800 m (median ~1100m). Projection of this depth range onto the Sendji burial model derived from TemisFlow™ basin modelling indicates that pressure solution was active from 105 to 12 Ma. Inversion of calcite mechanical twins measured within the early diagenetic cement (U-Pb age = 100 +/- 1Ma) yields two main states of stress: (1) an extensional stress regime with a horizontal σ3 trending ~E-W associated with sub-perpendicular N-S compression, and (2) a strike-slip stress regime with a horizontal σ1 trending ~E-W (changing from pure E-W compression to N-S extension through stress permutations). We interpret the former state of stress as local and related to the complex geometric interactions between moving halokinetic normal faults, while the latter presumably reflects the push effect of the Atlantic ridge, which prevailed from 12 Ma until present-day. Our results highlight that the stress history of the studied part of the offshore Lower Congo Basin passive margin has first been mainly dominated by burial and local normal faulting related to late Cretaceous to Miocene post-rift salt tectonics, then by a regional stress presumably originated from the far-field ridge push from ~12Ma onwards, which would indicate some mechanical re-coupling between the crust and the sedimentary cover during the Miocene.

Keywords: stress, paleopiezometry, calcite twins, stylolites, passive margin, salt.

How to cite: Zeboudj, A., Bah, B., Lacombe, O., Beaudoin, N. E., Gout, C., Godeau, N., and Girard, J.-P.: Paleostress and paleoburial history of a post-rift, supra-salt, carbonate reservoir offshore Congo (Atlantic): Insights from calcite twinning and stylolite roughness paleopiezometry., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7253, https://doi.org/10.5194/egusphere-egu22-7253, 2022.

EGU22-7305 | Presentations | TS2.2

A new free software to reconstruct stress trajectories: the Atmo-stress service 

Sofia Bressan, Olympia Gounari, Valsamis Ntouskos, Noemi Corti, Fabio Luca Bonali, Konstantinos Karantzalos, and Alessandro Tibaldi

The reconstruction of present-day stress and palaeostress trajectories is of paramount importance to study the tectonic regime and its evolution, in a specific area. Its comprehension is crucial also for seismic and volcanic hazard assessment, especially focusing on the shallow crust.

In the framework of the NEANIAS project (https://www.neanias.eu/), EU H2020 RIA, it has been developed the so called ATMO-Stress service (https://docs.neanias.eu/projects/a2-1-service/en/latest/), an open-source cloud service, currently hosted on the GARR Kubernetes platform, which allows to calculate stress trajectories in plain view, based on the concepts from Lee and Angelier (1994). It is designed to run on modern computers for both academics and non-academics purposes, spanning from research activity to oil and gas industries, natural hazard prevention and management.

The service is freely accessible at https://atmo-stress.neanias.eu/ and is designed to calculate the stress trajectories for a specific area, considering as input the same type of stress (e.g. σHmax or σHmin). Data input can be from different sources (e.g. field data, focal mechanism solutions, in-situ geotechnical measures). They must be listed in a homogeneous ASCII text file or Excel file format, including the geographic coordinates, azimuth of the stress and the angular error. The service is capable of processing data from local to regional scale. Following the principles from Lee and Angelier (1994), the trajectory calculation can be done using different parameters and settings. The outputs can be seen directly on the website and can be downloaded with file formats ready to be imported and analyzed in GIS environment and Google Earth.

How to cite: Bressan, S., Gounari, O., Ntouskos, V., Corti, N., Bonali, F. L., Karantzalos, K., and Tibaldi, A.: A new free software to reconstruct stress trajectories: the Atmo-stress service, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7305, https://doi.org/10.5194/egusphere-egu22-7305, 2022.

Reconstructing the brittle structural history of a complex strike-slip fault system remains a challenging process in paleostress reconstructions. Here, we investigated the small-scale brittle structures such as shear fractures and tension joints which are well developed in the Early Paleozoic Inkisi red sandstones in the “Pool” region of Kinshasa and Brazzaville, along the Congo River. The fracture network affects the horizontally bedded sandstones with alternating cross-bedded, horizontally bedded and massive layers. The fractures are particularly dense and of various orientation in the rapids of the Congo River just downstream Kinshasa and Brazzaville. They control the channels of the Congo River in its connection to the Atlantic Coast.

A total of 1150 factures have been measured and assembled into a single data file, processed using the Win-Tensor Program. They contain only a limited number of kinematic indicators for slip sense (displaced pebbles, irregularities on striated surfaces, slickensides) or extension (plume joints). Before interactive fault-slip data separation into subset and stress inversion, a kinematic data analysis evidenced at least three different phases of brittle deformation, each starting by the formation of plume joints and evolving into a strike-slip fault system. We used the principle of progressive saturation of the rock mass by the apparition of new faults or the reactivation of already existing ones during the successive brittle stages. We combined the stress inversion of fault-slip data, fault-slip tendency analysis and data separation in order to obtain well-separated data subsets, each characterized by its own paleostress tensor. The total data set can be explained by the action of 4 different brittle deformation and related paleostress stages, all of strike-slip type. There possible age is estimated from stratigraphic relations and the known geological history of the area.

The oldest stage developed in intact rock under NW-SE horizontal compression, probably before the Jurassic unconformity that affects the entire Congo Basin. It generated dominantly N-160°E striking left-lateral faults. The second stage generated dominantly new N050°E striking right-lateral faults, at a high angle from the ones of the previous stage, under NE-SW horizontal compression. They are estimated to be related to ridge push forces from the opening of the Atlantic Ocean during the Oligocene. The third stage, which corresponds to N-S horizontal compression, generated additional N030°E and N340°E conjugated fractures and reactivated the preceding fracture networks. A fourth and relatively minor system was also identified with WNE-ESE horizontal compression but its chronological relation with the other ones is not clear. 

How to cite: Delvaux, D., Miyouna, T., Boudzoumou, F., and Nkodia, H.: Using combined paleostress reconstruction and slip tendency for reconstructing the brittle structural history of a complex strike-slip fault system: Fault-controlled origin and evolution of the “Pool” area between Kinshasa and Brazzaville, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7401, https://doi.org/10.5194/egusphere-egu22-7401, 2022.

EGU22-8449 | Presentations | TS2.2 | Highlight

Numerical modelling of current state of stress in the Geneva Basin and adjacent Jura fold-and-thrust belt (Switzerland and France). 

Sandra Borderie, Jon Mosar, Louis Hauvette, Adeline Marro, Anna Sommaruga, and Michel Meyer

The Northern Alpine foreland is divided into two domains: the Molasse Basin and the Jura fold-and-thrust belt (FTB). The Mesozoic and Cenozoic sedimentary cover of this area is deformed by thrust-related folds and strike-slip faults. The main structures root in a basal Triassic décollement. The Geneva Basin, located in western Switzerland, is part of the Plateau Molasse (belonging to the Molasse Basin), and is limited to the NW by the Jura FTB, to the SW by the Vuache fault, and to the SE by the Mont Salève ramp related anticline and the Subalpine Molasse.

If current seismicity indicates that the Geneva Basin is tectonically active, few data regarding the state of stress in the area are currently available. The goal of this study is to densify the knowledge of the state of stress in the Geneva Basin and in the adjacent Jura FTB, by using numerical modelling.

The first part of the study is a regional study. In a 2D section, we study the impact of the friction along the basal décollement, on the localisation of deformation and on the associated stress field. Results indicate that depending on the friction, deformation will localise at the rear of the Mont Salève, in the Geneva Basin or at the frontal part of the Jura FTB. In the range of frictions where deformation localises in the Geneva Basin, the distribution of stress varies. Differential stress is higher and more localised for higher basal frictions.

The second part of the study is more local. The prototype section is based on seismic interpretation of a seismic surveys in the Geneva Basin. We study the impact of friction along the inherited faults on incipient deformation. Results indicate that a decrease in the fault’s friction allows forwards propagation of deformation and allows reactivation of inherited faults. If the friction in the faults is too low, deformation will localise at the first inherited fault (i.e. the Salève thrust in this case study). The stress fields vary depending on the localisation of deformation. Stress magnitudes are lower and more distributed when all faults have the same friction. The more deformation is localised on a structure, the more stress concentration is observed.

These results allow to better constrain the mechanical context of these sections and to populate this part of the Northern Alpine foreland with stress data.

How to cite: Borderie, S., Mosar, J., Hauvette, L., Marro, A., Sommaruga, A., and Meyer, M.: Numerical modelling of current state of stress in the Geneva Basin and adjacent Jura fold-and-thrust belt (Switzerland and France)., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8449, https://doi.org/10.5194/egusphere-egu22-8449, 2022.

EGU22-8886 | Presentations | TS2.2

Reconstructing stress magnitude evolution in deformed carbonates: a paleopaleopiezometric study of the Cingoli anticline (North-Central Apennines, Italy) 

Aurélie Labeur, Nicolas E. Beaudoin, Olivier Lacombe, Lorenzo Petraccini, and Jean-Paul Callot

Picturing the distribution of stress, in term of magnitude and orientation, during the development of a fold-and-thrusts belt is key for many fundamental and applied purposes, e.g., crustal rheology, orogen dynamics, fluid dynamics and prediction of reservoir properties. Specific meso- and micro-structures observed in fold-and-thrust belts and related forelands (i.e., faults, stylolites, veins and calcite twins), on top of being good markers of the deformation sequence that affected the rocks before, during and after folding and thrusting, can be used to access the past stress orientation and/or magnitude. This study reports the result of a paleopiezometric analysis of calcite twins and stylolite roughness documented in Mesozoic carbonates cropping out in the Cingoli anticline, an arcuate fold in the Umbria-Marche Apennine Ridge (UMAR), where a complex fracturing sequence was highlighted in a previously published study. The stylolite roughness inversion technique (SRIT) was applied to tectonic stylolites related to early folding layer-parallel shortening (LPS), and the calcite twin inversion technique (CSIT) was applied to cements from veins related to either foreland flexure or LPS. Both inversion processes require somehow the knowledge of the depth at which deformation occurred, as the vertical stress is an input for SRIT in the case of its application to tectonic stylolites, and as the differential stress magnitudes obtained by CSIT combined to vertical stress magnitude provides access to the absolute principal stress magnitudes. Building on a previously published time-burial path valid for the studied strata at the Cingoli anticline that also predicted the timing of each deformation stage, we quantify differential and principal stress magnitudes at the scale of the anticline. Beyond regional implications, our approach helps improve our knowledge of the past stress magnitudes in folded carbonate reservoirs.

How to cite: Labeur, A., Beaudoin, N. E., Lacombe, O., Petraccini, L., and Callot, J.-P.: Reconstructing stress magnitude evolution in deformed carbonates: a paleopaleopiezometric study of the Cingoli anticline (North-Central Apennines, Italy), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8886, https://doi.org/10.5194/egusphere-egu22-8886, 2022.

Shear zones associated with major thrust faults generally record overprinting of deeper crustal deformation signatures by shallower crustal signatures due to faults climbing up-section along the transport direction. In this study, we investigate the deformation signatures related to the shallow crustal conditions on one such major thrust, the Ramgarh thrust (RT) from Sikkim Himalayan Fold Thrust Belt (FTB). RT is an intermediate crustal thrust that has recorded a translation of ~58-65 km and overprinting of deformation structures. RT acts as the roof thrust of Lesser Himalayan duplex, hence got reactivated several times, and records a long deformation history.

In Sikkim Himalaya, the frontal most exposure of the RT is near Setikhola (N26° 56.178’, E88° 26.607’) as ~57m thick shear zone that exposes the lower Lesser Himalayan Daling quartzite and phyllite in the hanging wall over Gondwana sandstone in the footwall. The mean bedding is oriented ~72°, 298°, and the mean dominant cleavage is ~ 70°, 305°. The outcrop forms the overturned forelimb of a fault-bend antiform. The outcrop is strongly fractured. Based on the angular relationship with respect to the bedding, three sets of fractures were identified. Low angle fractures (< 30° to bedding) constitute ~20.23 %, moderate (30° – 60° to bedding) and high angle fractures (60°- 90° to bedding) constitute ~39.88% of the total fracture population. The fractures are uniformly distributed throughout the stretch of the shear zone. Daling quartzites accommodate more number of fractures than the phyllites. Preliminary investigation indicates that the thicker beds have higher fracture intensity than thinner beds. Few of the fractures were identified as opening mode fractures based on their association with the plumose structures. ~ 17.3% of the total measured fractures records slickenline lineations. These shear fractures reveal two clusters on the stereonet (Set 1: ~90°, 098°; Set 2: ~77°, 331°). They have a dihedral angle of ~54⁰ and set 1 and set 2 are oriented ~ 27⁰ and ~ 32⁰ to the bedding respectively. Based on preliminary analysis, the local maximum principal stress (σ1) is oriented sub-horizontally with a SSW trend. Interestingly, this estimate is in agreement with the current global stress orientations from the Eastern Himalaya, where σ1 is near horizontal and trends NNE – SSW (Larson et al., 1999).

How to cite: Jk, A. and Bhattacharyya, K.: Preliminary fracture analysis from the frontal most exposure of a major roof thrust in the Eastern Himalaya: Insights from the Ramgarh thrust, Sikkim Himalaya., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9168, https://doi.org/10.5194/egusphere-egu22-9168, 2022.

We estimate paleostress orientations (σ1, σ2 and σ3), stress ratios (φ) and driving pressure ratios (R′) from the extension veins exposed within the Buxa dolomite of the frontal Main Boundary thrust (MBT) sheet in the Siang valley, Arunanchal Lesser Himalaya. Based on the angular relationship with the bedding, the fractures and veins were divided into low-angle (<30°), moderate-angle (~30°-60°) and high-angle (>60°) sets. Observations in the field as well as at a microscopic level indicate that the high- and moderate-angle veins overprint the low-angle veins implying that the latter are the oldest. The high-angle veins are the most dominant set (~49%; mean orientation: ~23°, ~141°) followed by the moderate- (~31%; mean orientation: ~70°, ~176°) and the low-angle (~20%; mean orientation: ~58°, ~224°) set. The poles to the low- and high-angle veins define a clustered distribution in the stereoplot indicating that the pore fluid pressure (Pf) was less than the intermediate principal stress (σ2) during the formation of these vein sets. In contrast, the poles to the moderate-angle veins mark a girdled pattern in the stereoplot indicating that the pore fluid pressure (Pf) exceeded the intermediate principal stress (σ2) during their formation. On applying the stress inversion method (Yamaji et al., 2010) to the veins, 5 different generations of veins are revealed. Preliminary microstructural study indicates that the low-angle veins are dominantly quartz-rich, whereas the high-angle veins are dominantly calcite-rich indicating the presence of multiple generations of veins. The study also indicates the presence of blocky texture in the veins with the growth direction of the mineral grains at a high angle to the vein wall. Based on the stress ratio (φ), driving pressure ratio (R′) and the orientation of stress axes associated with each generation, the different generations of veins most likely formed under different stress conditions.

How to cite: Behera, S. S. and Bhattacharyya, K.: Characterization of vein-sets and estimation of stress orientations and stress ratios from the Buxa dolomite, Main Boundary thrust (MBT) sheet, Siang Valley, Arunanchal Lesser Himalaya, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9169, https://doi.org/10.5194/egusphere-egu22-9169, 2022.

 

Estimating deformation conditions from shear zone rocks is critical in understanding its complex deformation history. However, often the deformation conditions from mylonite provide information on the finite deformed state conditions. On the contrary, if there are veins preserved, they may record incremental strain stages during progressive deformation. Thus, we used veins as incremental strain markers to evaluate the spatial and temporal variation in deformation conditions along the transport direction of a major shear zone. We estimated vein attributes at the microscopic scale, deformation temperature, flow stress, and strain rate from the Pelling-Munsiari thrust in the Sikkim Himalaya. It is a regionally folded thrust that acts as the roof thrust of a complex Lesser Himalayan duplex. The PT zone is exposed as ~938 m and ~188 m thick quartz-mica mylonite zone at the hinterland-most (Mangan) and the frontal exposures (Suntaley) in eastern Sikkim, respectively. The PT zone is subdivided into three domains where the protomylonite domain is surrounded by mylonite domains on both sides.

We recognize three different vein-sets based on the angular relationship to the mylonitic foliation. At both the locations of the PT zone, the low-angle (0-30°) is the dominant vein-set followed by moderate-angle (30-60°) and high-angle (60-90°). Based on the cross-cutting relationship, we find high-angle vein set is the youngest. The low-angle vein-sets are dominant in both these locations. We observed multiple crack-and-sealed events in Mangan, indicating repeated failure and mineral precipitation. In contrast, we do not observe any such texture in the veins that are preserved in the frontal exposure of the PT zone. At both the PT zones, there are higher distribution of veins near the footwall. In the hinterland, veins record coarser grain sizes in the protomylonite domain than in the mylonite domain. However, we observed a different trend in the frontal exposure, where veins from the mylonite domain record coarser grain sizes. In both locations, quartz grains dominantly exhibit the subgrain rotation recrystallization mechanism. We semi-quantitatively estimate a first-order deformation temperature using the recalibrated quartz recrystallization thermometer (Law, 2014). In the hinterland, the low-angle vein-set records the highest deformation temperature. In contrast, high-angle veins record higher deformation temperature in the foreland. Following Stipp et al. (2003) and Twiss (1977), we estimate flow stress from recrystallized quartz grain-size piezometer. The high-angle (~24.71MPa) vein-set records the highest flow stress in the hinterland. In comparison, moderate-angle (~29.55MPa) veins record the highest flow stress in the foreland exposure. Following Hirth et al. (2001), we estimated similar strain rates (~10-15 sec-1) from both locations. The three sets of veins record different deformation conditions in both locations suggesting different incremental strain stages. Interestingly, the high-angle veins record the fastest strain rate (~6*10-15 sec-1) in the hinterland most exposure, whereas, in the frontal part the moderate-angle veins record the fastest strain rate (~9*10-15 sec-1).

How to cite: Ranjan, R. and Bhattacharyya, K.: Estimation of deformation temperature, flow stress, and strain rate from the veins of an internal shear zone: Insights from Pelling-Munsiari thrust, Sikkim Himalaya, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9170, https://doi.org/10.5194/egusphere-egu22-9170, 2022.

The North Anatolian Fault experienced large earthquakes with 250–400 years recurrence time. In the Marmara Sea region,
the 1999 (Mw=7.4) and the 1912 (Mw =7.4) earthquake ruptures bound the Central Marmara Sea fault segment. Using
historical-instrumental seismicity catalogue and paleoseismic results (≃ 2000-year database), the mapped fault segments, fault
kinematic and GPS data, we compute the paleoseismic-seismic moment rate and geodetic moment rate. A clear discrepancy
appears between the moment rates and implies a signifcant delay in the seismic slip along the fault in the Marmara Sea. The
rich database allows us to identify and model the size of the seismic gap and related fault segment and estimate the moment
rate defcit. Our modelling suggest that the locked Central Marmara Sea fault segment (even including a creeping section)
bears a moment rate defcit 6.4 × 1017 N.m./year that corresponds to Mw ≃ 7.4 for a future earthquake with an average
≃ 3.25 m coseismic slip. Taking into account the uncertainty in the strain accumulation along the 130-km-long Central fault
segment, our estimate of the seismic slip defcit being ≃ 10 mm/year implies that the size of the future earthquake ranges
between Mw=7.4 and 7.5.

Reference:

[1] Meghraoui, M., Toussaint, R. & Aksoy, M.E. The slip deficit on the North Anatolian Fault (Turkey) in the Marmara Sea: insights from paleoseismicity, seismicity and geodetic data. Med. Geosc. Rev. 3, 45–56 (2021). https://doi.org/10.1007/s42990-021-00053-w

How to cite: Meghraoui, M., Toussaint, R., and Aksoy, M. E.: Stress evolution and slip deficit on the North Anatolian Fault (Turkey) in the Marmara Sea: insights from paleoseismicity, seismicity and geodetic data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11676, https://doi.org/10.5194/egusphere-egu22-11676, 2022.

EGU22-13201 | Presentations | TS2.2

Joint inversion of tectonic stress and magma pressures using dyke trajectories 

Frantz Maerten, Laurent Maerten, Romain Plateaux, and Pauline Cornard
    In volcano-tectonic regions, dyke propagation from shallow magmatic chambers are often controlled by ambient perturbed stress field. The variations of the stress field result from combining factors including, but not exclusively, the regional tectonic stress and the pressurized 3D magma chambers. In this contribution, we describe and apply a new multiparametric inversion technique based on geomechanics that can invert for both the far field stress attributes and the pressure of magma intrusions, such as stocks and magma chambers, constrained by observed dyke orientations. This technique is based on a 3D boundary element method (BEM) for homogeneous elastic half-space where magma chambers are modelled as pressurized cavities. To verify this approach, the BEM solution has been validated against the known 3D analytical solution of a pressurized cylindrical cavity. Then, the effectiveness of this technique and its practical use, in terms of mechanical simulation, is demonstrated through natural examples of dyke network development affected by magma intrusions of two different volcanic systems, the Spanish Peaks (USA) and the Galapagos Islands (Ecuador). Results demonstrate that regional stress characteristics as well as pressure of magma chambers can be recovered from observed radial and circumferential dyke patterns.

 

How to cite: Maerten, F., Maerten, L., Plateaux, R., and Cornard, P.: Joint inversion of tectonic stress and magma pressures using dyke trajectories, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13201, https://doi.org/10.5194/egusphere-egu22-13201, 2022.

EGU22-13203 | Presentations | TS2.2

Late Cenozoic faulting deformation of the Fanshi Basin (Northern Shanxi rift, China), inferred from paleostress analysis of mesoscale fault-slip data 

Markos D. Tranos, Konan Roger Assie, Yu Wang, Huimin Ma, Kouamelan Serge Kouamelan, Eric Thompson Brantson, Liyun Zhou, and Yanick Blaise Ketchaya

The Fanshi Basin is one of the NE-SW-striking depocenters formed along the northern segment of the fault-bounded Shanxi rift. In order to understand the crustal driving stresses that led to the basin formation and development, a paleostress analysis of a large number of fault-slip data collected mainly at the boundaries of the basin was accomplished. The stress inversion of these data revealed three stress regimes. The oldest SR1 was a Neogene stress regime giving rise to a strike-slip deformation with NE-SW contraction and NW-SE extension. SR1 activated the large faults trending NNE-NE, i.e., (sub) parallel to the main strike of the Shanxi rift, as right-lateral strike-slip faults. It was subjected to the Shanxi rift before the activation of the Fansi Basin boundary fault, i.e., the Fanshi (or Wutai) fault, as a normal fault. The next is a short-lived NE-SW extensional stress regime SR2 in the Early Pleistocene, which shows the inception of the basin's extension. A strong NW-SE to NNW-SSE extensional stress regime SR3 governed the northern segment of the Shanxi rift since the Late Pleistocene and is the present-day extension. It gives rise to the current half-graben geometry of the Fanshi Basin by activating the Fanshi (or Wutai) fault as a normal fault in the southern part of the graben. Because of the dominance of the NW-SE to NNW-SSE extension, which is perpendicular to the NE-SW extension, mutual permutations between σ3 and σ2 due to inherited fault patterns might occur while the stress regime changed from SR1 to SR3.

How to cite: Tranos, M. D., Assie, K. R., Wang, Y., Ma, H., Kouamelan, K. S., Thompson Brantson, E., Zhou, L., and Blaise Ketchaya, Y.: Late Cenozoic faulting deformation of the Fanshi Basin (Northern Shanxi rift, China), inferred from paleostress analysis of mesoscale fault-slip data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13203, https://doi.org/10.5194/egusphere-egu22-13203, 2022.

EGU22-13406 | Presentations | TS2.2

Paleoburial and paleostress history of a carbonate syn-rift reservoir : constraints from inversion of calcite twins and stylolite roughness in the Toca formation (Lower Congo Basin, South Atlantic) 

Boubacar Bah, Olivier Lacombe, Nicolas Beaudoin, Jean-Pierre Girard, Claude Gout, and Nicolas Godeau

To construct accurate geological models of reservoirs and better predict their properties, it is critical to have a good understanding of the burial and stress history of the host sedimentary basin over time. Stress and strain are important factors influencing the preservation or reduction of reservoir porosity and permeability. One way to access the orientations and magnitudes of paleostresses is to use paleopiezometers. This study aims at reconstructing the stress and burial history of the syn-rift Barremian (130-125 Ma) Toca Fm in the Lower Congo basin (West African passive margin) using stress inversion of calcite mechanical twins and sedimentary and tectonic, bedding-parallel stylolite. This combined approach was applied to two oriented borehole cores drilled in a poorly deformed oil field, offshore Congo, and provided constraints on both paleostress orientations and magnitudes. The timing of the different paleostress regimes documented was derived from a burial-time model reconstructed by use of TemisFlowTM.

The inversion of calcite twins was performed on a widespread early diagenetic cement (dated 127.4 ± 4.9 to 123.1 ± 7.7 Ma by U-Pb LA-ICPMS) and revealed two types of stress regimes. (1) An extensional stress regime with σ1 vertical and σ3 oriented either N50°±20° or N120°±20°, and mean differential stresses of 45 MPa for (σ1-σ3) and 20 MPa for (σ2-σ3). The NE-SW (N50°±20) extensional direction, which restores to N100° after moving back Africa to its position at Barremian times, marks the syn-rift extension that led to the opening of the South Atlantic. The 120° direction (~N-S after restoration) possibly reflects local perturbation and/or σ2-σ3 permutations during rifting in response to tectonic inheritance. (2) A compressional or strike-slip stress regime with horizontal σ1oriented ~E-W (and associated N-S extension) and mean differential stresses of 40 MPa for (σ1-σ3) and 15 MPa for (σ2-σ3). This suggests that the basin underwent a post-rift compressional history during the continuous burial of the Toca formation possibly related to the Atlantic ridge push effects. For the first time, we also reconstructed paleostress orientations from “tectonic” bedding-parallel stylolites, that developed during a tectonic extensional phase. The results point to a NE-SW extension consistent with the direction of the syn-rift extension revealed by calcite twinning. In order to constrain the sequence of stress evolution, we used the results of sedimentary stylolite roughness inversion paleopiezometry, which documents that the burial-related pressure solution in the Toca Fm occurred in the 400-1700m depth range (dissolution along 90% of stylolites halting between 700 and 1000m). Projection of this depth range onto the TemisFlowTM reconstructed burial-time curve of the Toca Fm indicates that vertical pressure solution was active between 122 and 95 Ma, and therefore that σ1 switched from vertical to horizontal around 95 Ma. Our study reveals that the Toca Fm has undergone a complex polyphase stress history during burial, with stress regimes evolving from extensional to compressional/strike-slip. It also illustrates the great usefulness of combining stress inversion of calcite twins and stylolite roughness with a burial-time model to constrain the stress history of a deeply buried reservoir.

How to cite: Bah, B., Lacombe, O., Beaudoin, N., Girard, J.-P., Gout, C., and Godeau, N.: Paleoburial and paleostress history of a carbonate syn-rift reservoir : constraints from inversion of calcite twins and stylolite roughness in the Toca formation (Lower Congo Basin, South Atlantic), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13406, https://doi.org/10.5194/egusphere-egu22-13406, 2022.

The NNW-SSE trending Koziakas-Itamos Mts of Western Thessaly, Central Greece, constitute the innermost part of the External Hellenides, i.e., the Hellenic fold-and-thrust belt, formed from the Tertiary orogenic (alpine) processes due to collision between the Apulia and Eurasia plates. Along these mountains, large ophiolite masses have thrust towards WSW over Mesozoic carbonate and clastic rocks, which in turn thrust over the Tertiary flysch rocks of the Pindos Unit. The mountains bound the NW-SE trending late-alpine Mesohellenic Trough to the east, filled with Late Eocene to Miocene molasse-type sediments, and the younger Thessaly basin filled up with Neogene and Quaternary sediments.

 

A detailed paleostress reconstruction based on the fault-slip analysis and the stress inversion through the TR method (TRM) unravels a multi-stage deformation history for the innermost parts of the Hellenic fold-and-thrust belt. More precisely, the late orogenic faulting deformation temporally constrained in Late Oligocene to Middle Miocene was originally driven by stress regimes that define an ENE-WSW ‘real’ compression normal to the orogenic fabric associated with mainly NE-directed back thrusts. The compression shifted to ‘hybrid’ with the activation of oblique- and strike-slip faults. After that stage, the hybrid compression predominates with counterclockwise changes in the trend of the greatest principal stress axis (σ1) from ENE-WSW to NNE-SSW. The last stage of the late-orogenic faulting deformation is an NW-SE orogen parallel extension segmenting and differentiating the NNW-SSE orogenic fabric along its strike.

 

Post-orogenic faulting deformation is driven by extensional stress regimes that caused the basin-and-range topography and the formation of well-established basins filled up with Late Miocene and younger sediments like the Thessaly basin. In particular, an ENE-WSW pure extension normal to the orogenic fabric has been defined. A general counterclockwise rotation of the least principal stress axis (σ3) occurred, initially giving rise to NE-SW  extension-transtension during Late Miocene-Pliocene and NNE-SSW extension-transtension since the Quaternary.

How to cite: Neofotistos, P. and Tranos, M.: Multi-stage late- and post-orogenic deformation history of the innermost Hellenic fold-and-thrust belt from a detailed paleostress reconstruction (Koziakas-Itamos Mts., Western Thessaly, Central Greece), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13463, https://doi.org/10.5194/egusphere-egu22-13463, 2022.

EGU22-66 | Presentations | ERE5.2

Influence of brittle deformation on the permeability of granite: assessing the geothermal potential of crustal fault zones 

Lucille Carbillet, Michael J. Heap, Hugo Duwiquet, Luke Griffiths, Laurent Guillou-Frottier, Patrick Baud, and Marie Violay

Economically viable geothermal systems rely on the efficiency of fluid circulation and heat transfer. Permeable fault zones are therefore excellent candidates for geothermal exploitation. In crustal fault zones, hot fluids from depths that correspond to the brittle-ductile transition are brought to the surface via crustal-scale permeable fault zones and may therefore constitute a new kind of geothermal system. To assess their geothermal potential, we measured the permeability of reservoir rock during deformation to large strains (up to an axial strain of about 0.1) in the brittle regime - fault formation and sliding on the fault - by performing triaxial experiments on samples of well-characterised Lanhélin granite (France). Prior to deformation, samples were thermally-stressed to 700°C to ensure that their permeability was sufficiently high to measure on reasonable laboratory timescales. All experiments were conducted on water-saturated samples under drained conditions, at a constant pore pressure of 10 MPa and confining pressures of 20, 40, and 60 MPa (corresponding to a maximum depth of about 2 km), and at room temperature. Our data show that permeability decreases by about an order of magnitude prior to macroscopic shear failure. This decrease can be attributed to the closure of pre-existing microcracks which outweigh the formation of new microcracks during loading up to the peak stress. As the macroscopic shear fracture is formed, sample permeability increases by about a factor of two. The permeability of the sample remains almost constant during sliding on the fracture to large strains (corresponding to a fault displacement of ~7 mm), suggesting that the permeability of the fracture does not fall below the permeability of the host-rock. The permeability of the sample at the frictional sliding stress is lower at higher confining pressure (by about an order of magnitude between 20 and 60 MPa) but, overall, the evolution of sample permeability as a function of strain is qualitatively similar for confining pressures of 20−60 MPa. These experimental results will serve to inform numerical modelling designed to explore the influence of macroscopic fractures on fluid flow within a fractured geothermal reservoir.

How to cite: Carbillet, L., Heap, M. J., Duwiquet, H., Griffiths, L., Guillou-Frottier, L., Baud, P., and Violay, M.: Influence of brittle deformation on the permeability of granite: assessing the geothermal potential of crustal fault zones, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-66, https://doi.org/10.5194/egusphere-egu22-66, 2022.

EGU22-981 | Presentations | ERE5.2

Friction behavior of gabbro under hydrothermal conditions 

Wei Feng, Lu Yao, Rodrigo Gomila, Shengli Ma, and Giulio Di Toro

Fault friction is one of the most significant parameters controlling fault slip behavior and earthquake mechanics. Great success has been achieved in understanding the stability of fault slip, nucleation of earthquake and dynamic weakening mechanism in the past decades by performing low (~1 μm/s, sub-seismic conditions) to high (~1 m/s, seismic conditions) velocity friction experiments. However, extrapolating these experimental results to nature remains limited. In fact, for low velocity experiments, usually performed with tri-axial machines, though the hydrothermal conditions can be imposed, the shear displacement is limited to several millimeters neglecting the effect of cumulative displacement. For high velocity experiments aiming at reproducing coseismic fault slip, the implementation of hydrothermal conditions has been hindered by technical difficulties leaving high-velocity friction property of faults under realistic crustal conditions still ambiguous.

Here we exploited a Low to High Velocity rotary shear apparatus (LHV) equipped with a dedicated hydrothermal pressure vessel installed at the Institute of Geology, China Earthquake Administration, to investigate the frictional behavior of gabbro under realistic hydrothermal conditions. The samples were sheared at effective normal stresses of 10 MPa and 20 MPa, velocities (V) spanning from 1 μm/s to 0.1 m/s, displacement up to 3 m, under temperature conditions (T) up to 400 ℃ and pore pressure (Pf) up to 30 MPa. Our results showed that at T = 300 ℃ and Pf = 10 MPa (pore fluid as liquid), dramatic slip weakening happened at all tested velocities. At slip initiation the friction coefficient increased sharply to a peak value (~0.7±0.05), then decayed toward a residual value of ~0.35. Instead at T = 400 ℃ and Pf =10 MPa (pore fluid as vapor), we observed that friction remained high (~0.7) at V < 10 mm/s and slip weakening only occurred for V ≥ 10 mm/s. For experiments at T = 400 ℃ and Pf =30 MPa (pore fluid in supercritical conditions), slip weakening behavior occurred in most cases. The evolution of friction coefficient with displacement was complex, e.g., two peaks, large variations. Moreover, comparative experiments conducted at relatively low temperature suggested that mechanisms leading to the dramatic weakening under such a wide velocity range could be closely linked with both fluid-rock interactions and the physical state of the fluid. However, what exact fluid-rock reactions are involved is still an open question, which will be investigated by further microstructural and mineralogical analysis. The unique frictional behavior observed in this study challenges the results obtained from small-displacements experiments in many aspects and improves our understanding on friction behavior of faults in geothermal applications.

How to cite: Feng, W., Yao, L., Gomila, R., Ma, S., and Di Toro, G.: Friction behavior of gabbro under hydrothermal conditions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-981, https://doi.org/10.5194/egusphere-egu22-981, 2022.

Upper Cretaceous (Turonian and Cenomanian) carbonates in the Münsterland Cretaceous Basin, NW Germany, have become a target for geothermal energy production in recent years. These carbonates are present at depths of up to ca. 1,800 m in the region of the city of Münster in the center of the basin (e.g. Münsterland-1 well) and at depths beyond 2,000 m in the so-called Vorosning Depression. They represent the shallowest calcareous strata within the sedimentary succession of the Münsterland Basin and the underlying Rhenish Massif. Previous industrial drilling campaigns mostly focused on potential hydrocarbon gas reservoirs of the Upper Carboniferous. In the context of geothermal reservoir exploration, analog studies in outcrops of the Cretaceous carbonates are a prerequisite for reservoir quality assessment since subsurface/in situ data of these stratigraphic units, and especially petrophysical properties, are very sparse, not accessible or even absent in some areas. Investigations of quarries with Cretaceous carbonates mostly focused on paleontological and facies related research in the past rather than on their petrophysical properties. Three quarries in the Lengerich and Oerlinghausen areas, all at the northern margin of the basin, were now sampled for petrophysical laboratory experiments of Cenomanian and Turonian rocks. Additionally, scanline investigations, which involve collecting information such as length and aperture and others of each fracture along a line intersecting the rock mass, capturing of Unmanned Aerial Vehicle (UAV, commonly called drones) footage and laser scanning was performed at the three Cenomanian outcrops in Lengerich and one Turonian outcrop in Oerlinghausen. Further UAV footage and laser scans were collected for other outcrops within the quarries. The facies of the investigated rocks are expected to be comparable to what can be anticipated in the center of the Münsterland Basin according to the current paleogeographical understanding. Their analysis can thus be helpful in predicting the conditions that may be encountered in the central part of the basin. However, since the data was collected at the northern margin of the basin, the influence of the Osning Fault Zone (Upper Cretaceous inversion tectonics) has to be taken under consideration when further interpreting the data. The drone footage was processed, and Virtual Outcrop Models (VOM) were created using Agisoft Metashape. The point clouds of both, the laser scanning and processed UAV footage, were analyzed using the open-source package CloudCompare with its Facets and Compass plugins. The plugins allowed the detection of differently oriented fracture sets in the point clouds. This allowed to characterize fracture distributions and the comparison between the virtual outcrop data and the scanline data. Subsequently, the parameters of the fracture distributions of these structural features together with the laboratory measurements on bulk petrophysical properties were combined in a discrete fracture network (DFN). This representation of the reservoir, and in particular the 3D distribution of permeability, will be used for reservoir analog modelling to characterize fluid flow in the subsurface.

How to cite: Slama, S., Jüstel, A., Lippert, K., and Kukla, P.: Characterizing fracture networks and petrophysical bulk properties of carbonates from the margin of the Münsterland Cretaceous Basin, NW Germany, from outcrops, virtual outcrop models and laboratory testing, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2503, https://doi.org/10.5194/egusphere-egu22-2503, 2022.

EGU22-3309 | Presentations | ERE5.2

CT scan of a small-scale fault network: 3D fault geometries and their interpretation 

Inbar Vaknin and Andy Nicol

Fault surfaces and networks have been shown to have complex geometries. Outcrop observations are typically two-dimensional and limited in size by the exposure dimensions, while three-dimensional (3D) seismic data lack the resolution to characterize and quantify fault complexities on length scales less than a decameter. Defining the geometries of faults and their networks (high-resolution in 3D) is critical for understanding the interactions between faults and fluids. This presentation will examine the geometries of a network of small-scale normal faults displacing (by <1 cm) well bedded sand and silt layers in the Mount Messenger and Mohakatino formations in Taranaki, New Zealand. A 3D model of faulting was produced from high-resolution multi-band CT scanner (MARS Bioimaging Ltd.) imagery of a 10x8x3 cm rock sample. The digitally sectioned rock contains calcified fault rock that is distinguishable from wall rock and mapped throughout the rock volume at sub-millimeter scale. Fault-rock thicknesses vary by in excess of an order of magnitude, with greatest thicknesses at fault steps and fault bends. Fault zones comprise a series of lenses that have strike lengths greater than dip lengths and lens shapes that are often elongate parallel to bedding. The fault network is highly connected with branch lines, fault steps and fault bends most often sub-parallel to bedding. These observations suggest that mechanical heterogeneity of beds may partly control the geometries of both fault zones and the fault network. At the time of formation, the interconnected fault network likely increased bedding-parallel permeability (at scales from sub-millimeter and above) along fault zones.

How to cite: Vaknin, I. and Nicol, A.: CT scan of a small-scale fault network: 3D fault geometries and their interpretation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3309, https://doi.org/10.5194/egusphere-egu22-3309, 2022.

EGU22-3414 | Presentations | ERE5.2

Fluid pressure diffusion in fractured media: insights from harmonic and non-harmonic periodic pumping tests 

Nicolás D. Barbosa, Nima Gholizadeh Doonechaly, and Jörg Renner

Fractures can significantly impact fluid flow and pore pressure distribution in the subsurface. Understanding the mechanisms and conditions influencing their ability to transport fluids and to promote pore pressure diffusion is key for many activities relying on fracture-controlled flow such as, for example, enhanced geothermal systems. In situ characterization of these properties is typically done by performing hydraulic tests in selected intervals of a borehole and their interpretation relies on the solution of a linear pressure diffusion equation. However, it has been shown that the hydraulic behavior of fractures as well as the associated near borehole flow regimes can be largely affected by the coupling between the solid deformation and fluid pressure upon injection/production. In this work, we explore these effects by performing a series of harmonic injection tests (HIT) as well as non-harmonic production tests (NHPT) in a packed-off interval of a borehole containing multiple natural fractures. The borehole is located in the Bedretto Underground Laboratory for Geosciences and Geoenergies in Switzerland and penetrates granitic rock mass. The two kinds of tests consist of a periodic repetition of the same injection or production protocol. Flow rates, interval pressures as well as pressures above and below the double-packer probe are recorded at the surface. An important advantage of periodic testing is that it permits a continuous tracking of hydraulic changes during the test. For our study, we conducted a so-called injectivity analysis, in which the phase-shift (time delay) and amplitude ratio between flow rate and interval pressure are used to infer effective hydraulic properties. We performed over 200 periodic tests including both HIT and NHPT with a large range of periods (7.5 s to 1800 s) as well as varying mean interval pressures (~1300 kPa to 2100 kPa) and flow oscillation amplitudes. As a result, we obtained a robust constraint of the radial flow regime prevailing in the fractures. Overall, we found that results from HIT and NHPT are in very good agreement despite the remarkably different injection protocols. For all cases, a prominent and consistent period dependence of phase shifts and amplitude ratios of flow rates and interval pressure was observed, in which both increase as the oscillatory period decreases. Amplitude ratios showed almost no variation with mean interval pressure regardless of the injection protocol. In contrast, a prominent pressure dependence of the phase shifts is captured by the HIT but not the NHPT data. Using the pressure-independent NHPT results, we reconstruct the general hydraulic response of the tested fractured section, which can be well represented by an analytical solution of the pressure-diffusion equation. This general trend explains the HIT data as well, although evidence of significant variations that are correlated with the amplitude of the pressure oscillations points to the predominant role of hydromechanical coupling effects on the fluid pressure diffusion process.

How to cite: Barbosa, N. D., Gholizadeh Doonechaly, N., and Renner, J.: Fluid pressure diffusion in fractured media: insights from harmonic and non-harmonic periodic pumping tests, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3414, https://doi.org/10.5194/egusphere-egu22-3414, 2022.

Flow through faults and fractures has been studied extensively in the context of hydrocarbon exploration and production, to understand charge and migration, hydrocarbon column heights and fault transmissibility. Learnings have typically been captured in pragmatic models, such as the Shale-Gouge-Ratio (SGR) concept, providing dimensionless or relative fault permeability definitions based on limited subsurface data.

The resulting coarse predictions are however not suitable for geoenergy applications, including CO2 sequestration (CCS) or underground hydrogen storage (UHS), where injection into a storage reservoir requires assurance that the injected fluids or gases will not leak out of the storage complex via faults or fractured caprocks. The conventional fault seal analyses do not provide this containment assurance.

A new paradigm is required for characterizing faults and fractures in geoenergy projects, focused on derisking leakage of injected fluids and gases along faults. Such approach is not necessarily about accurately predicting the permeability of a fault or fracture, but rather about understanding what geometric properties and mechanical or chemical mechanisms would contribute to either permeable or sealing behaviour of faults. Improved insights in any of these areas would help in screening fault leakage risks in prospective subsurface geoenergy projects.

Analogue data, both from outcrops for geometric fault attributes and from the lab for mechanical and chemical properties, can help gain those fundamental insights into what controls fault leakage. Properties can be quantified and processes studied at a level of detail that cannot be matched by in-situ subsurface datasets, particularly not in the context of geoenergy systems, where operational subsurface projects are still limited. Outcrop studies can help improve our understanding of vertical connectivity, with focus on lower-permeability ductile rocks analogues to typical reservoir seals. Lab studies and in-situ experiments can provide insights into injected fluids such as CO2 or H2 affect the mechanical and chemical integrity of faults and subsequent flow behaviour. For geoenergy systems in particular, experiments should focus on the impact of rapid pressure or temperature cycling. Induced seismicity is another potential threat to containment integrity and requires further research to understand what fault geometries are most prone to reactivation as well as how reactivation affects the sealing behaviour of a fault.

In recent years, integrated studies such as the multi-scale, multiphysics ACT-DETECT project have started to provide some answers to these questions, resulting in novel insights and workflows that provide a first-order fault leakage risk assessment that can be used to identify ideal storage sites. However, with the envisioned increase in the number of geoenergy projects to meet carbon emission reduction targets, the need for more refined screening criteria will increase too as the flexibility in selecting ideal storage locations will decrease.

How to cite: Bisdom, K.: A new paradigm for flow through faults and fractures in the context of geoenergy, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3553, https://doi.org/10.5194/egusphere-egu22-3553, 2022.

At the Äspö hard rock underground laboratory in Sweden, six in situ hydraulic fracturing experiments took place at 410 m depth. A multistage hydraulic fracturing approach is tested with a low environmental impact, e.g., induced seismicity. The idea is to mitigate induced seismicity and preserve the permeability enhancement process under safe conditions. The fractures are initiated by two different injection systems (conventional and progressive). An extensive sensor array is installed at level 410 m, including simultaneous measurements of acoustic emissions, electric self-potential, and electromagnetic radiation sensors. The monitoring catalog includes more than 4300 acoustic emission events with estimated magnitudes from the continuous monitoring setup (in-situ sensors between 1-100 kHz). The experiment borehole F1 is drilled in the direction of Shmin, perpendicular to the expected fracture plane. Two electromagnetic radiation sensors are installed and aligned to (i) Shmin and (ii) the expected fracture plane with a sampling rate of 1 Hz and a frequency range between 35-50 kHz. The self-potential sensors are installed at level 410 with a distance of 50-75 m from the borehole F1, including nine measuring probes and one base probe. A second self-potential setup is deployed at level 280 m in the far-field with a distance of 150-200 m from F1. The self-potential data were measured with a sampling rate of 1 Hz. For the first time (to our knowledge), the results of electric and electromagnetic monitoring of two hydraulic stimulation at meter-scale are presented.

How to cite: Haaf, N. and Schill, E.: Electric self-potential and electro-magnetic monitoring of hydraulic fracturing experiments in the Äspö Hard Rock Laboratoy, Sweden., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3837, https://doi.org/10.5194/egusphere-egu22-3837, 2022.

EGU22-6166 | Presentations | ERE5.2

Assessing damage pattern at depth near the Alpine Fault, New Zealand 

Mai-Linh Doan, Virginia Toy, Rupert Sutherland, and John Townend

 

The Alpine Fault is the principal component of the plate boundary through the South Island of New Zealand, separating the Pacific and Indo-Australian Plates. It is recognised internationally as an important site for studying earthquake physics and tectonic deformation, as it produces large (M7-8) earthquakes approximately every 330 years and last ruptured in 1717. Therefore, the fault is considered to be late in its seismic cycle. It accommodates dextral-slip at a rate of 26 mm/yr with reverse slip at a maximum rate of 10 mm/yr in its central part, thus exhumed a fossil ductile shear zone, that was damaged brittlely during its exhumation.

 

The central Alpine Fault is the focus of the Deep Fault Drilling Project (DFDP), sponsored by the International Continental Drilling Project, which takes advantage of its globally rare tectonic situation to determine what temperatures, fluid pressures, and stresses exist within a plate-boundary fault in advance of an expected large earthquake. During DFDP phase II in 2014, an ~ 900 m drilled well that encountered an exceptionally high geothermal gradient (120 °C/km was measured in the borehole), was extensively characterized by repeated electric and sonic logs. These logs enable detailed study of fracture patterns near a major fault. The more than 19 km of logs run within the borehole gathered datasets covering, among others, thermal resistivity, sonic velocities, acoustic borehole imaging, and electrical resistivity. They show that the hanging wall is extensively fractured, explaining the high geothermal gradient measured in the borehole by lateral flow of hot water deep seated in the mountains.

 

We particularly focus on seven dual laterolog logs that provide a robust and reproducible dataset from which to determine the positions and orientations of conductive fractures. From these, different patterns of damage could be identified within the well. A first pattern consists of an extensive and dense pattern of isolated fractures that could be identified throughout the borehole. A second pattern suggests that decametric  zones of low resistivity localize damage and focus thermal anomalies. This suggests hierarchy of damage zone evolution of the damage zone of the Alpine Fault. A possible explanation is an initial phase of diffuse fracturing (pattern 1) that is followed by subsequent alteration of the major shear zone, which focuses fluid and heat flow (pattern 2).

How to cite: Doan, M.-L., Toy, V., Sutherland, R., and Townend, J.: Assessing damage pattern at depth near the Alpine Fault, New Zealand, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6166, https://doi.org/10.5194/egusphere-egu22-6166, 2022.

The regionalization of hydraulic properties like specific yield/storativity or permeability in fractured crystalline rock is of utmost importance for a variety of applications, such as geothermal and other resources, waste disposal or underground construction. However, accurate predictions for these properties – particularly for undrilled sites – bear a high degree of uncertainty as already direct observations through hydraulic in-situ tests show a variance of about 2 orders of magnitude at any depth (Achtziger-Zupančič et al., 2017).

Permeability-depth relationships using multiple log-log regressions conducted on an extended version of the worldwide permeability compilation of crystalline rocks (roughly 30000 entries in Achtziger-Zupančič et al., 2017; now consisting of about 50000 single in-situ permeability measurements to depths of 2000 mbgs) indicate that depth is generally the most important geological factor, resulting in a permeability decrease of three to four orders of magnitude in the investigated depth range. Specific yield and storativity show a similar but less pronounced depth trend. Beside depth, most influential factors for permeability in crystalline rock are the long-term tectono-geological history described by geological province which locally is overprinted by current seismotectonic activity as determined by peak ground acceleration (Achtziger-Zupančič et al., 2017). Although petrography might be of local importance, only a low impact has been observed for the global dataset, besides lithologies allowing for karstification. Ongoing vertical movements – particularly resulting from glacial isostatic adjustment – alter the permeability trend with depth.

The latter shows distinct trends starting at about logK -14.5 to -14.8 m² at 100 mbgs and showing diversion of about 1.5 orders of magnitude at 1 km depth between areas without significant uplift and areas with uplift of more than 4 mm/y as determined from a probabilistic interpolation of global geodetic measurements (Husson et al., 2018). The difference is attributed either to glacial loading (normal faulting or reactivation) induced destruction preserved during glacial induced rebound and/or uplift-caused horizontal fracture growth which improved connectivity in the rock mass. Areas undergoing subsidence show similar trends like highly uplifting areas which is attributed to efficient normal faulting induced destruction of the rock mass.

References:

Achtziger-Zupančič, P, Loew, S and Mariéthoz, G (2017). A new global database to improve predictions of permeability distribution in crystalline rocks at site scale. JGR: Solid Earth 122(5): 3513-3539.

Husson, L, Bodin, Th, Spada, G, Choblet, G and Kreemer, C (2018). Bayesian surface reconstruction of geodetic uplift rates: Mapping the global fingerprint of Glacial Isostatic Adjustment. J Geodyn 122: 25-40.

How to cite: Achtziger-Zupancic, P.: The influence of glacial induced adjustment and other geological factors on the depth distribution of permeabilities in crystalline rocks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7157, https://doi.org/10.5194/egusphere-egu22-7157, 2022.

EGU22-7835 | Presentations | ERE5.2

Fracture energy variations of rocks: a mechanical investigation 

Antoine Guggisberg, Mathias Lebihain, and Marie Violay

Crack propagation is critical for the assessment of the strength of rocks. Linear Elastic Fracture Mechanics (LEFM) theory is commonly used to describe its propagation. However, the variation of the fracture energy, its key parameter, is generally poorly understood as its experimental measurements are influenced by temperature, stress biaxiality, and rupture velocity. This indicates other dissipative processes may occur in the vicinity of the crack.

We conduct Modified Ring Tests (MRT) on Carrara marble to investigate these mechanisms. MRT provides stable mode I crack propagation under controlled velocity and stress biaxiality conditions. Coupled with a compliance method calibrated through Finite Element Method (FEM), we obtain multiple local measurements of the fracture energy within a single test. FEM also provides estimation of stress biaxiality levels as well as higher order terms of the Williams’ expansion of the stress field.

The method is validated on PMMA through Digital Image Correlation (DIC) techniques. Experiments on Carrara marble show that the stress biaxiality can directly influence the fracture energy measurements. A microscopic investigation on marble is performed to look for micro-mechanisms which may cause observed variations of fracture energy.

How to cite: Guggisberg, A., Lebihain, M., and Violay, M.: Fracture energy variations of rocks: a mechanical investigation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7835, https://doi.org/10.5194/egusphere-egu22-7835, 2022.

Between 2018 and 2021, the STIMTEC and STIMTEC-X hydraulic stimulation experiments were conducted at 130 m depth in the Reiche Zeche underground research laboratory in Freiberg/Germany. The STIMTEC experiment was designed to investigate the rock damage resulting from hydraulic stimulation and to link seismic activity and enhancement of hydraulic properties in anisotropic metamorphic gneiss. The following STIMTEC-X experiment aimed at better constraining the stress field in the rock volume to investigate the mechanisms leading to induced acoustic emission (AE) activity. Here, we present results from focal mechanism analysis of high-frequency (>1 kHz) AE events, associated with brittle deformation at the cm- to dm-scale induced by hydraulic stimulations. Focal mechanisms are calculated using full moment tensor inversion of first P-wave amplitudes using the hybridMT package. We use polarity and amplitude data from a (near) real-time seismic monitoring network, consisting of AE sensors, AE-hydrophones, accelerometers, and one broadband sensor. We observe changes in the predominant type of faulting from reverse faulting focal mechanisms during the frac and refrac cycles to oblique strike-slip focal mechanisms observed during subsequent high-volume fluid-injections performed during periodic pumping test. The observed differences in dominant focal mechanisms are consistent with the activation of less favourably oriented faults at increased pore fluid pressure during extended periodic pumping. We observe a reverse-faulting stress regime from focal mechanism inversion of low-volume injection stages for different boreholes, representative for the rock volume (typically ~5 m radially) surrounding the injection intervals. In contrast, stress field estimates obtained from analysing the instantaneous shut-in pressures of hydraulic stimulations in different boreholes indicate a regime change from thrust to strike-slip faulting in the investigated rock volume. The reservoir complexity seen at the scale of the experiment (30m x 30m x 20m) is large and is reflected by the significant variations in AE event activity in response to stimulation as well as small-scale rock, stress and structural heterogeneities.

How to cite: Boese, C., Kwiatek, G., Renner, J., and Dresen, G.: Stress field observations from hydraulic fracturing and focal mechanism inversion at the STIMTEC underground research lab, Reiche Zeche mine, Germany, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7986, https://doi.org/10.5194/egusphere-egu22-7986, 2022.

Fluid flow in low-porosity/permeability reservoir rocks such as tight carbonates is mostly restricted to structural discontinuities (e.g. faults, fractures, karstified zones). Fault zones, in particular in such rocks, offer both suitable fluid flow pathways, but may also act as impermeable barriers. The heterogeneous permeability structure of fault zones, however, impedes pre-drilling investigations of exploration targets by numerical models. A better understanding of the factors that control the fluid flow and the heterogeneity of permeability distribution along fault zones in tight reservoirs is a pre-requisite for the definition of drilling targets.

In this study, a hydraulic field laboratory with a volume of 30 m x 30 m x 20 m was set up in a quarry in SE Germany to investigate the influence of fault zones on the general permeability structure of tight carbonates. The test field contained three WNW-ESE-striking, repeatedly reactivated normal faults with offsets in the order of <1 m and two roughly perpendicularly oriented NNE-SSW-striking fracture corridors. Fault zones and fracture corridors were targeted by 62 wells. Wells that exhibited a decent hydraulic connection the to the overall conductive fracture network were logged (e.g. borehole image logs, FWS, etcs.) and in selected wells hydraulic tests were conducted. Water levels were measured both during static conditions and during testing. Due to the density of wells we were able to constrain the controlling factors for fluid flow along and across the fault zones. Damage zones were considered as conduits while the fault core was expected to be impermeable. These general assumptions could be confirmed by our tests, however we found some exceptions. While fluid flow in general is restricted to few, well-connected fractures, the majority of the fractures are dead ends, solely serving as storage for fluids. With increasing displacement and complexity of the fault zone, enhanced permeability parallel to the fault zone could be inferred. At larger offsets, where a thicker fault core develops, fhe fault core itself acts as barrier and fractures and fracture corridors do not penetrate the faults. We think that this is related to the presence of the much less competent fault core of a certain thickness which is able to accommodate the brittle deformation. Where the faults offset is less than ~0.4 m, the integrity of the fault seal is breached by fracture corridors, cross cutting the faults. This is clearly shown by the pressure distribution in static and transient conditions. Faulting, hence leads to a compartmentalization of the reservoir, where the compartments do either communicate or interact with significant delay.

The information and data received from the conducted field tests furthermore serve as input parameters and validation for a newly developed numerical approach that aims to simulate fluid flow in this type of geological settings, results of which will be presented in an additional presentation by our project partners.

How to cite: Freitag, S., Bauer, W., Stollhofen, H., and Hähnel, L.: (1)   Transmissivity of fault zones in tight carbonates – results from a reservoir-scale hydraulic field laboratory in the Franconian Alb, SE Germany, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8457, https://doi.org/10.5194/egusphere-egu22-8457, 2022.

In outcrop-based fracture studies, the quantification of fracture intensity is often limited by the limitations of the manual sampling technique, characterized by punctual measurements (e.g. sampling spot, scanline, scanwindow) and moderate biases (e.g. fracture length truncation, technical and personal errors). The proximal remote sensing technologies, as terrestrial or Uncrafted Aerial Vehicle (UAV)-based LiDAR and photogrammetry, can help to overcome these limitations due to the possibility to obtain high-resolution and accurate quantitative data from the digital twin of the outcrop, the so-called Digital Outcrop Model (DOM). The DOMs can be very useful in outcrop-based fracture studies because their analysis allows to obtain several quantitative information with manual and/or automatic methods and with continuity in each position of the outcrop, increasing the accuracy of the fracture intensity estimations. However, due to the novelty of DOM technology and the lack of well-defined DOM-based fracture sampling procedures, these huge fracture datasets are often difficult to study and interpret, and therefore, the benefits of the DOM cannot be fully exploited. 

For this reason we present a complete workflow based on the DICE (Discontinuity Intensity Calculator and Estimator) open-source MATLAB© application that allows to quantitatively characterize the fractures of rocky outcrops from the 3D Digital Outcrop Models (DOMs). The proposed workflow consists in the following steps: (1) fracture mapping onto the 3D DOMs; (2) calculation of the fractures dimension, position and orientation; (iii) determination by DICE algorithm of the discontinuity parameters (persistence/dimension, distribution, spacing and intensity) using different 3D sampling techniques (3D scanline, 3D circular scan window and spherical scan volume). The differences of these sampling techniques and the fracture intensity parameters that can be obtained (p10, p21, p32) are discussed, showing the advantages and limitations of each DICE method.

How to cite: Menegoni, N., Giordan, D., and Perotti, C.: 3D Digital Outcrop Model-based quantification of fracture intensity: the Discontinuity Intensity Calculator and Estimator (DICE) open-source application, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10207, https://doi.org/10.5194/egusphere-egu22-10207, 2022.

EGU22-10259 | Presentations | ERE5.2

CHENILLE: Coupled beHavior undErstaNdIng of fauLts: from the Laboratory to the fiEld 

Audrey Bonnelye, Pierre Dick, Fabrice Cotton, Rüdiger Giese, Yves Guglielmi, Damien Jougnot, Jan Henninges, Grzegorz Kwiatek, and Stefan Lüth

The understanding of the coupled thermo-hydro-mechanical behaviour of fault zones in naturally fractured reservoirs is essential both for fundamental and applied sciences and in particular for the safety assessment of radioactive waste disposal facilities. In this framework, an international research program callled CHENILLE was built to address key questions related to the impact of high temperatures (up to 150°C) on shear zones as well as fault reactivation processes in shale formations. The project includes a thermally controlled in situ fluid injection experiment on a strike-slip fault zone outcropping atIRSN’s Tournemire Underground Research Laboratory (URL) and a series of laboratory experiments to understand the chemical and structural evolution occurring within the fault zones during the thermal and hydraulic loading. The in situ experiment includes a heating system installed around an injection borehole will enable a precise and controlled incremental increase of the thermal load. The injection borehole will be equiped with a Step-Rate Injection Method for Fracture In-Situ Properties (SIMFIP) probe, in order to perform step pressure tests. The probe will not only measure the flow and pressure rate inside the injection borehole but also allow to monitor the borehole’s 3D deformation during the hydraulic and thermal loading steps. In addition, an array of seismicifferent sensors will be implemented around the injection area to measure the seismic and aseismic deformation induced either by thermal or by hydraulic loading. The seismic monitoring system is composed of Acoustic Emission (sensitive between 1kHz and 60kHz) enabling monitoring fracturing processes of sub-decimeter size. Furthermore, a fibre optic network will be installed in the heating boreholes to measure spatially temperature variationsvia Distributed Temperature Sensing technology in the investigation area. Active seismic surveys, using different source types, are scheduled before and after the experiment to determine the structural network but also to detect the appearance of new structures triggered from the hydro-thermal pressurization of the fault by tomography and reflection seismic methods. The overall goal of our work is to present the interaction between the different geophysical methods that we are using as well as some preliminary results. A first part is dedicated to the description of the fault zone through field and core samples observations as well as borehole to borehole correlation, whereas the second is dedicated to preliminary results on the thermal diffusion expected in the fault.

How to cite: Bonnelye, A., Dick, P., Cotton, F., Giese, R., Guglielmi, Y., Jougnot, D., Henninges, J., Kwiatek, G., and Lüth, S.: CHENILLE: Coupled beHavior undErstaNdIng of fauLts: from the Laboratory to the fiEld, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10259, https://doi.org/10.5194/egusphere-egu22-10259, 2022.

EGU22-12748 | Presentations | ERE5.2

Crack healing in salt: time-resolved 3D microtomography 

Yuntao Ji, Christopher Spiers, Suzanne Hangx, Hans de Bresser, and Martyn Drury

Rocksalt caverns are considered or already used as storage for nuclear waste, petroleum, hydrogen, CO2, and compressed air energy because of the low permeability and potential of fracture healing of salt. An important concern is the sealing capacity. Undisturbed rocksalt deposits in nature generally have very low permeability. However, as a result of excavation stress, a network of fractures will be induced within the rocksalt formation, increasing the permeability. At low deviatoric stresses and/or at low effective stresses, a fracture network filled with brine is expected to heal, and the connectivity of the brine-filled network, consisting of grain boundaries, pores, and microcracks, is expected to decrease over time. The driving force for such a healing process is the tendency to reduce the interfacial energy by reducing the total interfacial area. In order to assess the rate of pore reconfiguration and permeability evolution in damaged salt and to capture the key process of crack network evolution during healing, we employ time-resolved 3D microtomography to study the long-term evolution of the fracture network of small-scale polycrystalline rocksalt samples. We found that precipitation prefers to occur in open spaces in the early stage of healing, such as new cracks. As a result, flat cracks evolve into zigzag cracks, which create narrow throats, thereby reducing the permeability of the crack network. Our study also offers a way to testify the thermodynamic models quantitatively.

How to cite: Ji, Y., Spiers, C., Hangx, S., de Bresser, H., and Drury, M.: Crack healing in salt: time-resolved 3D microtomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12748, https://doi.org/10.5194/egusphere-egu22-12748, 2022.

EGU22-12855 | Presentations | ERE5.2

Direct shear experiments to investigate the effect of chemical alteration on fault frictional behaviour in granitic geothermal systems 

Nick Harpers, Nathaniel Forbes Inskip, Michael John Allen, Daniel Faulkner, Hannes Claes, Andreas Busch, and Sabine den Hartog

Enhanced temperature gradients related to locally elevated heat production in granitic plutons offer the potential for low carbon geothermal energy production. Cornwall in SW England hosts several granitic plutons that are the subject of current geothermal projects (United Downs Deep Geothermal Power [UDDGP] Project and Eden Project). These projects target fault zones in crystalline rock that provide pre-existing pathways for fluid flow. Reinjection of cooler fluids into the reservoir after heat extraction may result in chemical disequilibrium with the host rock, potentially driving precipitation or chemical alteration. Such changes could influence the frictional properties of the fault zones, and hence require modifications to numerical risk-based calculations of the likelihood, or not, of induced seismicity.

In order to study the effects of such alterations, we have conducted a series of direct shear experiments under representative in-situ conditions on Cornish Carnmenellis granite samples which have undergone varying degrees of natural chemical alteration. The direct shear experiments were conducted on gouges (grain size < 125 μm) and at effective normal stresses of 80-105 MPa, pore fluid pressures of 25-50 MPa and temperatures of 16-180 °C. These conditions are relevant for the depths where the UDDGP project injection and production boreholes intercept the Porthtowan Fault zone, the assumed main conduit for fluid flow. In each test, load point velocity was stepped between 0.3 μm/s, 1 μm/s and 3 μm/s, and shear resistance of the sample was measured to determine the stability of sliding and thus the likelihood of induced seismicity as a function of degree of alteration. Initial shear tests at room temperature suggest little difference in the frictional response of altered and unaltered samples.

How to cite: Harpers, N., Forbes Inskip, N., Allen, M. J., Faulkner, D., Claes, H., Busch, A., and den Hartog, S.: Direct shear experiments to investigate the effect of chemical alteration on fault frictional behaviour in granitic geothermal systems, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12855, https://doi.org/10.5194/egusphere-egu22-12855, 2022.

EGU22-12888 | Presentations | ERE5.2

A semi-automatic workflow for structural interpretation of large point-cloud Digital Outcrop Models on complex fractured metamorphic rocks (Aosta Valley, Italy) 

Bruno Monopoli, Andrea Bistacchi, Federico Agliardi, Gloria Arienti, Giovanni Dal Piaz, Davide Bertolo, and Stefano Casiraghi

Characterization of fracture networks, both in fault zones and in the less-fractured background, is essential for the analysis and modelling of mechanical and hydraulic properties of the rock mass (i.e. rock plus fractures). Here we present our experience in characterizing fracture networks and other structural features on large outcrops of different basement and metamorphic cover units in the Penninic, Austroalpine and Helvetic units of the Aosta Valley. These units show a variety of lithological, mechanical, and rheological characteristics and were subjected to different ductile and brittle tectonic evolution, resulting in complex combinations of compositional layering, metamorphic schistosity, and fracture networks.

Our methodology is based on a combination of traditional field surveys and remote-sensing techniques such as ground-based and UAS photogrammetric surveys, and terrestrial or helicopter laser scanning. The first task, whose importance is too often overlooked, is represented by selecting outcrops that are representative in terms of structural and lithological properties of a larger rock volume, based on a thorough knowledge of regional structural geology and tectonics. The field survey is carried out with traditional techniques, paying attention to the kinematics, relative chronology, and mineralization (e.g. veins or mineral coatings) of structures. These features, that are often overlooked in fracture studies, are fundamental to frame the evolution of a complex schistosity and fracture network, to separate tectonic fractures with respect to those related to slope dynamics, and to develop predictive models of fracturing at depth (where slope-related fracture will not be present). At the same time, remote-sensing datasets are collected. The choice of the survey technique (terrestrial vs. aerial, photogrammetry vs. laser scanning) depends on various conditions, but in all cases the output is a point cloud DOM, colorized with RGB values, that should have a density (points/area) sufficient to characterize the smallest relevant structural features. From this, also textured surface DOMs and/or DEM plus orthophotos (for almost flat outcrops) can be obtained.

The first step of DOM analysis is carried out “manually”, selecting facets and traces with suitable software tools (e.g. Compass plugin in CloudCompare). This allows selecting different sets of structures, characterizing their orientation statistics, and assigning them to sets defined in the field (with kinematics, chronology, etc.). This step also allows understanding how well the structural features recognized in the field are represented in the DOM. The second step of DOM analysis consists in an automatic segmentation (in case of a point cloud) or tracing (in case of a DEM of triangulated surface textured with images) with algorithms calibrated with results of the manual interpretation. Overall, this results in a supervised semi-automatic workflow, allowing to extract huge structural datasets in a reasonable time, maintaining the connection with kinematic and chronological observations carried out in the field.

The fracture datasets can be eventually characterized with tools allowing to measure statistical distributions of different parameters of the fracture sets using virtual scanlines and/or scanareas, and these distributions can be used to model different properties of the fracture networks or generate stochastic DFN models.

How to cite: Monopoli, B., Bistacchi, A., Agliardi, F., Arienti, G., Dal Piaz, G., Bertolo, D., and Casiraghi, S.: A semi-automatic workflow for structural interpretation of large point-cloud Digital Outcrop Models on complex fractured metamorphic rocks (Aosta Valley, Italy), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12888, https://doi.org/10.5194/egusphere-egu22-12888, 2022.

EGU22-575 | Presentations | GD6.1

Strain relaxation around stressed quartz inclusions in garnet 

Hugo van Schrojenstein Lantman, David Wallis, Mattia Bonazzi, Jay Thomas, Maartje Hamers, Martyn Drury, and Matteo Alvaro

The measurement of residual stresses in exhumed rocks yields valuable information about metamorphic temperature and pressure, deformation and rheology, and stress state. However, the state of elastic strain and stress at the surface of a sample does not necessarily correspond to the state well below the surface. When a sample under elastic strain is cut, polished, or otherwise prepared for analysis, a part of the constraining rock is removed, allowing for the partial relaxation of the elastic strain. To be able to work with residual elastic strain and stress with analytical methods that probe the upper few microns of a sample, the process of strain relaxation must be well understood.

For this work we used high-angular resolution EBSD to analyse stressed quartz inclusions in natural garnet from a range of settings, and in several samples grown in piston-cylinder experiments that were previously analysed with Raman spectroscopy for inclusion pressures. The experimental samples are not expected to have undergone plastic deformation in the garnet during cooling, as the majority of the pressure within the inclusion built up during decompression at room temperature. Additionally, the inclusion pressures in buried inclusions matches what is expected for the experimental conditions, suggesting no plastic yielding. Thus, in these samples we can isolate elastic strain from potential plastic deformation. One of the experimental samples was analysed with TEM to test this expectation.

Forescatter images reveal topographical effects resembling quartz and adjacent garnet “extruding” out of the sample. Furthermore, rotations of the quartz lattice and the garnet lattice immediately around the quartz inclusion are observed. The rotation axis of the misorientation generally lies in the plane of the sample surface. TEM analysis revealed a number of dislocations in experimental garnet where these were not expected. However, a significant degree of bending of a wedge of garnet between the original sample surface and a quartz inclusion is also observed.

The dislocations observed with TEM do not fit with the model of the experiments. Also, the formation of dislocations before sample preparation does not explain the dependence of the rotation axis on the surface orientation. A likely scenario for the deformation measured with EBSD is that the partial relaxation of elastic strains in stressed quartz inclusions in garnet as result of sample preparation induced local distortion of the inclusion and host. Additionally, the persistence of topographical features related to this relaxation despite several steps of polishing suggests that relaxation is not instantaneous but occurs over time.

How to cite: van Schrojenstein Lantman, H., Wallis, D., Bonazzi, M., Thomas, J., Hamers, M., Drury, M., and Alvaro, M.: Strain relaxation around stressed quartz inclusions in garnet, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-575, https://doi.org/10.5194/egusphere-egu22-575, 2022.

EGU22-1247 | Presentations | GD6.1

Fast resetting of zircon in garnet inclusion pressures: implications for elastic geothermobarometry. 

Nicola Campomenosi, Boriana Mihailova, Ross John Angel, Marco Scambelluri, and Matteo Alvaro

The contrast in the thermoelastic properties between one inclusion and its surrounding host is commonly exploited to back-calculate the pressure (P) and temperature (T) conditions of inclusion entrapment. This is elastic thermobarometry and it is based on the elastic properties of minerals rather than chemical equilibrium. The effect of inclusion confinement is the inclusion residual pressure (P-inc), which can be determined via Raman spectroscopy. For a given host-inclusion system, a specific P-inc corresponds a P-T line along which the confinement effects between the two crystals disappear: the isomeke. By definition, this line potentially represents the P-T conditions of inclusion entrapment. Away from the isomeke, the inclusion exhibits over- or under-pressure with respect to the external pressure. The position and slope of the isomeke can be calculated using the equations of state of both the host and the inclusion [1].

In this contribution, we show how zircon-in-garnet isomekes can be partially investigated via in-situ Raman spectroscopy at high T and ambient P by comparing the evolution of the Raman peak position of the inclusion with respect to a free zircon crystal at the same temperature. Several zircon inclusions in pyrope-rich garnets from the Dora-Maira whiteschists (Western Alps) were heated up and brought from the over- to the under-pressure domain across their corresponding isomeke. At temperatures above the isomeke, we found that zircon inclusions in garnet can be reset on the timescale of laboratory experiments: after cooling down the P-inc was different from the original. We interpret this reset as the result of viscous relaxation at the host-inclusion boundary [2] and annealing of submicron dislocations of the garnet host at high temperature. Importantly, for similar heating rate and T range, viscous relaxation occurs more easily when the inclusions are in the under-pressure domain. This suggest that original confinement effects of zircon in a garnet host whose exhumation path mostly occurs within the inclusion under-pressure domain can be easily reset to record P-T conditions on the retrograde path, while those from a garnet host whose exhumation path mostly occurs within the inclusion over-pressure domain can be better preserved. Therefore, since the isomekes of zircon with garnet are steep in P-T, this system may be more reliable for high T and low P terranes for which the exhumation path passes directly or quickly into the over-pressure domain [3]. On the other hand, for UHP domains such as Dora-Maira resetting occurs [4] due to the exhumation path being steep and thus in the under-pressure domain until low pressures.   

[1] Angel et al. 2015 Journal of Metamorphic Geology33(8), 801-813. [2] Zhong et al. 2020 Solid Earth11(1), 223-240.  [3] Gilio et al. 2021 Journal of Metamorphic Geology 10.1111/jmg.12625 [4] Campomenosi et al. 2021 Contributions to Mineralogy and Petrology176(5), 1-17  

This work was supported by the Alexander von Humboldt foundation and the ERC-StG TRUE-DEPTHS grant (number 714936) to M. Alvaro

How to cite: Campomenosi, N., Mihailova, B., Angel, R. J., Scambelluri, M., and Alvaro, M.: Fast resetting of zircon in garnet inclusion pressures: implications for elastic geothermobarometry., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1247, https://doi.org/10.5194/egusphere-egu22-1247, 2022.

EGU22-2449 | Presentations | GD6.1

Hybridization of magmas by break down of partially molten granitic rock and its assimilation 

Pavlina Hasalová, Karel Schulmann, Anne-Sophie Tabaud, and Jitka Míková

During orogenic processes continental crust experiences significant partial melting. Repeated thermal pulses or fluctuation in fluid content can even cause multiple anatectic events that result in complex intrusion suits. The Vosges Mountains (NE France) reveal two chronologically and geochemically distinct tectono-magmatic events. An early major pulse of Mg‒K magmatism was followed ten millions years later by development of a magma-rich detachment zone and intrusion of Central Vosges Granite forming a felsic MASH zone. This MASH zone is characterized by the production of a large quantity of anatectic melts that interacted with the older Mg‒K granites and surrounding granulites and metasedimentary rocks. We aim to understand how such hybridization processes impact on the crustal rocks rheology, deformation as well as its geochemistry and geochronology. Three different granite varieties were distinguished: (i) the older Mg‒K granite end-member that is coarse-grained with a high proportion of feldspar phenocrysts, zircon U-Pb ages of 340 Ma and specific geochemical signature; (ii) Medium-grained type has a smaller amount of phenocrysts and shows advanced brecciation where fine-grained Pl+Kfs+Qtz form discontinuous corridors to an interconnected network surrounding fractured phenocrysts. Its geochemical signature suggests that this represents a mixing of Mg−K and Central Vosges granites, as confirmed by the presence of both inherited (340 Ma) and younger (330‒310 Ma) zircon domains; (iii) Isotropic medium-grained granite that shows geochemical signature typical for the Central Vosges Granite in which younger zircon domains (310‒320 Ma) dominate over inherited xenocrysts (340 Ma). These three granite varieties represent different stages of magma hybridization by the break up of the older Mg‒K granite by the younger Central Vosges Granite magmas. The interaction between new melt and previously crystallized granitoids results in variety of granite textures, fabrics, chemical compositions, isotopic signatures and deformational behavior. In summary, the resulting signature is result of interplay of melt transfer and interaction in the MASH zone.

How to cite: Hasalová, P., Schulmann, K., Tabaud, A.-S., and Míková, J.: Hybridization of magmas by break down of partially molten granitic rock and its assimilation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2449, https://doi.org/10.5194/egusphere-egu22-2449, 2022.

EGU22-3549 | Presentations | GD6.1

Evolution of P-wave velocities during antigorite dehydration at pressures up to 2.5GPa 

Alexandre Schubnel, Arefeh Moarefvand, Julien Gasc, Damien Deldicque, and Loïc Labrousse

Antigorite dehydration is considered as one of the potential triggering mechanisms of intermediate depth earthquakes in subduction zones. Here, the evolution of p-wave velocities were measured during antigorite dehydration experiments at pressure and temperature conditions representative of the upper mantle (1 to 2.5 GPa) for the first time.

Experiments were realized on a natural antigorite serpentinite from Corsica (Gasc et al. 2011), using a 3rdgeneration Griggs-type apparatus equipped with p-wave velocity ultrasonic monitoring (Moarefvand et al. 2021).Velocities were measured maintaining constant hydrostatic pressure conditions at  1, 1.5, 2 and 2.5 GPa, and slowly heating the sample beyond dehydration temperatures. At each pressure conditions, two experiments were carried out at a maximum temperature of 650°C or 700°C respectively, in order to investigate reaction kinetics and equilibrium overstepping. Experiments were quenched once the dehydration was completed, in order to preserve the microstructure.

In all our experiments, P-wave velocity decreased dramatically at the onset of dehydration.  This important drop in elastic properties is related to the fracturing and porous space generated by water release. At 700°C temperature, observed velocity drops were faster, and more pronounced compared to experiments performed at 650°C, indicating that the dehydration reaction progress was faster and more important. The velocity drop also got smaller with increasing pressure, but remained noticeable, even at 2.5GPa, a pressure at which the reaction volume change is negative. This indicates that even in the absence of fluid overpressures, the reaction is accompanied by an important amount of microcracking/softening. Recovered samples were then analyzed using scanning electron microscopy (SEM) and Electron backscatter diffraction (EBSD). With these microstructural data, the final reaction progress/advancement was estimated and we show that in situ measurements of p-wave velocity represent a good proxy for reaction progress and kinetics.

Our study opens up the door to a vast domain, where mineral reactions kinetics could be monitored in situ outside the synchrotron environment, via a direct access to elastic properties. It also reveals our need to apply state of the art effective medium theory modeling of porous and cracked aggregates when computing elastic properties of hydrating/dehydrating mineral assemblages. Finally, the elastic softening observed upon dehydration, even above 2GPa, tends to confirm the dehydration stress transfer model (Ferrand et al. 2017) for intermediate depth earthquake triggering.

 

references:

- Ferrand, Thomas P., et al. "Dehydration-driven stress transfer triggers intermediate-depth earthquakes." Nature communications 8.1 (2017): 1-11.

- Gasc, Julien, et al. "Simultaneous acoustic emissions monitoring and synchrotron X-ray diffraction at high pressure and temperature: Calibration and application to serpentinite dehydration." Physics of the Earth and Planetary Interiors189.3-4 (2011): 121-133.

- Moarefvand, Arefeh, et al. "A new generation Griggs apparatus with active acoustic monitoring." Tectonophysics816 (2021): 229032.

How to cite: Schubnel, A., Moarefvand, A., Gasc, J., Deldicque, D., and Labrousse, L.: Evolution of P-wave velocities during antigorite dehydration at pressures up to 2.5GPa, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3549, https://doi.org/10.5194/egusphere-egu22-3549, 2022.

EGU22-4325 | Presentations | GD6.1

Pervasive melt migration in hot continental crust – numerical models 

Petra Maierová, Pavlína Hasalová, Karel Schulmann, and Pavla Štípská

The common view of melt transport in the continental crust involves an initial stage of percolation along grain boundaries, melt segregation into leucosomes and dykes, coalescence of small melt conduits into larger ones and quick nearly vertical melt flow leading to formation of plutons. An entirely different style of melt migration was described in the Bohemian Massif, eastern European Variscan belt. There, a sequence of metaigneous migmatites was described where veins are lacking, leucosomes are rare and relics of melt are spread along grain boundaries. Textural, geochemical and compositional variations in these rocks show that they formed due to equilibration with melt coming from an external source, and that pervasive flow along grain boundaries was the dominant mechanism of melt transport.

The question arises, at what conditions this style of melt transport can operate and what consequences the different styles of melt transport have on the crustal-scale tectonics. We address this question by means of a 2D crustal-scale model of two-phase flow using the code ASPECT (aspect.geodynamics.org). The system of pores through which the melt flows is not resolved in our model and it is described only by its permeability. A low permeability describes material with pores along grain boundaries while a high permeability corresponds to a system of leucosomes, dykes or cracks

For different material properties and thermal conditions we obtain different styles of melt migration and characteristics of the modeled crust. The melt can form a diffuse zone in the lower–middle crust, km-scale waves of high melt fraction gathering into sub-vertical channels, or a horizontal zone with high melt fraction in the middle crust. The lower crust is depleted and the middle crust is enriched in incompatible elements, and composition of the middle crust typically shows km-scale variations. The compositional variations are obtained even in the models with low permeability that corresponds to the melt percolation along grain boundaries, in agreement with the characteristics of the Bohemian migmatites.

How to cite: Maierová, P., Hasalová, P., Schulmann, K., and Štípská, P.: Pervasive melt migration in hot continental crust – numerical models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4325, https://doi.org/10.5194/egusphere-egu22-4325, 2022.

EGU22-4494 | Presentations | GD6.1

Large-strain elastoplastic formulations for host-inclusion systems with applications to elasto-thermobarometry and geodynamic models 

Evangelos Moulas, Konstantin Zingerman, Anatoly Vershinin, Vladimir Levin, and Yuri Podladchikov

Elastic thermobarometry has been at the forefront of research during the last decade. Using state-of-the-art spectroscopic and diffraction methods it has been possible to assess the residual elastic strain of mineral inclusions in an in-situ manner (Mazzucchelli et al., 2021; Zhong et al., 2019). The interpretation of residual stress/strain and its extrapolation to geological conditions requires mechanical models, that are based on continuum mechanics, which provide the range of pressure-temperature (P-T) conditions where host and inclusion are under homogeneous stress. This set of conditions may correspond to the entrapment conditions if the system is purely elastic. In the case of viscous/plastic relaxation of the host-inclusion system, the inferred P-T conditions represent apparent-entrapment conditions that could lie anywhere between the conditions of the true entrapment and the conditions of viscous/plastic relaxation (Moulas et al., 2020; Zhong et al., 2020). Thus, the interpretation and validity of elastic barometry strongly relies on the purely elastic behavior of the host-inclusion system.

The commonly employed elastic solutions assume a linear-elastic behavior and deal only with small-strain approximations. However, large values of residual stresses/strains may indicate that the range of decompression for such host-inclusion systems requires the incorporation of material/geometric non-linearity. In this work, we provide new numerical and analytical solutions for the non-linear, elasto-plastic behavior of host-inclusion systems. Our analytical solutions are based on new published models that describe the Neo-Hookean behavior of materials and reduce to the Murnaghan equation of state when the deformation is purely volumetric (Levin et al., 2021). We find that for the range of residual pressures that is commonly employed in barometric applications (<1GPa) the incorporation of geometric non-linearity does not influence the results significantly. Nevertheless, the incorporation of plasticity and the combined non-linear elastic and plastic behavior may lead to results that render elasto-thermobarometry inapplicable for very large compression/decompression ranges. Our results can be useful for benchmarking: a) models relevant to elasto-thermobarometry and b) geodynamic models that require the treatment of large volumetric deformations during the exhumation from lithospheric/mantle depths.

References

Levin, V.A., Podladchikov, Y.Y., Zingerman, K.M., 2021. An exact solution to the Lame problem for a hollow sphere for new types of nonlinear elastic materials in the case of large deformations. European Journal of Mechanics - A/Solids 90, 104345. https://doi.org/10.1016/j.euromechsol.2021.104345

Mazzucchelli, M.L., Angel, R.J., Alvaro, M., 2021. EntraPT: An online platform for elastic geothermobarometry. American Mineralogist 106, 830–837. https://doi.org/10.2138/am-2021-7693CCBYNCND

Moulas, E., Kostopoulos, D., Podladchikov, Y., Chatzitheodoridis, E., Schenker, F.L., Zingerman, K.M., Pomonis, P., Tajčmanová, L., 2020. Calculating pressure with elastic geobarometry: A comparison of different elastic solutions with application to a calc-silicate gneiss from the Rhodope Metamorphic Province. Lithos 378–379, 105803. https://doi.org/10.1016/j.lithos.2020.105803

Zhong, X., Andersen, N.H., Dabrowski, M., Jamtveit, B., 2019. Zircon and quartz inclusions in garnet used for complementary Raman thermobarometry: application to the Holsnøy eclogite, Bergen Arcs, Western Norway. Contributions to Mineralogy and Petrology 174, 50. https://doi.org/10.1007/s00410-019-1584-4

Zhong, X., Moulas, E., Tajčmanová, L., 2020. Post-entrapment modification of residual inclusion pressure and its implications for Raman elastic thermobarometry. Solid Earth 11, 223–240. https://doi.org/10.5194/se-11-223-2020

How to cite: Moulas, E., Zingerman, K., Vershinin, A., Levin, V., and Podladchikov, Y.: Large-strain elastoplastic formulations for host-inclusion systems with applications to elasto-thermobarometry and geodynamic models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4494, https://doi.org/10.5194/egusphere-egu22-4494, 2022.

EGU22-6103 | Presentations | GD6.1 | Highlight

The role of mechanics in the modelling of common rock microstructures 

Lucie Tajcmanova, Yury Podladchikov, and Ivan Utkin

Understanding rocks at the microscale is essential to comprehending Earth's history and making reasonable predictions about how planetary processes may change in the future.  

Advanced models for complex rock microstructures, such as symplectites or a development of exsolution lamellae, have been developed (Kuhl & Schmid, 2007; Petrishcheva & Abart, 2009). Despite of this recent valuable progress in our understanding of these microstructures, the mechanisms controlling its evolution especially from slowly cooled rocks are still not complete.

Commonly, such models focus solely on the chemical process. Interestingly, mechanics, i.e. stress and pressure redistribution, may also play an important role on microstructure evolution. In this contribution, we investigate the coupled, chemo-mechanical, effect for representative rock microstructures. We provide a comparison between purely chemical vs. coupled chemo-mechanical systems and provide predictions on the evolution of the given microstructures in 3D.

References:

Kuhl, E., Schmid, D.W. (2007). Computational Modeling of Mineral Unmixing and Growth. Comput Mech 39, 439–451.

Petrishcheva, E., & Abart, R. (2009). Exsolution by Spinodal Decomposition I: Evolution Equation for Binary Mineral Solutions with Anisotropic Interfacial Energy. American Journal of Science, 309(6), 431-449.

 

How to cite: Tajcmanova, L., Podladchikov, Y., and Utkin, I.: The role of mechanics in the modelling of common rock microstructures, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6103, https://doi.org/10.5194/egusphere-egu22-6103, 2022.

EGU22-7325 | Presentations | GD6.1

A multiscale model for coupled chemical reaction and deformation of porous rocks 

Viktoriya Yarushina and Yury Podladchikov

Coupled hydro-mechano-chemical (HMC) modeling is a topic of active ongoing research in various branches of Earth sciences and subsurface engineering. In engineering applications, HMC modeling is used to assess the feasibility of permanent CO2 storage in mafic and ultramafic rocks. The deformation and stresses building during the reaction is believed to induce fracturing, increase permeability and thus promote extensive reactions between CO2 and host rock. CCS in depleted reservoirs faces challenges related to possible CO2 leakage through old plugged and abandoned wells. When CO2 reaches the well, old cement compositions react with cement, compromising well integrity due to chemical degradation. In geology, coupled reactions and deformation are involved in melt extraction and migration, influencing the dynamics of volcanic systems and the evolution of subduction zones.

A large focus of previous studies was whether or not it is possible to achieve 100% of the reaction. Common reactive transport models predict that the reaction product will clog the pores, which will stop the fluid flow and thus further reactions. However, recent developments suggest that reaction progress depends on the assumed reaction kinetics and the constitutive models used in coupled models. Models that account for solid volume change as in mineral replacement reactions have a much higher potential for preserving porosity than the common dissolution-precipitation model, thus predicting the complete reaction. It is often assumed that reaction processes are transport-dominated, i.e., that all dissolved material is carried away by pore fluid. Then it precipitates on the available pore space leading to clogging and permeability reduction. However, recent observations suggest that while some reactions might be associated with dissolution and precipitation at the nano-scale, aqueous species transport is limited, and reaction products do not precipitate in the pores but rather stay attached to the primary mineral. Thus, the overall effect is the same as in mineral replacement reactions.

Using a combination of effective media theory and irreversible thermodynamics approaches, we propose a new model for reaction-driven mineral expansion, which preserves porosity and limits unrealistically high build-up of the force of crystallization by allowing inelastic failure processes at the pore scale. To fully account for the coupling between reaction, deformation, and fluid flow, we derive macroscopic poroviscoelastic stress-strain constitute laws that account for chemical alteration and viscoelastic deformation of porous rocks. These constitutive equations are further used with macroscopic conservation laws to illustrate the mutual impact of reactive transport and mechanical deformation on simple 1D examples of wellbore stability and fluid transport.

How to cite: Yarushina, V. and Podladchikov, Y.: A multiscale model for coupled chemical reaction and deformation of porous rocks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7325, https://doi.org/10.5194/egusphere-egu22-7325, 2022.

EGU22-8033 | Presentations | GD6.1

Modelling focused fluid flow: What matters? 

Lawrence Hongliang Wang, Viktoriya M. Yarushina, and Yury Podladchikov

Two-phase flow equations that couple solid deformation and fluid migration have opened new research trends in geodynamical simulations and modelling of subsurface engineering operations. The physical nonlinearity of fluid-rock systems and strong coupling between flow and deformation in such equations lead to interesting predictions such as the spontaneous formation of focused fluid flow in ductile/plastic rocks. However, numerical implementation of two-phase flow equations and their application to realistic geological environments with complex geometries and multiple stratigraphic layers is challenging. Here, we present an efficient pseudo-transient solver for two-phase flow equations. We first study the focused fluid flow under the viscous regime without considering the elasticity. The roles of material parameters, reservoir topology, geological heterogeneity, and porosity are investigated. We show that focused fluid channels are the natural outcome of the flow instability of the two-phase system with a low ratio (< 0.1) between shear viscosity and bulk viscosity. We also confirm the previous studies that  decompaction weakening is necessary to elongate the porosity profile. The permeability exponents play the dominant role in the speed of wave propagation. The numerical models study fluid leakage from high porosity reservoirs into less porous overlying rocks. Geological layers present in the overburden do not stop the propagation of the localized channels but rather modify their width, permeability, and growth speed. We further validate our conclusions by modelling the full two-phase system with viscoelastic rheology and elastic solid and fluid compressibility (Yarushina et al., 2015). The Deborah number (De), solid (Ks), and fluid (Kf) bulk moduli are thus introduced into the governing equations. We found that the elasticity makes a difference when the Deborah number approaches one by speeding up the channel propagation. At the same time, its effect is rather limited when Deborah's number is small (e.g., 0.1). The effects of compressibility of the solid and fluid, on the other hand, are not found significant within the reasonable ranges of the bulk moduli.

 

How to cite: Wang, L. H., Yarushina, V. M., and Podladchikov, Y.: Modelling focused fluid flow: What matters?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8033, https://doi.org/10.5194/egusphere-egu22-8033, 2022.

EGU22-8422 | Presentations | GD6.1 | Highlight

Chronometry of a nappe-scale thermal event inferred by thermobarometry and viscous relaxation of quartz inclusion pressure (Adula nappe, Alps) 

Xin Zhong, Marisa Germer, Alexandra Pohl, Vincent Könemann, Olga Brunsmann, Philip Groß, Jan Pleuger, and Timm John

The Adula nappe is located at the eastern flank of the Lepontine dome in the Swiss Alps. It consists mainly of orthogneiss and paragneiss with intercalated lenses of eclogite, amphibolite and metasediments. Previous petrological studies on the peak pressure and temperature (P-T) conditions yield somewhat inconsistent results, particularly the pressure in the southern part of the nappe, but in general exhibit an increasing trend in both P-T towards the south. In this work, we applied zirconium-in-rutile thermometer and quartz-in-garnet Raman elastic barometer to constrain the P-T conditions using samples covering most of the nappe with high spatial coverage within the 600 km2 area to obtain an internally consistent dataset. Based on the results of zirconium-in-rutile thermometer, the temperature gradually increases from the north at ca. 540 °C to the south at ca. 680 °C. Using the quartz-in-garnet elastic barometer, the calculated entrapment pressure increases from ca. 2.0 GPa to ca. 2.2 GPa from the north to the middle-south region of the Adula nappe, but rapidly falls to ca. 0.8-1.2 GPa towards the southern region, where the temperature exceeds ca. 650 °C. It is speculated that due to the temperature increase towards the south, viscous relaxation became activated that led to an apparent drop of the recorded residual quartz inclusion pressure. This suggests that by applying a pure elastic model to high temperature conditions, one may potentially underestimate of the formation pressure of garnets. Therefore, this study may provide information on the limit of the quartz-in-garnet (pure) elastic barometry technique. Moreover, it may offer a potential opportunity to constrain the duration of the near-isothermal decompression path if a viscoelastic model can be applied, which requires not only the equation of state of minerals but also the creep behavior of the inclusion-host system.

How to cite: Zhong, X., Germer, M., Pohl, A., Könemann, V., Brunsmann, O., Groß, P., Pleuger, J., and John, T.: Chronometry of a nappe-scale thermal event inferred by thermobarometry and viscous relaxation of quartz inclusion pressure (Adula nappe, Alps), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8422, https://doi.org/10.5194/egusphere-egu22-8422, 2022.

EGU22-8776 | Presentations | GD6.1

Local variations of metamorphic record from compositionally heterogeneous rocks: Inferences on exhumation processes of (U)HP-HT rocks (Cima di Gagnone, Adula-Cima Lunga unit) 

Stefania Corvò, Matteo Maino, Antonio Langone, Filippo Luca Schenker, Leonardo Casini, Sandra Piazolo, and Silvio Seno

The record of metamorphic conditions may be highly heterogeneous in spatially close rocks with different composition and rheology. The Cima di Gagnone area (Central Alps) represents an example of ultrahigh–pressure and high–temperature ultramafic lenses enveloped within amphibolite–facies metasediments. Structural investigations demonstrate that the rheologically strong ultramafics and eclogites and weak metapelites experienced a common Alpine deformation history in a single tectonic unit, excluding their coupling within a tectonic mélange (Maino et al., 2021). New structural, microstructural and petrological analyses and thermodynamic modelling results on the metasediments, confirming that all rocks generally experienced medium pressure and medium temperature conditions of 1.0–1.2 GPa and 640–700 °C, followed by a retrograde stage around 0.6–0.8 GPa and 600–675 °C. However, significantly higher P–T conditions of 1.3–3.0 GPa and 750–850 °C are locally developed close to the rheological boundary depicted by the micaschists-peridotite contact (Corvò et al., 2021; Piccoli et al., 2021). Rock and mineral chemistry changes during growth of new mineral phases indicate a local melt/fluid interaction (i.e., metasomatism) between metasediments and ultramafics during the high temperature deformation. The local occurrence of (U)HP and HT conditions is demonstrated by the absence of significant melting in the unit, although around the peridotite lenses, metapelites show hydrated assemblage at T>800 °C were stable at variable P stage. U-Pb zircon and monazite dating indicate that local HP and HT conditions were accomplished at the early stage of Alpine exhumation (~36 Ma), while the rocks fa form the rheological boundaries records only pre–Alpine ages. Our results documented that, even though weak metasediments share the same structural evolution with the strong UM, large differences in the local metamorphic conditions (ΔP up to 2 GPa; ΔT up to 160 °C) are recorded in relation to the distance from the UM lenses. Fluid–assisted metasomatism is further documented as being strongly localized at the interface between ultramafic lenses and the metapelitic host throughout all part of the metamorphic evolution, including the HP–HT stage. Therefore, in the Cima di Gagnone type–locality, the interplay between metapelites and ultramafic exerts a crucial first–order control to allow assemblage equilibrium during HT metamorphism and amphibolite–facies retrogression. These new findings exclude that the different metamorphic record may be attributed only to differential preservation during the retrograde path. Our new P–T–t–D paths highlight the crucial role of the rheological boundaries in modify the P-T metamorphic records without varying lithostatic pressure and thus depth conditions.

References:

Maino, M., Adamuszek, M., Schenker, F.L., Seno, S., Dabrowski, M., 2021. Sheath fold development around deformable inclusions: Integration of field-analysis (Cima Lunga unit, Central Alps) and 3D numerical models. J. Struct. Geol. 144, 104255.

Corvò, S., Maino, M., Langone, A., Schenker, F. L., Piazolo, S., Casini, L., & Seno, S., 2021. Local variations of metamorphic record from compositionally heterogeneous rocks (Cima di Gagnone, Central Alps): Inferences on exhumation processes of (U) HP–HT rocks. Lithos, 390, 106126.

Piccoli, F., Lanari, P., Hermann, J., & Pettke, T., 2021. Deep subduction, melting, and fast cooling of metapelites from the Cima Lunga Unit, Central Alps. Journal of metamorphic geology

How to cite: Corvò, S., Maino, M., Langone, A., Schenker, F. L., Casini, L., Piazolo, S., and Seno, S.: Local variations of metamorphic record from compositionally heterogeneous rocks: Inferences on exhumation processes of (U)HP-HT rocks (Cima di Gagnone, Adula-Cima Lunga unit), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8776, https://doi.org/10.5194/egusphere-egu22-8776, 2022.

EGU22-9093 | Presentations | GD6.1 | Highlight

Grain-scale equilibrium reactions guide fluid-driven eclogitization of dry crustal rocks 

Timm John, Sascha Zertani, Johannes C. Vrijmoed, Caroline Brachmann, and Oliver Plümper

When a fluid is introduced into dry rocks at high-pressure conditions, it acts as a catalyst and facilitates re-equilibration. This often promotes weakening and subsequent ductile deformation. Here, we present a detailed micro-structural and mineral chemical study of eclogitization of initially dry continental crustal rocks in the absence of ductile deformation. The studied sample features an incomplete (fluid-induced) transition from lower crustal granulite to eclogite, and the transition is fully preserved. None of the mineral phases show any signs of ductile deformation, indicating that the transformation was entirely static. Material transport during the reaction was limited to the availability of fluids. Detailed analysis of the local assemblages along the transect reveals that the reaction occurs in three distinct steps: The plagioclase-plagioclase grain boundaries were the first to re-equilibrate followed by clinopyroxene-plagioclase and garnet-plagioclase grain boundaries. Lastly, the grain boundaries that included only garnet and/or clinopyroxene are involved in the transformation. Thermodynamic modelling of local equilibria at dry conditions and with H2O in excess reveals that this stepwise transformation is caused by the varying reactivity of the local assemblages at the prevailing P-T conditions. Those reactions that result in the largest decrease of the Gibbs free energy from the dry case to the case with H2O in excess occur first. Once the reaction is facilitated, this effect is amplified because the density increase is largest at those grains boundaries that have reacted first, creating new fluid pathways through volume reduction. The calculated stable local mineral assemblages are consistent with those present in the sample indicating that element transport is limited, also supported by the observation that the fabric of the granulite is preserved in the eclogite. Our results demonstrate that reactive fluid flow is guided by the local energy budget along the grain boundaries, and that element transport during static re-equilibration is limited to the extent where it is thermodynamically advantageous.

How to cite: John, T., Zertani, S., Vrijmoed, J. C., Brachmann, C., and Plümper, O.: Grain-scale equilibrium reactions guide fluid-driven eclogitization of dry crustal rocks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9093, https://doi.org/10.5194/egusphere-egu22-9093, 2022.

EGU22-9608 | Presentations | GD6.1 | Highlight

Formation of olivine veins by dehydration during viscously deforming serpentinite: a numerical study 

Stefan Markus Schmalholz, Evangelos Moulas, Ludovic Räss, and Othmar Müntener

The dehydration of serpentinite during subduction and the associated formation of dehydration veins is an important process for the global water cycle and the dynamics of the subducting plate. Field observations suggest that olivine veins can form by dehydration during viscous shear deformation of serpentinite. However, this hypothesis of olivine vein formation, involving the coupling of rock deformation, dehydration reactions and fluid flow, has not been tested and quantified by hydro-mechanical-chemical (HMC) models. Here, we present a new two-dimensional HMC numerical model to test whether olivine veins can form by dehydration during viscous shearing of serpentinite. The applied numerical algorithm is based on the pseudo-transient finite difference method. We consider the simple reaction antigorite + brucite = forsterite + water. Volumetric deformation is viscoelastic and shear deformation is viscous with a shear viscosity that is an exponential function of porosity. In the initial model configuration, total and fluid pressures are homogeneous and in the antigorite stability field. Small, initial perturbations in porosity, and hence in viscosity, cause pressure perturbations during far-field simple shearing. During shearing, the fluid pressure can locally decrease and reach the thermodynamic pressure required for the dehydration reaction, so that dehydration is triggered locally. The simulations show that dehydration veins form during progressive shearing and grow in a direction parallel to the maximum principal stress. During the dehydration the porosity can increase locally from 2% (initial value) to more than 50% inside the dehydration vein. The numerical model allows quantifying the mechanisms and variables that control the evolution of porosity and fluid pressure. We show that the porosity evolution is controlled by three mechanisms: (1) volumetric deformation of the porous solid, (2) temporal variation of the solid density and (3) mass transfer during the dehydration reaction. We quantify the evolution of the fluid pressure that is controlled by five variables and processes: (1) the total pressure of the porous rock, (2) elastic effects of the total volumetric deformation, (3) the temporal variation of porosity, (4) the temporal variation of solid density and (5) mass transfer during the dehydration reaction. This model supports the observation-based hypothesis of the formation of olivine veins due to dehydration during viscous shearing of serpentinite. More generally, our HMC model provides quantitative insights into the evolution of porosity, and hence dynamic permeability, fluid pressure and mass transfer during dehydration reactions in deforming rock.

How to cite: Schmalholz, S. M., Moulas, E., Räss, L., and Müntener, O.: Formation of olivine veins by dehydration during viscously deforming serpentinite: a numerical study, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9608, https://doi.org/10.5194/egusphere-egu22-9608, 2022.

EGU22-9773 | Presentations | GD6.1

The influence of non-hydrostatic stress on mineral equilibria: insights from Molecular Dynamics 

Mattia L. Mazzucchelli, Evangelos Moulas, Boris Kaus, and Thomas Speck

Mountain building, earthquake generation, and volcanic eruptions occur in Earth’s lithosphere and have direct impacts on society. Understanding the mechanism of geodynamic processes relies on the determination of the pressure-temperature history which is recorded by rocks that have been involved in geodynamic processes. In most cases, the interpretation of the conditions attained by rocks is based on the assumption that the stresses in the Earth are hydrostatic. However, non-hydrostatic stresses are observed in the lithosphere, and the significance of the magnitude of the differential stress on phase equilibria is still actively contested among researchers who hold completely incompatible views about the use of various thermodynamic potentials (e.g. [1-3]).

The problem of phase equilibria under non-hydrostatic stress has been explored in several rock-deformation experiments (on mm scale), in which recrystallization of minerals was observed under an applied non-hydrostatic stress [4-6]. However, during experiments, stress and pressure heterogeneities may develop in the sample (e.g. [6]). Therefore, the direct effect of the applied non-hydrostatic stress on the thermodynamics of the reactions cannot be separated from the effect caused by local pressure variations in the sample itself.

Here, we explore the effect of non-hydrostatic stress on the thermodynamics of mineral reactions by investigating a system at the molecular scale. With Molecular Dynamics (MD) we perform coexistence simulations in which two phases are brought in contact and equilibrated at given temperature, pressure, and stress conditions. As expected, the obtained stress component normal to the phase-phase interfaces is homogeneous across the system. Our data suggest that the direct effect of non-hydrostatic stress on the solid-liquid equilibria is rather minor for geological applications, consistent with theoretical predictions [7,8]. However, our analysis does not take into account the indirect effect of stress heterogeneities at the sample scale. Spatial variations of stress can reach GPa level and can therefore indirectly affect phase equilibria.

M.L. Mazzucchelli is supported by an Alexander von Humboldt research fellowship.

References

[1] Wheeler, J. Geology 42, 647–650 (2014);

[2] Hobbs, B. et al. Geology 43, e372 (2015);

[3] Tajčmanová, L. et al. Lithos 216–217, 338–351 (2015)

[4] Hirth, G. et al. J. Geophys. Res. 99, 11731–11747 (1994)

[5] Richter, B. et al. J. Geophys. Res. Solid Earth 121, 8015–8033 (2016)

[6] Cionoiu, S. et al. Sci. Rep. 9, 1–6 (2019)

[7] Sekerka, R. et al. Acta Mater., 52(6), 1663–1668 (2004)

[8] Frolov, T. et al. Phys. Rev. B Condens. Matter Mater. Phys. 82, 1–14 (2010)

How to cite: Mazzucchelli, M. L., Moulas, E., Kaus, B., and Speck, T.: The influence of non-hydrostatic stress on mineral equilibria: insights from Molecular Dynamics, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9773, https://doi.org/10.5194/egusphere-egu22-9773, 2022.

EGU22-10147 | Presentations | GD6.1

H2O contents in nominally anhydrous minerals and its effect on the formation of eclogite-facies, hydrous shear zones (Holsnøy, Western Norway) 

Lisa Kaatz, Stefan M. Schmalholz, Julien Reynes, Jörg Hermann, and Timm John

High-grade dry granulites of Holsnøy (Western Norway) were subducted during the Caledonian orogeny and reached eclogite-facies conditions at ~2 GPa and 700° C. However, they stayed in a metastable state until brittle deformation enabled infiltration of an aqueous fluid, which triggered the kinetically delayed eclogitization. Field observations reveal an interconnected network of hydrated eclogite-facies shear zones surrounded by unaltered and pristine granulites. The formation of these features is highly controlled by deformation, fluid infiltration and fluid-rock interaction.

At first, the shear zone evolution was analyzed to better understand the relation between strain localization within the shear zones and the progressive widening of these shear zones from cm- to m-wide thickness. The results showed that widening overcomes the effect of stretching during progressive fluid-rock interaction and strain accumulation, if either a substantial amount of continuously infiltrating fluid and/or numerous repetitive fluid pulses enter the system.

Therefore, investigations have been carried on the H2O contents in nominally anhydrous minerals of the granulite and eclogite. The H2O contents were measured using Fourier transform infrared spectroscopy. Garnet (grt), clinopyroxenes (cpx) and plagioclase (plg) have been measured with a close look on spatial repartition of OH at the grain scale and at the shear zone scale. The aim is to decode the link between fluid infiltration, mineral reaction, and deformation. There are no significant compositional changes between granulite and eclogite, which means that the fluid mainly worked as a catalyst without mass transfer beside H2O. The analyses across a shear zone profile reveal three major observations: (i) average H2O contents of the grt cores increase from granulite towards the shear zone (from 10 to 50 µg/g), (ii) average H2O contents of the cpx increase, too (from 145 to 310 µg/g), (iii) the plg stores limited amounts of H2O until a phase separation leads into an symplectites consisting of albite-rich plg (anhydrous) and clinozoisite (hydrous). The H2O contents of the minerals are interpreted to be a result of two different diffusional mechanisms acting simultaneous at different spatial scales and rates. The H2O increase in grt and cpx cores without mineral reaction is a result of hydrogen diffusion (H+/H2), which is much faster and pervasive than the porous influx of an aqueous fluid (H2O), which, contemporaneously, caused the formation of hydrous phases.

The above findings are combined in a 1D numerical shear zone model to reproduce the measured mineral chemical data and the respective H2O-contents. The results shed light on the dynamic weakening processes caused by the influx of H+/H2 in combination with synkinematic mineral reactions.

How to cite: Kaatz, L., Schmalholz, S. M., Reynes, J., Hermann, J., and John, T.: H2O contents in nominally anhydrous minerals and its effect on the formation of eclogite-facies, hydrous shear zones (Holsnøy, Western Norway), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10147, https://doi.org/10.5194/egusphere-egu22-10147, 2022.

EGU22-10316 | Presentations | GD6.1 | Highlight

Thermolab: a thermodynamics laboratory for non-linear transport processes in open systems 

Johannes C. Vrijmoed and Yury Y. Podladchikov

We developed a numerical thermodynamics laboratory called “Thermolab” to study the effects of the thermodynamic behavior of non-ideal solution models on reactive transport processes in open systems. The equations of state of internally consistent thermodynamic datasets are implemented in MATLAB functions and form the basis for calculating Gibbs energy. A linear algebraic approach is used in Thermolab to compute Gibbs energy of mixing for multi-component phases to study the impact of the non-ideality of solution models on transport processes. The Gibbs energies are benchmarked with experimental data, phase diagrams and other thermodynamic software. Constrained Gibbs minimization is exemplified with MATLAB codes and iterative refinement of composition of mixtures may be used to increase precision and accuracy. All needed transport variables such as densities, phase compositions, and chemical potentials are obtained from Gibbs energy of the stable phases after the minimization in Thermolab. We demonstrate the use of precomputed local equilibrium data obtained with Thermolab in reactive transport models. In reactive fluid flow the shape and the velocity of the reaction front vary depending on the non-linearity of the partitioning of a component in fluid and solid. We argue that non-ideality of solution models has to be taken into account and further explored in reactive transport models. Thermolab Gibbs energies can be used in Cahn-Hilliard models for non-linear diffusion and phase growth. This presents a transient process towards equilibrium and avoids computational problems arising during precomputing of equilibrium data.

How to cite: Vrijmoed, J. C. and Podladchikov, Y. Y.: Thermolab: a thermodynamics laboratory for non-linear transport processes in open systems, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10316, https://doi.org/10.5194/egusphere-egu22-10316, 2022.

EGU22-10318 | Presentations | GD6.1 | Highlight

Eclogitization of the Allalin gabbro under heterogeneous stress conditions 

Cindy Luisier, Philippe Yamato, Horst R. Marschall, Evangelos Moulas, and Thibault Duretz

Eclogitization reactions in mafic rocks involve large volume changes, porosity evolution and fluid transfer. They impact many important geological processes such as the localization of deformation and fluid channeling at intermediate depth in subduction zone. The study of exhumed eclogitic bodies in orogens shows that eclogitization of the oceanic crust is heterogeneous from both a structural and metamorphic point of view. For example, in the European Alps, the Allalin metagabbro shows high strain areas, consisting of hydrous metagabbros, fully equilibrated under eclogite-facies conditions during the Alpine orogeny. Conversely, large volumes of low strain, fluid-undersaturated gabbros remained largely unaffected by the high-pressure (HP) metamorphism, locally preserving igneous textures and even, occasionally, relics of their magmatic mineralogy. The intensity of deformation as well as the degree of eclogitization in the metagabbro have been shown to be directly related to the extent of pre-Alpine hydration during high-temperature hydrothermal alteration [1]. However, the influence of this degree of hydration on (1) reaction kinetics and/or (2) enhancing rheological contrasts leading to heterogeneous deformation patterns and metamorphic conditions is still debated.

In order to address this issue, we propose a multidisciplinary study involving petrographic and microtextural observations combined with 2D thermo-mechanical numerical models allowing to discuss the role of pre-Alpine hydrothermal alteration on the development of HP metamorphic assemblages.

We present petrographic and textural data from three different types of rocks from the Allalin metagabbros: i) undeformed and mostly untransformed metagabbros, with relics of igneous augite and plagioclase, ii) coronites, with olivine pseudomorphs showing different levels of hydration, rimmed by a garnet corona, and iii) eclogitized metagabbros, with olivine and plagioclase sites fully replaced by high-pressure assemblages.

The role of protolith hydration on the observed range in metamorphic facies is then tested by using 2D thermo-mechanical models that allow to simulate the deformation of a strong and dry rock with several randomly oriented weak and hydrous zones. Our results show that the shearing of heterogeneous rock can lead to the formation of localized ductile shear zone within a matrix that remains relatively undeformed but where plastic deformation can occur. The associated P field is also highly heterogeneous, with P ranging from 1 to 3 GPa. The deformation patterns and P modelled may suggest that locally hydrated portions of the gabbro acted as rheological perturbations sufficiently efficient in producing the structural and metamorphic record now observed in the field.

 

 

[1] Barnicoat, A. C. & Cartwright, I. (1997) Journal of Metamorphic Geology 15, 93–104

How to cite: Luisier, C., Yamato, P., Marschall, H. R., Moulas, E., and Duretz, T.: Eclogitization of the Allalin gabbro under heterogeneous stress conditions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10318, https://doi.org/10.5194/egusphere-egu22-10318, 2022.

EGU22-10383 | Presentations | GD6.1

Geodynamic constraints on ophiolite emplacement 

Iskander Ibragimov and Evangelos Moulas

Ophiolite complexes are commonly found outcropping along ancient suture zones in continental regions. Many geological studies suggest that, during subduction initiation, a small remnant of the oceanic crust can be thrusted upon continenal regions. This thrusting occurs during a process that is generally termed as “ophiolite obduction”. Despite the relatively small volume of the ophiolite rocks, their occurence provides important geologic/geodynamic constraints for the processes of subduction initiation. 
Following the seminal work of Cloos (1993), oceanic lithosphere that is older than 10 Myrs is dense enough, and as a result, facilitates oceanic subduction in a spontaneous manner. This suggestion is based on the fact that buoyancy is one of the most important forces relevant to large-scale geodynamics. However, old oceanic lithosphere is also expected to be cold and, as a consequence, mechanically strong. The increased strength of the oceanic lithosphere hinders subduction initiation and makes ophiolite obduction difficult.
In this work we perform systematic numerical simulations to investigate the effects of initial geometry and convergence velocity on subduction initiation and ophiolite obduction. We use LaMEM to calculate 2D thermo-mechanical models that include the effects of visco-elasto-plastic rheology. In addition, we have incorporated a thermodynamically-consistent density structure for the crust and mantle. In this way, buoyancy forces are calculated in a consistent manner based on the pressure and temperature fields of the thermo-mechanical models. Our results show that when the oceanic lithosphere is older than 10Myr, subduction is very difficult and does not initiate in a spontaneous manner. Our systematic simulations provide insights for the range of conditions and parameters of oceanic subduction and ophiolite emplacement.

References
Cloos, M. (1993) Lithospheric Buoyancy and Collisional Orogenesis: Subduction of Oceanic Plateaus, Continental Margins, Island Arcs, Spreading Ridges, and Seamounts. Geological Society of America Bulletin, 105, 715-737.
https://doi.org/10.1130/0016-7606(1993)105<0715:LBACOS>2.3.CO;2

How to cite: Ibragimov, I. and Moulas, E.: Geodynamic constraints on ophiolite emplacement, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10383, https://doi.org/10.5194/egusphere-egu22-10383, 2022.

EGU22-10445 | Presentations | GD6.1

Reactive Melt Transport Using Porosity Waves Across the Thermal Boundary Layer. 

Marko Repac, Annelore Bessat, Stefan Schmalholz, Yury Podladchikov, Kurt Panter, and Sebastien Pilet

The lithosphere and the asthenosphere are characterized by different heat transport mechanisms, conductive for the lithosphere, convective for the asthenosphere. The zone associated with the transition between these two distinct mechanisms is known as the "Thermal Boundary Layer" (TBL). How the melt is transported across this zone is an important question regarding intraplate magmatism and for the nature of the seismic Low-Velocity Zone. Numerous studies and models suggest that primary magmas from intraplate volcanos are the product of low degree partial melting in the asthenosphere, while the differentiation process takes place in the crust or shallow lithospheric mantle. The question is how low degree melt ascends through the TBL and the lithospheric mantle. The thermal structure of the lithosphere is characterized by a high geothermal gradient, which questions the ability of melt to cross the lithospheric mantle without cooling and crystallizing. Since the base of the lithosphere is ductile, the possible modes of magma transport are porous flow or porosity waves. For these reasons, we would like to understand how melt is transported and what are the implications on the evolution of primitive melt, going from the convective part of the geotherm to the conductive part of the geotherm and further across the lithosphere.

We present the results of a thermo-hydro-mechanical-chemical (THMC) model1 for reactive melt transport using the finite difference method. This model considers melt migration by porosity waves and a chemical system of forsterite-fayalite-silica. Variables, such as solid and melt densities or MgO and SiO2 mass concentrations, are functions of pressure, temperature, and total silica mass fraction (CtSiO2). These variables are pre-computed with Gibbs energy minimization and their variations with evolving P, T, and CtSiO2 are implemented in the THMC model. We consider P and T conditions relevant across the TBL. With input parameters characteristic for alkaline melt and conditions at the base of the lithosphere, we obtain velocities between 1 to 150 m yr-1,which is a velocity similar to melt rising at mid-ocean ridges2. This implies the inability of primary melts to cross the lithosphere. However, melt addition to the base of the lithosphere is important to understand mantle metasomatism, and could, to some extent, contribute to physical properties of the Lithosphere-Asthenosphere Boundary and Mid Lithosphere Discontinuity observed with geophysical methods. We suggest that the appearance of alkaline magmas at the surface requires multiple stage processes as melts rising in the lithosphere progressively modify the geotherm allowing new melts to propagate to the surface. Our earlier modeling results1 demonstrated that a single porosity wave has a minor impact on chemical evolution. In this study, we search for a mechanism responsible for stabilizing porosity wave motion to some lateral location forcing consecutive waves to follow the same ascent path. The passage of a large number of quickly rising porosity waves over a long time through the same path would accumulate large melt to rock ratios and cause significant chemical evolution.

 

  • Bessat et at., 2022, G3, in press
  • Connolly et al. 2009, Nature 462, 209-212.

How to cite: Repac, M., Bessat, A., Schmalholz, S., Podladchikov, Y., Panter, K., and Pilet, S.: Reactive Melt Transport Using Porosity Waves Across the Thermal Boundary Layer., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10445, https://doi.org/10.5194/egusphere-egu22-10445, 2022.

EGU22-11149 | Presentations | GD6.1

Early reaction of plagioclase : an underrated alteration step during burial of the continental crust 

Loic Labrousse, Marie Baisset, and Alexandre Schubnel

Mutual links between metamorphic reactions and rheological properties of rocks under pressure, temperature and deviatoric stress are a major source of discrepancy of thermo-mechanical models when it comes to predict strain localization for instance. The interactions between metamorphism and strain are also considered as a possible cause for unexpected mechanical instabilities, e.g. mechanical failure, in lithological units buried deep in convergent plate boundaries.

The partially transformed granulite facies anorthosites on the Holsnøy Island, Bergen Arcs, Norwegian Caledonides, constitute one of the few archetypical exposure of crustal rocks deforming and reacting at the same time in the eclogite facies conditions. In these rocks, eclogite-facies paragenesis develops with devitrification patterns in « brittle » pseudotachylyte, and in their damage walls, along a pervasive network of « ductile » shear zones, as well as « statically » along digitations following the preserved granulite facies foliation, with no apparent relation to strain.

The present study, that follows recent advances in the understanding of relationships between crystallization of pyroxene and local scale pressure field, or modeling of the interaction between the eclogitization reactions sequence and strain localization, focuses on the first steps of incipient plagioclase destabilization along eclogite facies « fingers ». 

Granulite facies plagioclase, close to 40 % anorthite in composition, is subject to reactions both in the NASH and CASH subsystems, with contrasted stoechiometries and kinetics. Petrological observations evidence that the lowermost pressure reaction in the CASH system (an + H2O = zo + ky + qz), occurs unbalanced, with high kinetics and reaction volume change and therefore initiates strain within plagioclase grains, that react by twinning and subgrains individualization. This early stage of intra-grain transformation induces an effective grain size reduction, and favors fluid percolation, therefore promoting the eclogitization progression. The reaction occurring inside of plagioclase grains also affects their grain boundaries where kyanite and transient reactions products, such as potential melts, accumulate also altering the overall aggregate properties. 

We claim that this early, fast and pervasive reaction is a significative, yet underrated, step of mechanical alteration of the burying continental rocks.

How to cite: Labrousse, L., Baisset, M., and Schubnel, A.: Early reaction of plagioclase : an underrated alteration step during burial of the continental crust, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11149, https://doi.org/10.5194/egusphere-egu22-11149, 2022.

EGU22-11487 | Presentations | GD6.1 | Highlight

Deformation-facilitated melting of plagioclase 

Sarah Incel, Marie Baisset, Loic Labrousse, and Alexandre Schubnel

Geological processes involving deformation and/or reactions are highly influenced by the rock grain size, especially if diffusion-controlled processes take place such as long-range metamorphic reactions and diffusion creep. Although many processes, inducing grain-size reduction, are documented and understood at relatively high stresses and low temperatures (e.g., cataclasis) as well as at lower stress and higher temperature conditions (e.g., bulging, subgrain rotation), deformation twinning, a plastic deformation mechanism active in various minerals at lower temperatures, has been neglected as cause for grain-size reduction so far. We conducted experiments on natural plagioclase-bearing aggregates at 2.5 to 3 GPa confining pressure and temperatures of 720 to 950 °C using two different deformation apparatus, a DDIA and a Griggs press, as well as a piston-cylinder apparatus. Regardless of the apparatus type, we observe the breakdown of plagioclase into an eclogite-facies paragenesis, which is associated with partial melting in the high pressure, high temperature domain of the eclogite facies. In contrast to the sample that experienced hydrostatic conditions in the piston-cylinder press, the deformed samples reveal melt patches inside of several plagioclase grains. These patches coincide with the occurrence of deformation twins in plagioclase that formed due to differential stress. The ability of plagioclase to form deformation twins and their exploitation for melt initiation significantly lowers the effective grain size of plagioclase-rich rocks and thus impacts their reactivity and deformation behavior.

How to cite: Incel, S., Baisset, M., Labrousse, L., and Schubnel, A.: Deformation-facilitated melting of plagioclase, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11487, https://doi.org/10.5194/egusphere-egu22-11487, 2022.

EGU22-11490 | Presentations | GD6.1

Creep and acoustic emission in Shales from the Barents Sea 

Alina Sabitova, Sergey Stanchits, Viktoriya Yarushina, Georgy Peshkov, Lyudmila Khakimova, and Vladimir Stukachev

Nowadays, environmental awareness has become one of the key directions of humankind development. There are a lot of projects aimed at preserving the environment: ensuring the environmental safety of geothermal energy facilities; study of global geodynamics and its influence on the composition, state, and evolution of the biosphere; geoecological substantiation of safe placement, storage, and disposal of toxic, radioactive and other wastes, etc. An essential role is assigned to the storage of increasing volumes of carbon dioxide gas. This problem requires complex approaches and solutions. Given that both CO2 and radioactive storage are long-term projects, it is necessary to investigate the creep process to monitor the state of the underground environment and assess the risks of leakage. A viscous deformation of the formation accompanies the prolonged loading. Viscosity is an essential parameter in coupling fluid flow and deformation processes occurring on Earth [Sabitova et al., 2021]. At the same time, focused fluid flow is a common phenomenon in sedimentary basins worldwide. Flow structures often penetrate the sandy reservoir rocks and clay-rich caprocks [Peshkov et al., 2021]. The impacts of the viscoelastic deformation of clay-rich materials need to be evaluated from an experimental and modeling perspective to understand better the mechanisms forming such structures. Here, we present multistage triaxial laboratory creep experiments with acoustic emission analysis conducted on samples from the Barents Sea. We performed lithological and geochemical characterization of each sample as a petroleum system element. Bulk and shear viscosities used in numerical models are calculated for all samples. The experimental curves are explained using the theoretical model for porous rock viscoelastoplastic (de)compaction [Yarushina et al., 2020].

References:

Sabitova, A., Yarushina, V. M., Stanchits, S., Stukachev, V., Khakimova, L., & Myasnikov, A. (2021). Experimental compaction and dilation of porous rocks during triaxial creep and stress relaxation. Rock Mechanics and Rock Engineering, 54(11), 5781-5805.

Peshkov, G. A., Khakimova, L. A., Grishko, E. V., Wangen, M., & Yarushina, V. M. (2021). Coupled Basin and Hydro-Mechanical Modeling of Gas Chimney Formation: The SW Barents Sea. Energies, 14(19), 6345.

Yarushina, V. M., Podladchikov, Y. Y., & Wang, L. H. (2020). Model for (de) compaction and porosity waves in porous rocks under shear stresses. Journal of Geophysical Research: Solid Earth, 125(8), e2020JB019683.

How to cite: Sabitova, A., Stanchits, S., Yarushina, V., Peshkov, G., Khakimova, L., and Stukachev, V.: Creep and acoustic emission in Shales from the Barents Sea, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11490, https://doi.org/10.5194/egusphere-egu22-11490, 2022.

EGU22-11811 | Presentations | GD6.1

The simplest visco- or elasto-plastic rheology allowing to spontaneous earthquake nucleation 

Yury Alkhimenkov, Ivan Utkin, Lyudmila Khakimova, Celso Alvizuri, and Yury Podladchikov

Understanding the physical processes governing earthquake nucleation has been a hot topic since the last decade. A lot of research has been done trying to explain the physics of seismic triggering events. However, the exact physics behind seismic events nucleation is still poorly understood. The outcome of our recent research is the new theory of earthquake nucleation (Alkhimenkov et. al., 2021). The simplest visco-plastic or elasto-plastic rheology allows us to model spontaneous earthquake nucleation. We consider pure shear boundary conditions and slowly increase stress in the model reflecting the stress increase e.g., due to tectonic forces in real rocks. Once the stress field reaches the yield surface, the strain localization occurs, resulting in slowly developing fractal shear bands. As time evolves, shear bands grow spontaneously, and stress drops take place in the medium. Such stress drops are caused by the instantaneous development of new shear bands, their intersections, and intersections with the boundaries of the numerical domain. A stress drop corresponds to a particular new strain localization pattern. The new strain localizations act as seismic sources and trigger seismic wave propagation (Minakov and Yarushina, 2021). We suggest that the (seismic) radiation pattern of the focal mechanism might be similar to a particular moment tensor source, typical for realistic earthquakes (Alvizuri et al., 2018). This new modeling approach is based on conservation laws without any experimentally derived constitutive relations.

References

Alkhimenkov Y., Utkin I., Khakimova L., Alvizuri C., Quintal Q., Podladchikov Y. Spontaneous earthquake nucleation in elasto-plastic media. 19th Swiss Geoscience Meeting 2021, Geneva, Switzerland.

Minakov, A. and Yarushina, V., 2021. Elastoplastic source model for microseismicity and acoustic emission. Geophysical Journal International, 227(1), pp.33-53.

Alvizuri, C., Silwal, V., Krischer, L. and Tape, C., 2018. Estimation of full moment tensors, including uncertainties, for nuclear explosions, volcanic events, and earthquakes. Journal of Geophysical Research: Solid Earth, 123(6), pp.5099-5119.

How to cite: Alkhimenkov, Y., Utkin, I., Khakimova, L., Alvizuri, C., and Podladchikov, Y.: The simplest visco- or elasto-plastic rheology allowing to spontaneous earthquake nucleation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11811, https://doi.org/10.5194/egusphere-egu22-11811, 2022.

EGU22-11836 | Presentations | GD6.1

Thermo-chemo-mechanical coupling in Maxwell-Stefan multi-component diffusion 

Lyudmila Khakimova, Evangelos Moulas, Ivan Utkin, and Yury Podladchikov

Classical Fickian linear diffusion of inert or trace-like elements is restricted to ideal solution models of components with equal molar mass. Simultaneous diffusion of multiple concentrations is well-treated by the classical Maxwell-Stefan model. Quantitative predictions of concentrations evolution in real mixtures require careful replacement of concentration gradients by gradients of chemical potentials. Coupling of multi component diffusion to mechanics result in pressure gradients that contribute to Gibbs-Duhem relationship. We aim at developing of thermodynamically admissible multicomponent thermo-chemo-mechanical (TMC) model with ensured non-negative entropy production. We also ensure correct equilibrium limit with zero gradients of chemical potentials of individual components and satisfaction of classical Gibbs-Duhem and Maxwell relationships under pressure gradients. Following recent Tajčmanová et al. (2021) we consider both molar and mass formulations. We present optimal pseudo-transient numerical scheme for multi-diffusional fluxes coupled to visco-elastic bulk deformation.

Tajčmanová, L., Podladchikov, Y., Moulas, E. and L. Khakimova. The choice of a thermodynamic formulation dramatically affects modelled chemical zoning in minerals. Sci Rep 11, 18740 (2021).

How to cite: Khakimova, L., Moulas, E., Utkin, I., and Podladchikov, Y.: Thermo-chemo-mechanical coupling in Maxwell-Stefan multi-component diffusion, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11836, https://doi.org/10.5194/egusphere-egu22-11836, 2022.

EGU22-12215 | Presentations | GD6.1

Channelizing of melt flow by reactive porosity waves and its impact on chemical differentiation 

Andrey Frendak, Yury Alkhimenkov, Lyudmila Khakimova, Ivan Utkin, Yury Podladchikov, and Stefan Schmalholz

Many geodynamic processes are coupled. For example, in the partially molten mantle, the solid and molten mantle phases interact chemically during porous melt flow. For such two-phase reactive melt migration, solid and melt densities are functions of temperature, pressure, and chemical composition. Numerical models of such coupled physical-chemical systems require special treatment of the various couplings and concise numerical implementation. We elaborate a 2-D thermo-hydro-mechanical-chemical (THMC) numerical model for melt migration by porosity waves coupled to chemical reactions (Bessat et. al., 2021). We consider a simple ternary chemical system of forsterite-fayalite-silica to model melt migration within partially molten peridotite around the lithosphere-asthenosphere boundary. Our THMC model can simulate porosity waves of different shapes depending on the ratio of shear to bulk viscosity and the ratio of decompaction to compaction bulk viscosity. For an initial circular (blob-like) porosity perturbation, having a 2-D Gaussian shape, the geometry of the propagating reactive porosity wave remains blob-like if all viscosities are similar. If the decompaction bulk viscosity is smaller than the compaction bulk viscosity, so-called decompaction weakening, then the propagating porosity wave evolves into a channelized form. Our simulations quantify the variation from a blob-like to a channel-like porosity wave as a function of the viscosity ratios. We describe the 2-D THMC numerical algorithm which is based on the pseudo-transient finite difference method. Furthermore, we quantify the impact of channelization on the chemical differentiation during melt flow. Particularly, we quantify the evolution of the total silica concentration during melt migration as a function of the degree of channelization.

References

Bessat, A., Pilet, S., Podladchikov, Y. Y., & Schmalholz, S. M. (2022). Melt migration and chemical differentiation by reactive porosity waves. Geochemistry, Geophysics, Geosystems. In press.  

How to cite: Frendak, A., Alkhimenkov, Y., Khakimova, L., Utkin, I., Podladchikov, Y., and Schmalholz, S.: Channelizing of melt flow by reactive porosity waves and its impact on chemical differentiation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12215, https://doi.org/10.5194/egusphere-egu22-12215, 2022.

EGU22-12337 | Presentations | GD6.1

Experimental and numerical investigation of acoustic emission and its moment tensors in sandstones during failure based on the elastoplastic approach 

Elena Grishko, Viktoriya Yarushina, Maria Bobrova, Sergei Stanchits, Alexander Minakov, and Vladimir Stukachev

Microseismicity and acoustic emission (AE) studies are a part of earthquake science. Compared to ordinary earthquakes, microseismic events are characterized by higher frequencies, lower magnitudes, shorter duration, and more complex source mechanisms. The researchers associate the induced seismicity with different processes: borehole breakouts, tunnel excavations, hydraulic fracturing, wastewater injection, and stimulation of geothermal reservoirs.

Acoustic emission represents elastic waves generated spontaneously due to the formation of microfractures when the rock is undergoing a sufficiently high load. AE can be used to obtain continuous data at various stages of the deformation process: from distributed plastic failure to localized macroscopic failure. The spatial distribution of AE events indicates the location of fractures, and the source mechanism provides information about the failure mode: a tensile fracture, a shear fracture, or a combination of both.

This work shows the results of an experimental study of borehole breakouts in sandstones. We measured AE during the deformation experiments and applied the moment tensor analysis to microseismic waveforms. We used a continuum mechanics model of Minakov and Yarushina [2021] to relate the laboratory AE data to the deformation processes. The comparison of the failure patterns and corresponding seismic responses obtained in laboratory and simulations, allows to classify the deformation regimes in real rocks based on seismic observables.

EG, MB, SS, and VS gratefully acknowledge support from the Ministry of Science and Higher Education of the Russian Federation under agreement No. 075-15-2020-119 within the framework of the development program for a world-class Research Center.

 

References:

  • Minakov, A., Yarushina, V., Elastoplastic source model for microseismicity and acoustic emission, Geophysical Journal International, Volume 227, Issue 1, October 2021, Pages 33–53, https://doi.org/10.1093/gji/ggab207

How to cite: Grishko, E., Yarushina, V., Bobrova, M., Stanchits, S., Minakov, A., and Stukachev, V.: Experimental and numerical investigation of acoustic emission and its moment tensors in sandstones during failure based on the elastoplastic approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12337, https://doi.org/10.5194/egusphere-egu22-12337, 2022.

The simplest kinetic normal growth model assumes linear dependence of the transformation rate (or the velocity of the phase boundary) on overstepping of equilibrium conditions (or the degree of metastability).   Under pressure gradients within the phases, the equilibrium state requires zero spatial gradient of difference of the chemical potentials of the two chemical components. This can be achieved by diffusional redistribution of the fraction of two components. At the phase boundary, equilibrium requires the equality of both chemical potentials. Accordingly, at the phase boundary, the linear kinetic model may assume the first component exchange between the phases to be proportional to the chemical potential difference of this component and the phase boundary velocity to be proportional to the chemical potential difference of the second complementary component. The phenomenological proportionality constants are needed to quantify the "mobility" of the phase boundary and intensity mass exchange between phases. These phenomenological material parameters can either be taken from an experiment or derived from a Cahn-Hilliard-type model. Cahn-Hilliard-type model resolving the fine structure of advancing phase boundary  ‘can derive, rather than postulate, a kinetic relation governing the mobility of the phase boundary and check the validity of the "normal growth" approximation’ (Truskinovsky, 1994).

Truskinovsky, L. About the “normal growth” approximation in the dynamical theory of phase transitions. Continuum Mech. Thermodyn 6, 185–208 (1994). https://doi.org/10.1007/BF01135253

How to cite: Podladchikov, Y. and Utkin, I.: Normal growth versus Cahn-Hilliard models for kinetics of the first-order phase transformations in binary mixtures under pressure gradients, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12437, https://doi.org/10.5194/egusphere-egu22-12437, 2022.

EGU22-12496 | Presentations | GD6.1 | Highlight

Numerical modelling of lithospheric deformations with frictional plasticity 

Thibault Duretz, René de Borst, Ludovic Räss, Phillippe Yamato, Tim Hageman, and Laetitia Le Pourhiet
Strain localisation is a key process that allows for the emergence of tectonic plates and controls their long-term deformation. Upper crustal levels are relatively cold and their rheology is thus governed by frictional plasticity. In order to predict the formation of tectonic plates and quantify the deformation of the Earth's upper shell, geodynamic modelling simulation tools must reliably account for deformation in the frictional plastic realm. 
Nevertheless, the simulation of frictional plastic strain localisation poses severe issues. Commonly employed implementations (visco-plastic and visco-elasto-plastic) often fail to accurately satisfy force balance and suffer from a lack of convergence upon mesh refinement. These problems are intimately linked to the fact that commonly employed models do not encompass any characteristic spatial or temporal scales of localisation. Various regularisation techniques can thus be used as a remedy. Here we investigate three popular regularisation techniques, namely viscoplasticity, gradient plasticity and the use of a Cosserat medium, and discuss their potential application for geodynamic modelling.  

How to cite: Duretz, T., de Borst, R., Räss, L., Yamato, P., Hageman, T., and Le Pourhiet, L.: Numerical modelling of lithospheric deformations with frictional plasticity, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12496, https://doi.org/10.5194/egusphere-egu22-12496, 2022.

EGU22-13185 | Presentations | GD6.1 | Highlight

Brittle failure at high-pressure conditions: the key role of reaction-induced volume changes 

Philippe Yamato, Thibault Duretz, Marie Baïsset, and Cindy Luisier

Metamorphic reactions can lead to drastic changes in rocks mechanical properties. Indeed, during such transformations, the nucleation of new phases with different strength, grain size and/or density compared to the primary phases is enhanced, and transient processes due to the ongoing reaction are then activated.

Eclogitization of lower crustal rocks during continental subduction constitutes an emblematic transformation illustrating these processes. In such tectonic context, it has been shown that eclogitization seems to be closely associated with the occurrence of seismogenic events. However, the mechanisms that trigger brittle failure in such high pressure environments remain highly debated. Indeed, whether the change in density or the change in rheology can lead to embrittlement is still enigmatic.

By using 2D compressible mechanical numerical models we studied the impact of the strong negative volume change of the eclogitization reaction on the rocks rheological behaviour. We show that eclogitization-induced density change occurring out of equilibrium can, by itself, generates sufficient shear stress to fail the rocks at high-pressure conditions.

Rupture initiation at depth in continental subduction zones could therefore be explained by volume changes, even without considering the modifications of the rheological properties induced by the transformation. Our results also indicate that the negative volume change associated with brittle failure can enhance the propagation of the eclogitization process by a runaway mechanism as long as the reaction is not limited by the lack of reactants.

 

How to cite: Yamato, P., Duretz, T., Baïsset, M., and Luisier, C.: Brittle failure at high-pressure conditions: the key role of reaction-induced volume changes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13185, https://doi.org/10.5194/egusphere-egu22-13185, 2022.

In the recent decade, numerical modelling approaches based on combination of staggered finite differences with marker in cell techniques became increasingly popular in geodynamics due to their simplicity, flexibility and computational efficiency. Here, I present new version of popular 3D thermomechanical code i3ilvis, which has been fundamentally revised to include the following methodological advances (Gerya, 2019 and references therein):

  • Full thermomechanical coupling (through global Picard iteration) including compressible time-dependent mass conservation equation and adiabatic and shear heating effects in the energy conservation equation.
  • Regularized visco-elasto-viscoplastic rheological model with/without dilation. (Duretz et al., 2019) based on global thermomechanical Picard iteration.
  • Accurate continuity-based velocity interpolation for marker advection applicable for both compressible and incompressible flows.
  • Free surface stabilization against “drunken sailor” instability.
  • Accurate 3D rotation of elastic stresses on markers.
  • Dislocation-diffusion creep rheology with grainsize evolution(Bercovici and Ricard, 2012) including newton iteration for dislocation creep to compute effective viscosity for markers.

The new code is OpenMP parallel and has already been successfully tested for cases of realistic 3D geodynamic modeling including tectono-magmatic model of continental breakup to oceanic spreading transition and spontaneous subduction initiation scenario associated with slab bending and normal faulting.

 

Bercovici, D., Ricard, Y. (2012) Mechanisms for the generation of plate tectonics by two- phase grain-damage and pinning. Phys. Earth. Planet. Inter. 202-203, 27–55.

Duretz, T., de Borst, R., Le Pourhiet, L. (2019) Finite thickness of shear bands in frictional viscoplasticity and implications for lithosphere dynamics. Geochemistry, Geophysics, Geosystems, 20, 5598–5616.

Gerya T.V. (2019) Introduction to Numerical Geodynamic Modelling. Second Edition. Cambridge University Press, 472 pp.

 

How to cite: Gerya, T.: New i3elvis: Robust visco-elasto-plastic geodynamic modelling code based on staggered finite differences and marker in cell, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13215, https://doi.org/10.5194/egusphere-egu22-13215, 2022.

EGU22-521 | Presentations | GMPV6.1

Detecting H2 degassing events related to serpentinization in Oman 

John Aiken, Robert A. Sohn, Peter B. Kelemen, François Renard, and Bjørn Jamtveit

Peridotite alteration via serpentinization has been identified as a major potential sink of man-made carbon. Peridotite serpentinization provides a geochemical pathway to store CO2 as a solid, and releases natural hydrogen as a byproduct. Given the large quantities of peridotite available in oceanic environments, serpentinization could serve as a major component in mitigating man-made climate change. “Reaction driven cracking” has been proposed as an attractive mechanism to explain how peridotite is fully serpentinized.  In this process, when the peridotite alters and becomes a serpentinite, the volume of the rock grows producing stress on the surrounding rock. This process produces new fractures that allow water to enter new areas within the rock thus promoting new serpentinization. Cracking events due to this fracturing process being driven by peridotite alteration have never been detected in the environment (e.g., seismic data). As part of the Oman Drilling Project, a network of 12 hydrophones was deployed in two boreholes drilled in Oman over a period of nine months. This network was designed to detect the microseismic cracking events associated with reaction driving cracking. Surprisingly, it has served as an excellent detector of natural hydrogen degassing events. Hydrogen is a byproduct of the geochemical serpentinization process. These intermittent events come in short “spurts” where periods of quiescence alternate with short periods where many bubbles come out all at once. This poster presents evidence of hydrogen degassing events related to active serpentinization in Oman. We use the results to provide estimates of hydrogen released during the period of hydrophone deployment based on estimated bubble volumes.

How to cite: Aiken, J., Sohn, R. A., Kelemen, P. B., Renard, F., and Jamtveit, B.: Detecting H2 degassing events related to serpentinization in Oman, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-521, https://doi.org/10.5194/egusphere-egu22-521, 2022.

EGU22-1050 | Presentations | GMPV6.1

on the deformation of porous medium by pressurized flow 

Arnold Bachrach and Yaniv Edery

Fluid injections into the underground occurs in many industrial processes as hydraulic fracturing for oil and gas recovery, wastewater disposal, enhanced geothermal energy systems (EGS) and Carbon storage technologies. Often, the increase in pore pressure due to the fluid injections lead to the activation of a preexisting underground shear fractures (named faults), forming unanticipated local earthquakes.

While studying the mechanism of injection induced earthquakes, the rock deformation due to the fluid injection is unknown. Understanding the rock deformation coupling with the pressure change, requires detailed experiments linking the global and local deformation with the pressure change during flow, which ultimately influence the earthquake triggering.

In this study we present a novel experiment on transparent plastic rocks, that offers a detailed analysis of the artificial rocks’ deformation due to pressurized flow. In these experiments, we inject a fluid through the artificial rocks and analyze the internal deformation by capturing the displacement of fluorescent microspheres embedded in the artificial rock structure. Our analysis allows a straight-forward correlation between the deformation of rocks, the pressure change and the fluid flow. The study points a similarity between the material deformation due to internal pressure induced by the fluid injection and material deformation due to an external pulling.

How to cite: Bachrach, A. and Edery, Y.: on the deformation of porous medium by pressurized flow, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1050, https://doi.org/10.5194/egusphere-egu22-1050, 2022.

EGU22-1706 | Presentations | GMPV6.1

U–Pb geochronology of hydrothermal epidote unveils pre-kinematic hydration of highly deformed granitoids 

Veronica Peverelli, Alfons Berger, Andreas Mulch, Thomas Pettke, Francesca Piccoli, and Marco Herwegh

The Aar Massif is a mid-crustal basement section of the European plate and it was intensely deformed during the Alpine orogeny. Alpine deformation of Aar Massif granitoids is expressed by a pervasive network of ductile shear zones consisting of fine-grained polymineralic (ultra)mylonites dominated by viscous granular flow processes (Wehrens et al., 2016). Fluid circulation and hydration reactions are recorded by both granitic protoliths and shear zones. In particular, they are made evident by the alteration of feldspar into hydrous minerals like epidote and mica. The timing of this hydration event and, consequently, whether Alpine deformation was initiated in already altered granitoids or in fresh ones were unclear. This lack of time constraints led to a pivotal question: did deformation initiate in rocks that were altered by pre-kinematic hydration, or was hydration syn-kinematic and driven by the formation of Alpine shear zones?

 

Laser ablation ICP-MS U–Pb geochronology applied to epidote in hydrothermal veins provides new evidence for pre-Alpine hydration of granitoids in the Aar Massif. Two veining events are recognized: 1) one at ca. 276 Ma occurring during Permian transtension and rifting, and 2) another at ca. 14 Ma related to late Alpine exhumation phases. Initial 207Pb/206Pb ratios of all Permian epidote samples overlap within uncertainty, suggesting only one fluid source and equilibration path. Also, these ratios are more radiogenic than those of the host rocks at the time of vein formation. The hydrogen isotopic composition of the Permian fluids was calculated from measurements in bulk epidote separates by high-temperature conversion elemental analyzer. With a temperature range of epidote crystallization estimated between 200–300 °C, the calculated δDfluid value is -57 to -44 ‰. An external source for the Permian fluids is suggested by the disequilibrium of Pb isotopes between hydrothermal epidote and host granitoids. Percolation of meteoric water along transtensional faults and interaction with syn-rift sediments before reaching the granitoids underneath is suggested by the Permian transtensional geodynamics and supported the hydrogen isotopic composition of the Permian fluids.

 

The occurrence of Permian fluid circulation in the Aar Massif granitoids indicates that these rocks were altered before the onset of Alpine deformation. In fact, it can be inferred that fluid circulation caused not only veining, but also pervasive flow and thus the alteration of magmatic feldspar into fine-grained hydrous minerals throughout the granitoids of the present-day Aar Massif. This enabled pre-Alpine storage of water and the creation of numerous additional grain boundaries, both favoring viscous granular flow during Alpine deformation. In this context, the localization of strain in polymineralic aggregates containing hydrous minerals can recycle stored pre-kinematic (i.e., Permian) water. Thus, the initiation of Alpine deformation did not necessarily require the addition of syn-kinematic (i.e., Alpine) fluids, although their presence is confirmed by this and previous studies (e.g., Ricchi et al., 2019; Peverelli et al., 2021).

How to cite: Peverelli, V., Berger, A., Mulch, A., Pettke, T., Piccoli, F., and Herwegh, M.: U–Pb geochronology of hydrothermal epidote unveils pre-kinematic hydration of highly deformed granitoids, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1706, https://doi.org/10.5194/egusphere-egu22-1706, 2022.

Hydration of upper mantle rocks leads to serpentinization with drastic consequences for the geophysical and geochemical properties of the Earth’s lithosphere. Serpentinization takes place via a dissolution-precipitation process in which the fluid phase plays a key role both in the transport of dissolved constituents and in the supply of reactants. A limiting factor for serpentinization is the likelihood of pore-space clogging due to the large solid-volume increase and potential negative repercussions on reaction-induced fracturing [1]. However, small-angle neutron scattering [2] has shown that porosity remains abundant at the nanometer-scale ensuring that aqueous fluids can penetrate to the reaction front allowing serpentinization to progress. To further determine the nature of serpentinite nanoporosity and explore the consequences of fluids confined to nanometric dimensions, we couple multi-scale correlative electron microscopy to molecular dynamics simulations. In the analytical part, we combined electron backscatter diffraction (EBSD) with focused-ion beam scanning electron microscopy (FIB-SEM) nanotomography and transmission electron microscopy (TEM) to investigate two partially serpentinized peridotites from the mid-Atlantic ridge (ODP Leg 209) and the Røragen ultramafic complex, Norway. We determined the crystallographic orientation of the host olivine grains to constrain any potential orientational relationship between the host and the reaction-induced porosity within serpentine. No apparent correlation was found. Based on the EBSD maps, we excavated 23 FIB-SEM cross-sections across serpentine veins and the serpentine-olivine interface. At a pixel resolution of 3 nm, only three out of 23 cross-sections showed apparent pore space. Subsequent, FIB-SEM nanotomography of these three regions showed that vein porosity (average φFIB-SEM <50 nm) is concentrated at the olivine-serpentine interface and devoid in the vein middle. To further investigate pore space beyond the FIB-SEM resolution, we prepared eight electron-transparent foils for high-resolution TEM analysis. All foils show an apparent porosity between 1 to 4% with an average pore size of 5 nm. TEM-based energy-dispersive X-ray analysis reveals a 100-nm wide brucite-layer separating serpentine from olivine. Within the brucite-layer, total porosity ranges from 10 to 20% with pore size >10 nm. A higher porosity within brucite-bearing domains is also apparent at the SEM-scale, where we observe larger brucite-rich veins with a high density of nanopores. Hence, our microstructural investigations suggest that continued fluid transport to the reaction interface in the potential absence of reaction-induced fracturing could be sustained through a combination of a nanoporous serpentine network, porous brucite-rich veins, and a highly nanoporous brucite-layer at the olivine reaction interface. Overall, our observations that serpentinite porosity is constrained to the nanoscale have first-order implications for fluid transport and behaviour, because critical physicochemical properties, such as the dielectric constant ε, differ significantly in nanoscale-confined fluids when compared to their bulk counterparts. Initial molecular dynamics simulations of aqueous fluids confined in brucite nanochannels indicate that with the reduction of the width of the nanochannel, the perpendicular component of ε drops drastically which likely has a profound impact on minerals solubility hence overall reaction progress.

[1] Plümper et al. Geology (2012) 40(12): 1103-1106.

[2] Tutolo et al. Geology (2016) 44(2): 103-106.

How to cite: Chogani, A. and Plümper, O.: Nanoporosity in serpentinites and its consequences for fluid transport: a combined multi-scale electron microscopic imaging and molecular dynamics study, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2291, https://doi.org/10.5194/egusphere-egu22-2291, 2022.

EGU22-2313 | Presentations | GMPV6.1

Microscale deformation in a compacted and anisotropic mudstone: the Opalinus Clay, northern Switzerland 

Ismay Vénice Akker, Marco Herwegh, Lukas Aschwanden, Martin Mazurek, and Herfried Madritsch

The low permeability and excellent sealing properties of mudstones places such sedimentary rocks into focus of geo-engineering applications using clay formations as natural barriers for contaminant transport. Here we investigate microscale deformation structures in the Opalinus Clay in northern Switzerland, which is currently under investigation as a host rock for radioactive waste confinement. We aim to characterize paleo-faulting/fracturing as well as subsequent mineralization events. For this purpose, drill core samples were investigated macroscopically, as well as by low and high-resolution optical light microscopy and scanning electron microscopy (SEM) in combination with energy-dispersive X-ray spectroscopy (EDX). These data were combined with high-resolution trace element maps obtained by Synchrotron X-ray Fluorescence Microscopy (SXFM). By combining the observed microstructures with the micro-chemistry of the associated mineralization events we yield a grouping between different processes and, in combination with cross-cutting relationships, a relative timing of the different deformation events.

Commonly the Opalinus Clay is weakly deformed, with only few localized deformation structures. The latter include: calcite veins (mm thickness) as well as mineralized (calcite and celestite) thrusts, normal faults and strike-slip faults (all cm thickness). Micro-textural analysis shows that low-angle thrust faults with calcite slickensides on their dip-slip surfaces localize on pre-existing horizontal fibrous calcite veins. The horizontal veins imply an early deformation stage with temporarily high pore fluid pressures under sub-horizontal max. principle stresses within the highly anisotropic mudstone. The first order analysis of the major element chemistry between the calcite forming slickensides and the fibrous veins shows significant differences in Mg, Fe and Mn contents. From a fluid-mechanical perspective, this finding implies that generation of fibrous veins during a first fluid event provides the mechanical discontinuity, which is reused during later fluid assisted thrusting.

The overprinting relationships between fibrous veins and slickensides indicate that deformation/precipitation events occurred in a cyclic fashion. Such information is a key towards the understanding of fluid assisted deformation and mineralization processes in compacted and anisotropic clay formations. On a regional scale, variations in paleo-deformation-mineralization events in the Opalinus Clay imply regional differences likely related to a gradually varying intensity of compressional (thrusting) and extensional (normal faulting) tectonics throughout northern Switzerland.

How to cite: Akker, I. V., Herwegh, M., Aschwanden, L., Mazurek, M., and Madritsch, H.: Microscale deformation in a compacted and anisotropic mudstone: the Opalinus Clay, northern Switzerland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2313, https://doi.org/10.5194/egusphere-egu22-2313, 2022.

EGU22-2375 | Presentations | GMPV6.1

Dynamic evolution of porosity in lower crustal faults during the earthquake cycle 

Stephen Michalchuk, Luca Menegon, François Renard, Alireza Chogani, and Oliver Plümper

Fractures derived from earthquakes can create permeable conduits for fluids to flow, enhancing fluid-rock interactions, and potentially altering the strength and rheology of fault systems. In the dry lower crust, numerous field examples show mutually overprinting pseudotachylytes (solidified melts produced during seismic slip) and mylonitized pseudotachylytes (produced during the post- and interseismic viscous creep). The mylonites contain hydrous mineral assemblages, suggesting episodic pulses of fluids infiltration and rheological weakening triggered by the earthquake. Here, our aim is to understand the porosity generating mechanisms during the earthquake cycle and characterize the intermittent evolution of porosity.

The Nusfjord East shear zone network (Lofoten, Norway) is an exhumed lower crustal section composed largely of anhydrous anorthosites that contain mutually overprinting pseudotachylytes and mylonitized pseudotachylytes. We present a microstructural analysis focusing on the mechanisms generating, maintaining, and destroying porosity from an exhumed network of lower crustal coeval pseudotachylytes and mylonites using synchrotron X-ray microtomography (SμCT), focused ion beam scanning electron microscopy (FIB-SEM) nanotomography, electron backscatter diffraction (EBSD) analysis, and SEM imaging.

In the pristine pseudotachylyte, SμCT data show that porosity is concentrated within the pseudotachylyte vein (0.16 vol% porosity), especially around framboidal garnet clusters and single garnet grains. SEM observations reveal that garnets within the vein often contain an asymmetric rim of barium-enriched K-feldspar. The damage zone of the host anorthosite on the other hand is efficiently healed (0.03 vol% porosity) primarily with the growth of plagioclase neoblasts nucleated from pulverized fragments of the host anorthosite, and secondly with the precipitation of barium-enriched K-feldspar found lining intragranular microfractures. A FIB-SEM transect along one of these microfractures shows a myrmekite microstructure formed during fluid-rock interaction that completely sealed the porosity.

In the mylonitized pseudotachylyte, SμCT data show a porosity of 0.03 vol%, mainly concentrated within monomineralic domains of plagioclase, which are interpreted as recrystallized, sheared survivor clasts of wall-rock fragments. EBSD analyses indicate that deformation in these monomineralic domains was accommodated by diffusion creep and grain boundary sliding. Polymineralic domains along the mylonitic foliation, which primarily derive from the overprint of the original pseudotachylyte veins, also deformed by diffusion creep and grain boundary sliding. However, unlike in the monomineralic domains, they lack detectable porosity. We interpret these observations to reflect the efficient precipitation of hydrous phases into the pores during creep cavitation.

Dynamic fracturing during earthquakes is the primary mechanism for porosity generation in the lower crust. Our study shows that porosity is further reduced by up to 90% when a pristine pseudotachylyte is viscously re-worked under deformation conditions promoting grain-size sensitive creep and grain boundary sliding. We suggest that such porosity reduction eventually results in shear zone hardening, which may evolve in the development of new pseudotachylytes overprinting the mylonites, as frequently observed in Nusfjord. Thus, earthquake-induced rheological weakening of the lower crust is intermittent, and occurs only as long as the fluid can infiltrate in the shear zone, thereby facilitating diffusive mass transfer.

How to cite: Michalchuk, S., Menegon, L., Renard, F., Chogani, A., and Plümper, O.: Dynamic evolution of porosity in lower crustal faults during the earthquake cycle, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2375, https://doi.org/10.5194/egusphere-egu22-2375, 2022.

EGU22-3016 | Presentations | GMPV6.1

Ion-dependent adhesion between calcite surfaces 

Joanna Dziadkowiec, Shaghayegh Javadi, Matea Ban, Bjørn Jamtveit, and Anja Røyne

Disjoining pressure that operates between mineral surfaces in fluid-filled granular rocks is often strongly influenced by the ionic composition of pore solutions. Can various ionic species exhibit a remarkably different influence on the mineral adhesion and thus the cohesion within granular rocks? We explore this question in atomic force microscopy (AFM) experiments using two brittle calcite surfaces in a symmetrical surface configuration. Our AFM results show a robust difference between the adhesion in the presence of Na+ and Ca2+ ions. The adhesion is significantly higher for monovalent Na+ at a given ionic strength in comparison to more hydrated divalent Ca2+ cations. In addition, the adhesive forces are weakly modulated by the varying Ca2+ concentration. We thus infer that for weakly charged minerals such as calcite, Ca2+ can sustain relatively high positive disjoining pressures and thus thicker water films between the contacting mineral grains.

How to cite: Dziadkowiec, J., Javadi, S., Ban, M., Jamtveit, B., and Røyne, A.: Ion-dependent adhesion between calcite surfaces, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3016, https://doi.org/10.5194/egusphere-egu22-3016, 2022.

EGU22-3024 | Presentations | GMPV6.1

Evolution of an active continental detachment fault: clumped isotope thermometry of syntectonic calcite, Mai'iu fault, SE Papua New Guinea 

Yaron Katzir, Marcel Mizera, Tim Little, and Nivedita Thiagarajan

Detachment faults that bound continental metamorphic core complexes typically record slip magnitudes of tens of kilometers—sufficient to exhume crustal rocks in their footwall from below the brittle-ductile transition. However, initiation and slip on low-angle (dip <30°) normal faults are at odds with the predictions of Coulomb failure during horizontal extension. What allows low-angle normal faults to acquire large displacements? Key obstacle to addressing this question is the scarcity of presently exposed active detachment faults. With a strike length of >60 km and a dip of 16°–21°at the surface, the active Mai’iu low-angle normal fault in SE Papua New Guinea has self-exhumed a smooth and corrugated footwall fault surface of >29 km width in the extension direction. Progressive strain localization preserved relicts of older-formed fault rocks in structurally lower positions on the fault surface including, from bottom-to-top, non-mylonitic schists through mylonites to cataclasites and ultracataclasites. The rapidly exhumed metabasaltic footwall of the Mai'iu fault contains multiple generations of deformed calcite veins that crosscut the sequentially formed fault rock units. Microstructural and stable and clumped isotope data of the syntectonic calcite are combined to reconstruct a profile of crustal strength with depth.

Clumped isotope thermometry of calcite in non-mylonitic schists and mylonites (n=8) yielded temperatures of 150-200°C. These temperatures are well below peak metamorphic temperatures of the metabasalt and mostly below the temperature range estimated by calcite twin morphologies in the non-mylonitic schists and mylonites (250-400°). Thus, they do not document calcite crystallization, but represent blocking of isotope reordering in calcite during cooling, However, calcite veins in cataclasites (n=3) record T=130-160°C, mostly below calcite blocking temperatures, and thus may be interpreted as true calcite precipitation or recrystallization temperatures. At ~ 12-20 km depth (T=275-370°C), mylonites accommodated slip on the Mai’iu fault at low differential stresses (25-135 MPa) before being overprinted by localized brittle deformation at shallower depths. At ~6-12 km depth (T=135-270°C) differential stresses in the foliated cataclasites and ultracataclasites were high enough (>150 MPa) to drive slip on mid-crustal portion of the fault (dipping 30-40°).

Carbon isotope ratios of calcite veins from all fault rocks are within a narrow range: õ13CCc = +2.1 to -2.6‰, typical of marine carbonates. However, their õ18OCc values are more variable and span distinct ranges for individual rock types: non-mylonitic metamorphic rocks, 25 to 27.5‰ (n=5), mylonites, 21 to 24‰ (n=9) and cataclasites, 21.5 to 22.5‰ (n=2). The foliation-parallel calcite-rich seams from the non-mylonitic schist were derived from intercalations of pelagic limestones, metamorphosed together with their host metabasalt. Moving upwards into the fault-zone mylonites and cataclasites, both isotope ratiosdecrease sharply, suggesting that CO2 derived by breakdown of organic matter was dissolved in groundwater introduced into the damage zone of the Mai’iu fault and mixed with the local metamorphic fluids.

How to cite: Katzir, Y., Mizera, M., Little, T., and Thiagarajan, N.: Evolution of an active continental detachment fault: clumped isotope thermometry of syntectonic calcite, Mai'iu fault, SE Papua New Guinea, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3024, https://doi.org/10.5194/egusphere-egu22-3024, 2022.

EGU22-3157 | Presentations | GMPV6.1 | Highlight

Terrestrial constraints on H2 generation during Martian serpentinization 

Benjamin Tutolo and Nicholas Tosca

Serpentinization, the water-driven alteration of olivine-rich rocks, plays an integral role in solar system evolution. While much attention has been directed towards the role of serpentinization in the evolution of our own planet, it has also been proposed as a mechanism for warming and stabilizing liquid water on early Mars, controlling the fate of the Martian hydrosphere, and originating life early in the planet’s history. Because olivine is widespread on the Martian surface and highly reactive in the presence of water, many researchers have hypothesized that serpentinization would have been common during periods of Martian history when liquid water was present. Observations of serpentine, the most abundant by-product of serpentinization, in intimate association with olivine on the Martian surface lends fundamental support to this hypothesis.

H2 and organic carbon production during typical serpentinization on Earth is fundamentally limited by the modest quantities of Fe in terrestrial mantle olivine, which is typically composed of just 10% of the Fe-endmember, fayalite. To explore how this limitation would differ during Martian serpentinization, we compiled analyses of olivines in Martian meteorites and those analyzed by Curiosity in Gale Crater, Mars. The results show that even the most magnesian Martian olivines contain around twice the Fe content of terrestrial mantle olivine, and most contain much more. Thus, to gain a better understanding of H2 and organic carbon production during Martian serpentinization, we must study serpentinization of atypical, Fe-rich olivines on Earth. To this end, we have performed and compiled analyses of serpentinites of the Duluth Complex (USA), which solidified from tholeiitic magmas broadly similar to those that produced the Martian crust and contains ferroan olivines representative of those on Mars. The data show increases in Fe(III)/Fe(tot) with increasing extents of serpentinization (as measured by H2O content) that mimic the trends observed during serpentinization of terrestrial mantle rocks.  However, because of the much higher primary fayalite content, the Duluth Complex serpentinites produced around 5 times the H2 at any given extent of serpentinization than those in an equivalent compilation of terrestrial serpentinites. This observation implies that even weakly serpentinized (20%) rocks on Mars would have produced as much H2 as fully serpentinized terrestrial mantle peridotite, and a formation as large and stratigraphically continuous as the Olivine Bearing Unit in Jezero Crater could have produced a very substantial amount of H2, even if it were only partially serpentinized. Thus, although orbiter observations suggest serpentine may be uncommon on the Martian surface, this does not necessarily indicate that serpentinization, and the reduced gases that it produced, did not play a significant role in the planet’s biogeochemical evolution.

How to cite: Tutolo, B. and Tosca, N.: Terrestrial constraints on H2 generation during Martian serpentinization, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3157, https://doi.org/10.5194/egusphere-egu22-3157, 2022.

EGU22-3267 | Presentations | GMPV6.1

Olivine and enstatite formation during seismic faulting in serpentinite: an experimental approach 

Wei-Hsin Wu, Li-Wei Kuo, Steven A. F. Smith, and Matthew S. Tarling

Olivine and enstatite, formed by dehydroxylation of serpentine, have been naturally and experimentally documented as evidence of paleo-earthquake rupture propagation within natural serpentinite-bearing slip zones. To investigate the rheological and textural evolution during dehydroxylation of serpentinite, we performed rotary-shear friction experiments on water-saturated serpentinite powders using drained and undrained conditions (where drained conditions allow for excess fluid pressure to escape the gouge holder). Using a purpose-built gouge sample holder containing a thermocouple 1.5 mm from the eventual principal slip zone (PSZ), the experiments were performed at a seismic slip rate (1 m/s) and 10 MPa normal stress. Mechanical results show that in undrained experiments, the apparent friction coefficient (μ) initially reaches a peak value of ~0.21-0.24, followed by dramatic weakening to a steady-state value of 0.12-0.09, associated with gouge compaction, while the temperature at the thermocouple steadily increased reaching a maximum of ~180°C. In drained experiments, a plateau-like friction coefficient with a value of ~0.42 was reached, associated with gouge compaction at a steady temperature of ~250°C at the thermocouple, followed by a drop to a steady-state value of ~0.19, associated with gouge dilation at a temperature of ~450°C. The friction coefficient then gradually increased, reaching a value of ~0.3 (i.e. restrengthening) with gouge compaction and a max. temperature at the thermocouple of ~635°C by the end of the experiment. The PSZ of the products were examined by scanning electron microscope, in-situ synchrotron X-ray diffraction, and focused ion beam transmission electron microscope. Microanalysis showed no mineral phase changes in undrained experiments, which we interpret to indicate that fluid vaporization and pressurization buffered the temperature to below that required for serpentinite dehydroxylation. However, the PSZ in drained experiments contains well-developed aggregates of nanometric, rounded to polygonal forsterite + enstatite, which provide evidence for serpentinite dehydroxylation at temperatures of >600°C within the PSZ. Our observations indicate that fluid drainage facilitates a significant temperature increase within the gouge layer at seismic slip rates. We conclude that dehydroxylation of natural serpentinite gouges may occur under relatively dry conditions or when co-seismic permeability increases (e.g. due to fracturing) allow for efficient fluid drainage and decrease the efficiency of thermal pressurization.

How to cite: Wu, W.-H., Kuo, L.-W., Smith, S. A. F., and Tarling, M. S.: Olivine and enstatite formation during seismic faulting in serpentinite: an experimental approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3267, https://doi.org/10.5194/egusphere-egu22-3267, 2022.

EGU22-3483 | Presentations | GMPV6.1

Rapid fluid infiltration recorded in the brucite-rich reaction zone along the antigorite veins from the Oman ophiolite 

Kazuki Yoshida, Atsushi Okamoto, Ryosuke Oyanagi, and Masao Kimura

Fluid flow in subduction zones is related to geological processes such as seismic and volcanic activities. However, the timescale of fluid flow and its flux in the supra-subduction setting is unclear. In this study, we report the novel texture of the antigorite veins with a brucite-rich reaction zone in dunite in the crust-mantle transition zone of the Oman ophiolite, and investigated the timescale and time-integrated fluid flux during the vein formation.

The antigorite veins occur in the drilling cores of serpentinized dunite in the crust-mantle transition zone taken from the Oman Drilling Project CM1 site (Wadi Zeeb, Northern Sharqiyah). The dunite samples are completely serpentinized and consist mainly of lizardite, brucite, magnetite, and Cr-rich spinel and are cut by the antigorite vein networks and later chrysotile. These features indicate that the antigorite veins formed at the stage of obduction of the Oman ophiolite. The antigorite veins, which are distinct by ‘bright’ networks by X-ray CT due to magnetite, occur preferentially in dunite (at 160 – 313 m along the CM1A). The veins are filled with a mixture of randomly orientated antigorite crystals and fine chrysotile. Some antigorite vein contains fragments of the host rock. The brucite-rich reaction zone was developed at both sides of the antigorite veins with a thickness of 0.5 – 4 mm. The reaction zone is composed of brucite (39.4 area%), chrysotile (59.3 area%), and magnetite (1.3 area%). The microtexture of the reaction zone indicates the brucite silicification after the brucite reaction zone formation. Mass balance and thermodynamic calculation suggest that silica was leached from the host rock lizardite during antigorite vein crystallization, resulting in the formation of the brucite reaction zone. Given solution chemistry and the amount of leached SiO2 during vein formation, the time-integrated fluid flux was estimated to be 105 - 106 m3(fluid) m-2(rock). A diffusion-controlled model suggests that the reaction zone was formed in a short time, ~10-1 - 100 years. These results suggest that a large amount of high-temperature fluid passed through the fracture network over several hundred meters in a short time at the earlier stage of the obduction of the Oman ophiolite.

How to cite: Yoshida, K., Okamoto, A., Oyanagi, R., and Kimura, M.: Rapid fluid infiltration recorded in the brucite-rich reaction zone along the antigorite veins from the Oman ophiolite, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3483, https://doi.org/10.5194/egusphere-egu22-3483, 2022.

EGU22-3558 | Presentations | GMPV6.1

Transient weakening during the granulite to eclogite transformation within hydrous shear zones (Holsnøy, Norway) 

Erwan Bras, Marie Baïsset, Philippe Yamato, and Loic Labrousse

In Holsnøy (Bergen Arcs, Norway), metastable granulite facies anorthosite rocks are partially eclogitised within hydrous shear zones, that have been interpreted as widening over time with fluid influx and strain. We here present a detailed petrological description of metre-scale shear zones from this area. The granulite protolith (originally plagioclase + garnet + two pyroxenes) is transformed into an albite + zoisite + garnet + clinopyroxene assemblage within a few tens of centimetres of the shear zones. The outer edge of the shear zones consists in a fine-grained heterogeneous assemblage of omphacite + zoisite + kyanite + garnet + phengite ± albite ± quartz. An eclogite composed of coarser omphacite + kyanite + garnet + zoisite + phengite quartz forms the core of the shear zones. As the shear zones widened over time, this lateral evolution from the edge to the core of the shear zones reflects the temporal evolution of the granulite from the beginning to the end of the eclogitisation reaction. The outer omphacite + zoisite + kyanite + garnet + phengite ± albite ± quartz assemblage therefore represents a transient eclogite facies assemblage. This transient assemblage appears to be mechanically weaker than both the starting granulite and the final eclogite, based on field and petrological findings. We investigate the impact of transient weakening during syn-tectonic metamorphism using a one-dimensional numerical model of a fluid-fluxed, reacting shear zone. Our numerical model shows that transient weakening is required to explain the field and petrological data. Furthermore, we show that, while fluid infiltration was predominantly responsible for the widening of the shear zones, strain hardening during the end of the eclogitisation reactions sequence had a noticeable widening effect on the shear zones.

How to cite: Bras, E., Baïsset, M., Yamato, P., and Labrousse, L.: Transient weakening during the granulite to eclogite transformation within hydrous shear zones (Holsnøy, Norway), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3558, https://doi.org/10.5194/egusphere-egu22-3558, 2022.

The incipient development of diagnostic high-pressure assemblages –the `eclogitization'– of granitoids, such as plagioclase-breakdown and small-scale formation of garnet and phengite does not require exogenous hydration because unlike dry protoliths like basalt/gabbro or granulite, granitoids s.l. contain crystallographically-bound H2O in biotite. During high-pressure overprint, partial biotite dehydration-breakdown causes a localized increase in the chemical potential of H2O (µH2O). Diffusion of H2O into nearby plagioclase induces the formation of diagnostic eclogite-facies assemblages of jadeite–zoisite–K-feldspar–quartz ± kyanite ± phengite that pervasively replace former cm-sized plagioclase without requiring the participation of free H2O. Depending on P–T evolution, similar textures may involve albite instead of jadeite. Plagioclase-breakdown may also occur due to simple burial because compression leads to an increase of µH2O, without requiring additional influx of H2O at the texture scale. However, diffusion of biotite-derived H2O into plagioclase sites likely favors reaction due to its catalytic effect. In parallel, ~100 µm-thick complementary coronae involving garnet phengite–quartz develop at former biotite–plagioclase/K-feldspar interfaces due to the coupled diffusion of FeO–MgO–H2O from biotite towards feldspars, and minor CaO in the opposite direction. The reaction textures likely create structural weaknesses and preferential fluid pathways, thereby promoting further hydration, deformation and equilibration along the prograde path. If exogenous H2O is introduced, it is accommodated in phengite growing at the expense of igneous K-feldspar and possibly in epidote-group minerals. Upon decompression, such hydrated rocks would dehydrate, thereby favoring fluid-assisted retrogression and loss of diagnostic eclogite-facies assemblages at lower pressure. Whereas the prograde reaction textures are only preserved at closed-system conditions and in the absence of deformation, they are suggested to commonly form during orogenic metamorphism of granitoids and quartzofeldspathic gneisses that dominate the continental crust in high-pressure terranes such as the Western Italian Alps or the Western Gneiss Region (Norway).

How to cite: Schorn, S.: Self-induced incipient `eclogitization' of metagranitoids at closed-system conditions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3832, https://doi.org/10.5194/egusphere-egu22-3832, 2022.

EGU22-4636 | Presentations | GMPV6.1

The record of deep fluid pressure in veins : a new method based on quartz geochemistry 

Hugues Raimbourg, Vincent Famin, and Aurélien Canizarès

Fluids are a primary control on deformation processes, in particular in the upper, brittle portion of the crust. In the mechanical framework of poroelasticity or friction, used to describe brittle rock behavior, the influence of fluid is integrated through the fluid pressure. High fluid pressure reduce the deviatoric stress necessary for slip ; for example during seismic slip, the temperature rise due to frictional work in the fault core might result in a large drop in resistance to further slip and constitutes therefore a very efficient lubricating process. Another example of the influence of fluid pressure is observed in deep slow slip events in subduction zones, where the slipping portion of the plate interface and domains of high fluid pressure migrate conjointly.

While models and observations highlight the large mechanical role of fluid pressure, measurements of fluid pressure below a few kilometers of depths are very indirect and plagued by large uncertainties. Veins constitute one of the ubiquitous by-products of the fluid-rock interaction during deformation at depths. Vein-forming mineral, such as quartz and calcite, trap, as inclusions, the fluid that was present during crystal growth. Fluid inclusions constitute therefore one of the very few record of the physicochemical conditions of the deep fluid.

We examined in this work three examples of syn-deformation quartz veins, from a japanese accretionary complex. The crystals within veins show growth rims, bringing to light the time evolution of the rock-fluid system. Many fluid inclusions are trapped within the growth rims ; in particular methane-rich fluid inclusions, which minimize the problem of late-stage reequilibration and therefore unravel the fluid pressure at the time of trapping. In parallel, those growth rims can be divided into two types, with either low or large content in trace elements (in particular aluminum).

We correlated the median fluid pressure recorded in fluid inclusions with the average Al concentration in quartz : High/low fluid pressure correspond to low/high Al concentration, respectively. Based on literature data about crystal growth in hydrothermal and magmatic contexts, it appears that the higher incorporation of impurities can be accounted for by rapid, out-of-equilibrium growth of quartz. We propose therefore a model of vein evolution with repetitions of large fluid pressure drop, where crystal grew rapidly and incorporated a large concentration in Al, alternating with longer period of slower growth, at higher fluid pressure, with a reduced incorporation of Al. The highest fluid pressure variations are of the order of 70MPa, and the corresponding Al concentration variations of the order of 0.28wt%.

Quartz veins are abundant in most, if not all tectonic contexts. In addition, Al concentration in quartz is preserved throughout exhumation, unlike fluid inclusions signal, which is in many cases questionable because of reequilibration. In conclusion, quartz geochemistry can be considered as a promising sensor of fluid pressure variations, which can provide access to the conditions of the fluid attending deformation of the brittle crust.

How to cite: Raimbourg, H., Famin, V., and Canizarès, A.: The record of deep fluid pressure in veins : a new method based on quartz geochemistry, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4636, https://doi.org/10.5194/egusphere-egu22-4636, 2022.

EGU22-5013 | Presentations | GMPV6.1

Dynamics of Crustal-Scale Fluid Flow: Interaction between Darcy and Hydrofracture Fluid Transport 

Tamara de Riese, Paul Bons, Enrique Gomez-Rivas, and Till Sachau

Fluid flow through the crust can be described as “bimodal”. At low hydraulic head gradients, fluid flows slowly through the rock porosity, which can be described as diffusional. Hydraulic breccias such as the massive Hidden Valley Breccia in South Australia or those in the Black Forest are evidences for very high fluid velocities, which can only be achieved by localized fluid transport, via hydrofractures. Hydrofractures propagate together with the fluid they contain, and high fluid fluxes during ascent indicate that fluid flow must have been highly intermittent. The propagation of hydrofractures and simultaneous fluid transport can be seen as a “ballistic” transport mechanism, which is activated when transport by diffusion alone is insufficient to release the local fluid overpressure. The activation of a ballistic system locally reduces the driving force, by allowing the escape of fluid.

 

We use a numerical model to investigate the properties of the two transport modes in general, the transition between them in particular, as well as the resulting patterns of this “bimodal transport” (de Riese et al., 2020). When hydrofracture transport is activated due to a low permeability relative to the fluid flux, many hydrofractures develop which do not extend through the whole system. When hydrofracture transport dominates, the system self-organizes and the size-frequency distribution of these hydrofractures follows a power-law size distribution. These hydrofractures organize the formation of large-scale hydrofractures. The large-scale hydrofractures ascend through the whole system and drain fluids in large bursts. Their size distribution shows “dragon-king”-like large hydrofractures that deviate from the power-law distribution. With an increasing contribution of porous flow, escaping fluid bursts become less frequent, but more regular in time and larger in volume.

 

The observed fluid transport behaviour may explain the abundance of crack-seal veins in metamorphic rocks, as well as the development of hydrothermal hydraulic breccia deposits at shallower crustal levels. Fluid transport through the crust is a highly dynamical process. A better understanding of the dynamics and pathways of fluid migration in the crust is of major interest, e.g. to avoid human induced seismicity. The bimodal-transport concept may apply to many systems with a slow and steady transport mechanism and a fast one that is triggered at a certain threshold (e.g. fault zones: slow creep and earthquakes).

 

de Riese, T., Bons, P. D., Gomez-Rivas, E., & Sachau, T. (2020). Interaction between Crustal-Scale Darcy and Hydrofracture Fluid Transport: A Numerical Study. Geofluids2020.

 

How to cite: de Riese, T., Bons, P., Gomez-Rivas, E., and Sachau, T.: Dynamics of Crustal-Scale Fluid Flow: Interaction between Darcy and Hydrofracture Fluid Transport, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5013, https://doi.org/10.5194/egusphere-egu22-5013, 2022.

EGU22-5102 | Presentations | GMPV6.1

Boron-rich hydrothermalism marking Early Permian extensional structures of the central Southern Alps, N Italy 

Sofia Locchi, Robert B. Trumbull, Stefano Zanchetta, Marilena Moroni, and Andrea Zanchi

During the Early Permian, the post-Variscan evolution of the present-day Alpine region was characterized by crustal extension combined with strong magmatic activity at different crustal levels (Schaltegger and Brack, 2007), which finally led to the development of intracontinental extensional basins filled with volcanoclastic sediments (e. g. the Orobic Basin). In the central Southern Alps (cSA) N Italy, the opening of these basins was controlled by low-angle normal faults (LANFs). We investigated several Early Permian faults of the Orobic Basin with emphasis on their original features, as they have exceptionally escaped most of the Alpine deformation (Blom and Passchier, 1997). The identified LANFs of the Orobic Basin are characterized by cataclastic bands sealed with cm to dm thick layers of dark, aphanitic tourmalinites (Zanchi et al., 2019). The tourmalinites formed in response to circulation of boron-rich fluids channelled along Early Permian fault systems related to opening of the Orobic Basin. The tourmalinized faults were first noted in various sites of the cSA during the 1990’s: several authors linked them to the uranium mineralization of the Novazza-Val Vedello district (Slack et al., 1996; Cadel et al., 1996; De Capitani et al., 1999), although their genesis has never been fully characterized and the connection with U-ore bodies has also not been deeply investigated so far.

In this work, we further characterize the occurrence and assess the cause of the regional hydrothermalism in the context of intracontinental extension during the Early Permian. Field-based structural analysis are combined with mineral and whole-rock geochemistry, geochronology, microstructural studies and boron- isotopic analysis of tourmalinites from different sectors of the study area, in order to evaluate the origin of hydrothermal fluids. Preliminary results demonstrate a temporal relationship between tourmalinites and Early Permian magmatism in the cSA. Geochemical data on major and trace elements together with B isotope ratios suggest a direct connection between tourmalinites and the U-mineralization at the basement-cover contact and along LANFs within the Orobic Basin.

 

Blom, J. C., and Passchier, C. W. (1997). Geologische Rundschau, 86, 627-636.

Cadel, G., et al. (1996). Memorie di Scienze Geologiche, 48, 1-53.

De Capitani, L., et al. (1999). Periodico di Mineralogia, 68, 185-212.

Schaltegger, U., and Brack, P. (2007). International Journal of Earth Sciences, 96(6), 1131-1151.

Slack, J., F., et al. (1996). Schweiz. Mineral. Petrogr. Mitt., 76, 193-207.

Zanchi A. et al. (2019). Italian Journal of Geosciences, 138, 184-201

 

How to cite: Locchi, S., Trumbull, R. B., Zanchetta, S., Moroni, M., and Zanchi, A.: Boron-rich hydrothermalism marking Early Permian extensional structures of the central Southern Alps, N Italy, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5102, https://doi.org/10.5194/egusphere-egu22-5102, 2022.

EGU22-5402 | Presentations | GMPV6.1

Quantifying microstructures of Earth materials: Reconstructing higher-order correlation functions using deep generative adversarial networks 

Hamed Amiri, Ivan Pires de vasconcelos, Yang Jiao, Pei-EN Chen, and Oliver Plümper

It is well established that effective and macroscopic properties of geological materials are controlled by the geometry and physical properties at small scales, i.e., by their microstructures. Recent progress in imaging technology has enabled us to visualize and characterize the microstructures at different length scales and dimensions. As Earth materials are often heterogeneous with a certain degree of randomness, such a characterization must be of statistical nature – and one approach to this end is performed by computing n-point correlation functions known as statistical microstructural descriptors. These microstructural descriptors can, in principle, then be directly employed in upscaling to predict the macroscopic behaviours of the system as a whole. Alternatively, once microstructural descriptors are inferred from one or more samples, they can be used to generate new, statistically-equivalent structures having a larger size and additional dimension – this process is known as reconstruction. While several approaches have been proposed in the past decades, advanced machine-learning based image processing methods have shown to be promising for reconstructing microstructures of chosen representative sizes. Here, we train a deep-convolutional generative adversarial network (GAN) to reconstruct two-dimensional electron microscopy images of two chemically-altered rock samples. We show that employing a Wasserstein-loss with a gradient penalty, instead of common binary cross entropy, results in improved training stability and high-quality reconstructed microstructures. To quantitatively evaluate how reconstruction performs in retrieving patterns with high-order spatial correlations, n-point polytope functions are calculated in both reconstructed and original microstructures, and mean square error (MSE) between them is used as a quality metric. These n-point polytope functions, which are a subset of n-point correlation functions, provide statistical information about symmetric higher-order geometrical patterns in microstructures. Furthermore, we compare our model with a benchmark reconstruction method based on a two-point correlation function and stochastic optimization by simulated annealing (SA). Our findings indicate that although showing the same two-point statistics, two microstructures can be morphologically and structurally different, emphasizing the need for coupling higher-order correlation functions with reconstruction methods. We also show that GANs are naturally able to capture higher-order correlation functions at short and long range scales due to the convolutional layers which can learn to extract complex structural features, leading to realistic image reconstructions. This is of critical importance for future schemes that aim to exceed the limits of current imaging techniques by reconstructing the higher-order geometry in complex heterogeneous systems and couple microstructures to macroscopic phenomena.

How to cite: Amiri, H., Pires de vasconcelos, I., Jiao, Y., Chen, P.-E., and Plümper, O.: Quantifying microstructures of Earth materials: Reconstructing higher-order correlation functions using deep generative adversarial networks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5402, https://doi.org/10.5194/egusphere-egu22-5402, 2022.

EGU22-7798 | Presentations | GMPV6.1

Different microstructures in low grade shear zone formed at comparable temperatures: effect of pre and syn-kinematic fluid-rock interactions 

Laura Airaghi, Khadija Alaoui, Benoit Dubacq, Claudio Rosenberg, and Nicolas Bellahsen

Different microstructures and quartz recrystallization mechanisms can be observed in shear zones of granites that formed in similar greenschist-facies conditions. It is generally assumed that temperature plays a major role on quartz rheology and recrystallization. However, at low-grade conditions, fluid percolation also controls strain accommodation, by favouring the growth of weak phases as phyllosilicates. The relative importance of temperature over fluid-induced softening reactions on microstructures remains however poorly constrained mainly because comparative studies among low-grade shear zones are lacking.

The present work focusses on two granitic massifs of the central Pyrenees deformed at greenschist-facies conditions but showing different structural styles. While in Bielsa granitoid, shear zones are spaced of ~ 100-200 m, in Maladeta strain is localised in shear zones spaced of ~ 1.5 km. The Bielsa granitoid, is pervasively altered at late-Variscan time, as suggested by petrography and trace elements variations uncorrelated to strain gradients, and then at Alpine time. Alpine mylonites are made of white mica at ~ 50 % vol. Quartz poorly recrystallizes by bulging. Geochemical whole-rock analyses show systematic variations of alkali, fluid and volume with increasing strain. These results point to a pervasive fluid-rock interaction before and during deformation in Bielsa.  In contrast, in high strain rocks of Maladeta, the magmatic mineral assemblage is largely preserved. Quartz pervasively recrystallizes by sub-grain rotation and white mica is less abundant (20% vol). Consistently, geochemical whole-rock analyses show no or little major element transfer across Maladeta shear zone at constant volume. This point to a lower pre and syn-kinematic fluid-rock interaction in Maladeta than in Bielsa. Thermometry on metamorphic chlorite show similar temperature ranges for deformation in the two massifs (280-350°C).

Variations of pre-kinematic hydrothermal alteration therefore strongly affect quartz recrystallisation mechanisms and microstructures, by controlling the abundance of weak phases as white mica. This process is observed despite very similar temperature ranges. Such variations may also explain the difference of structural style in the two massifs (distributed vs localised deformation) up to an outcrop scale.

How to cite: Airaghi, L., Alaoui, K., Dubacq, B., Rosenberg, C., and Bellahsen, N.: Different microstructures in low grade shear zone formed at comparable temperatures: effect of pre and syn-kinematic fluid-rock interactions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7798, https://doi.org/10.5194/egusphere-egu22-7798, 2022.

EGU22-8048 | Presentations | GMPV6.1

Influence of pore fluid pressure and differential stress on gypsum dehydration and rock texture revealed by 4D synchrotron X-ray tomography 

Damien Freitas, Roberto Rizzo, Florian Fusseis, Ian Butler, Sohan Seth, John Wheeler, Oliver Plümper, Hamed Amiri, Alireza Chogani, Christian Schlepütz, Federica Marone, and Edward Ando

Tectonic-scale features happening at convergent plates are ultimately the outcome of microscopic, grain scale processes. In collision zones, prograde metamorphism occurs by gradual increase of pressure and temperature [1; 2]. Among the most important prograde mineral reactions are dehydration reactions, which are characterized by solid volume reduction, porosity creation, fluid release and high pore fluid pressures [3]. Most models linking dehydration and mechanical instabilities [4-6] involve feedback loops between coupled chemical, hydraulic and mechanical processes. Feedbacks control pore fluid pressure build-up and drainage, and provide efficient pathways for the transport of chemical components. Gypsum dehydration is crucial in the formation of detachment faults thin-skinned tectonics [7]. It is also used as a proxy for serpentine dehydration and the generation of intermediate depth seismic events/aseismic slip activity [8].

We performed a set of experimental gypsum dehydrations both at the TOMCAT microtomography beamline at the Swiss Light Source, and in the laboratory. Using a modified version of the Mjolnir triaxial rig [9] that allowed control of pore fluid pressure in the synchrotron microtomography setup enabled us to document how differential stress (∆σ) and pore fluid pressure (Pf) influence the dehydration of Volterra alabaster gypsum to bassanite at a constant confining pressure and temperature in 4D.

We derived data on mineral phase transformation and formation of pore networks by applying a deep-learning algorithm in ORS Dragonfly® software, which reduced data processing times, minimized interpretation biases, and allowed analysing larger volumes. The results exhibit an extremely high accuracy compared to standard procedures. The analysis of phase proportions (gypsum, bassanite and porosity) of segmented volumes correlates very well to theoretical predictions indicating a correct segmentation from the algorithms and self-consistency of the generated datasets. Comparing results obtained  at various ∆σ and Pf to the light of mechanical data and additional in-house experiments allows us to better interpret their effect on reaction duration, magnitude and textural evolution of the rock. Transient phenomena as well as individual grain transformation and growth are now traceable in a fully automated way.

Our data further our understanding of gypsum dehydration: We found that ∆σ greatly influences the assemblage of the bassanite needles, which tend to grow nearly vertical at ∆σ ≅ 0. Increasing ∆σ significantly increases sample compaction. On the contrary, increasing Pf decreases the bulk deformation and slows down the reaction. As pores grow around bassanite needles, the control of the orientation of needles by differential stress can influence the overall pore network and thus introduce anisotropies during transient and final stages of the reaction. Our data confirm that ∆σ and Pf greatly influence transient and final rock texture, which has implications on drainage during nappe emplacements.

References: [1] Hacker et al., 2003, /10.1029/2001JB001129; [2] Peacock, 2001, 10.1130/0091-7613(2001)029<0299:ATLPOD>2.0.CO;2 [3] Llana-Funez et al. 2012, /10.1007/s00410-012-0726-8; [4] Raleigh and Paterson, 1965;/10.1029/JZ070i016p03965  [5] Dobson et al., 2002; /10.1126/science.1075390 [6] Jung et al., 2004; /10.2747/0020-6814.46.12.1089 [7] Hubbert and Rubey, 1959;/10.1130/0016-7606(1959)70[115:ROFPIM]2.0.CO;2 [8] Rutter et al. 2009; /10.1016/j.jsg.2008.09.008 [9] Butler 2020, /10.1107/S160057752001173X.

How to cite: Freitas, D., Rizzo, R., Fusseis, F., Butler, I., Seth, S., Wheeler, J., Plümper, O., Amiri, H., Chogani, A., Schlepütz, C., Marone, F., and Ando, E.: Influence of pore fluid pressure and differential stress on gypsum dehydration and rock texture revealed by 4D synchrotron X-ray tomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8048, https://doi.org/10.5194/egusphere-egu22-8048, 2022.

EGU22-8711 | Presentations | GMPV6.1

Texturally controlled oxygen isotope analyses of serpentine phases record the multistage hydration history during abyssal serpentinization 

Coralie Vesin, Daniela Rubatto, Thomas Pettke, and Etienne Deloule

Serpentinization of ultramafic mantle rocks is one of the main reactions leading to a significant water incorporation into the oceanic lithosphere. The multiphase hydration is yet poorly constrained, in terms of sequence of events, their chemical and isotopic compositions, and the reaction conditions (temperature, fluid composition and the water/rock ratio). We present here the first study on Iberia and Newfoundland passive margins samples (oceanic drill core samples, ODP, from Site 1070 and Site 1277) that closely correlates petrographic observation, in situ oxygen isotopic data and major and trace elements mobility in serpentine phase.

The serpentine minerals lizardite and chrysotile are the main hydrous phases formed during the serpentinization reaction. These minerals crystallize in specific textures, depending on the primary minerals being replaced: (i) serpentine in mesh texture after the alteration of olivine, and (ii) serpentine as bastite pseudomorphing pyroxenes. As the textural control is the key to detect multistage fluid uptake during progressive hydration, we used Secondary Ion Mass Spectrometry (SIMS) to achieve a good spatial resolution of ∼20 µm for in situ oxygen isotope measurements. The trace elements analyses were analyzed with laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) and a spot size of ∼38 µm. Newfoundland samples show less variability in the oxygen isotope composition than Iberia samples and have values higher than the mantle composition, suggesting low temperature of serpentinization (110-200°C). One of the Iberia samples shows similar variability of the oxygen isotope composition but lower values than 𝛿18Omantle (temperature around 140-200°C). The second sample has the highest variability: (i) homogeneous mesh rim texture with 𝛿18O = 4.4 ± 0.8 ‰ (2𝜎), (ii) wide compositional range for mesh centers with 𝛿18O = 4.0 - 7.7 ‰, and (iii) bastite with large isotopic variation from 5.5 to 13.5 ‰. These values suggest a large hydration temperature range from 60-200°C within a single sample.

Texturally controlled rare-earth element (REE) analyses of the serpentine minerals reveal inherited, typical melt depletion patterns of the protolith, for both localities. The trace element composition of serpentine in the different textural domains displays typical signatures related to the precursor minerals (olivine vs. pyroxene), particularly in terms of Ni/Cr ratio. Positive anomalies of fluid-mobile elements (e.g. B, Sr, As) confirm hydration of the mantle rocks during oceanic serpentinization.

How to cite: Vesin, C., Rubatto, D., Pettke, T., and Deloule, E.: Texturally controlled oxygen isotope analyses of serpentine phases record the multistage hydration history during abyssal serpentinization, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8711, https://doi.org/10.5194/egusphere-egu22-8711, 2022.

EGU22-9789 | Presentations | GMPV6.1

Reconstructing fluid pathways by studying dedolomitization process: example of the Benassal Formation, Maestrat Basin, Spain 

Guilhem Hoareau, Stephen Centrella, Nicolas E. Beaudoin, and Jean-Paul Callot

Dedolomitization i.e. replacement of dolomite by calcite, is an important fluid-mediated replacement process occurring during carbonate diagenesis in basins. Especially, dedolomitization impact local reservoir rock properties, affecting the reservoir quality and rheology. The process of dedolomitization have been the subject of several studies but still, the controlling mechanism is not fully understood.

We investigate samples from the Maestrat Basin in Spain, formed during the upper Jurassic- lower Cretaceous. Between the Eocene and the Oligocene, the bassin recorded a compressive event and a general surrection responsible of dedolomitization. The detailed investigation of the progressive replacement of the original dolostone to the newly formed rock composed by calcite provide a key example to understand the dedolomitization process. Across the replacement interface, crystallographic orientation (EBSD) of the parent dolomite crystal is preserved in the calcite and no chemical zonation for major elements (EPMA) are visible in both phases, supporting a dissolution-precipitation mechanism. In order to better constrain the chemical evolution of the reaction, quantitative trace elements mapping (fs-LA-ICP-MS) was carried out and coupled to mass balance equations to quantify the elements gained and lost during the reaction. Results show a net gain of mass (~5%) with a loss of heavy Rare Rarth Elements and a gain in light ones. The specific gain in Zn and Rb pinpoints that the infiltrated fluid flowed through MVT deposits already present in the area.

How to cite: Hoareau, G., Centrella, S., Beaudoin, N. E., and Callot, J.-P.: Reconstructing fluid pathways by studying dedolomitization process: example of the Benassal Formation, Maestrat Basin, Spain, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9789, https://doi.org/10.5194/egusphere-egu22-9789, 2022.

EGU22-11056 | Presentations | GMPV6.1

Progressive veining during peridotite carbonation: insights from listvenites in Hole BT1B, Samail ophiolite (Oman) 

Manuel D. Menzel, Janos L. Urai, Estibalitz Ukar, Thierry Decrausaz, and Marguerite Godard

The reaction of serpentinized peridotites with CO2-bearing fluids to listvenite (quartz-carbonate rocks) requires massive fluid flux and significant permeability despite increase in solid volume. Understanding the mechanic-hydraulic interplay and the conditions, mechanisms and structures that enhance or hamper progress of this reaction is key to estimate the scale of long-term carbon fluxes and reservoirs in mantle rocks and their potential for industrial CO2 removal by mineral carbonation. Here we present a detailed microstructural analysis of listvenite and serpentinite samples from Hole BT1B of the Oman Drilling Project, which helps to understand the mechanisms and feedbacks during vein formation in this process [1]. The samples contain abundant magnesite veins in closely spaced, parallel sets and younger quartz-rich veins. These veins constitute large volumes of the listvenites, showing that fracturing and related advective fluid flow were integral to carbonation progress. Cross-cutting relationships suggest that antitaxial, zoned carbonate veins with elongated grains growing from a median zone towards the wall rock are among the earliest structures to form during carbonation of serpentinite. They show a bisymmetric chemical zoning of variable Ca and Fe contents with a systematic distribution of SiO2 and Fe-oxide inclusions; this and cross-cutting relations with Fe-oxides and Cr-spinel indicate that they record progress of reaction fronts during replacement of serpentine by carbonate in addition to dilatant vein growth. Euhedral terminations and growth textures of carbonate vein fill together with local dolomite precipitation and voids along the vein – wall rock interface suggest that these antitaxial veins acted as preferred fluid pathways allowing infiltration of CO2-rich fluids necessary for carbonation to progress. Fluid flow was probably further enabled by external tectonic stress, as indicated by the close spacing and subparallel alignment of these carbonate veins. As carbonation progressed, permeability was reduced during subsequent quartz veining and silica replacement of the matrix, but the scarcity of remnant serpentine in listvenite horizons indicates that penetration of CO2-rich fluid through the vein and matrix permeability network was sufficient for carbonation to proceed to completion.

[1] Menzel, et al., Solid Earth Discussions [preprint], https://doi.org/10.5194/se-2021-152, in review, 2022.

M.D.M. and J.L.U. acknowledge funding of DFG grants UR 64/20-1, UR 64/17-1.

How to cite: Menzel, M. D., Urai, J. L., Ukar, E., Decrausaz, T., and Godard, M.: Progressive veining during peridotite carbonation: insights from listvenites in Hole BT1B, Samail ophiolite (Oman), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11056, https://doi.org/10.5194/egusphere-egu22-11056, 2022.

EGU22-11319 | Presentations | GMPV6.1

On the potential role of reactive flow precipitation due to fluid-pressure gradients for the genesis of olivine veins in subducted metaserpentinite 

José Alberto Padrón-Navarta, Antonio Jabaloy-Sánchez, Vicente López Sánchez-Vizcaíno, María Teresa Gómez-Pugnaire, Karoly Hidas, and Carlos J. Garrido

Serpentinite-derived fluids are released at different P and T conditions through several quasi-discontinuous dehydration reactions, such as the breakdown of brucite and antigorite forming olivine at forearc depths, and the terminal breakdown of antigorite to olivine and orthopyroxene at subarc depths. In subduction-related metamorphic terranes, the record of the colder and shallower brucite-breakdown reaction (< 1.0 GPa and < 450 ºC) in serpentinite occurs as locally olivine veining, whereas the deeper and hotter high-pressure terminal antigorite dehydration (> 1.5 GPa and ca. 660 ºC) shows pervasive replacement patterns with varied textures. Previous works have provided important constraints on the contrasting fluid flow mechanisms associated with these dehydration reactions, but the potential role of the stress field in controlling the geometry of the structures and eventually dictating the fluid pathways remains poorly understood.

Here we report the results from field observations from Cerro del Almirez (Nevado-Filábride Complex, Betic Cordillera, S. Spain) that records the formation of olivine-rich veins in prograde serpentinite at temperatures lower than the terminal antigorite dehydration. We show the existence of two generations of abundant olivine-rich veins formed as open, mixed-mode and shear fractures during prograde metamorphism. Type I veins were likely synchronous with the development of the serpentinite main foliation, whereas Type II veins postdate the foliation indicating that Atg-serpentinites experienced punctuated brittle behavior events during subduction. Type I veins were formed by the fluid overpressure developed during the brucite breakdown reaction, whereas Type II were potentially formed by continuous compositional and structural changes in antigorite that released subordinate amounts of fluids. Type II olivine-rich veins were formed by brittle failure in a well-defined triaxial stress field and were not significantly deformed after their formation.

We interpret olivine-rich veins as due to the replacement of antigorite by olivine at the walls of the crack due to reactive fluid-flow dissolution and precipitation. The ultimate driving force for the dissolution and precipitation is the low and contrasting solubility of SiO2 and MgO in the aqueous fluid in combination with fluctuations in the fluid pressure relative to the lithostatic pressure. Equilibria under lower fluid pressure in the crack caused the nucleation and growth of olivine at the expense of antigorite dissolution. Comparison of the principal stress orientation inferred from Type II veins with those formed at peak metamorphic conditions in the ultramafic rocks at Cerro del Almirez shows a relative switch in the orientation of the maximum and minimum principal stress. These relative changes can be attributed to the cyclic evolution of shear stress, fluid pressure and fault-fracture permeability allowing for stress reversal.

FUNDING: This work is part of the project DESTINE (PID2019-105192GB-I00) funded by MICIN/AEI/10.13039/501100011033  and the  FEDER  program  “Una manera de hacer Europa”. J.A.P.N. acknowledges a Ramón y Cajal contract (RYC2018-024363-I) funded by 452MICIN/AEI/10.13039/501100011033 and the FSE program “FSE invierte en tu futuro”.

How to cite: Padrón-Navarta, J. A., Jabaloy-Sánchez, A., López Sánchez-Vizcaíno, V., Gómez-Pugnaire, M. T., Hidas, K., and Garrido, C. J.: On the potential role of reactive flow precipitation due to fluid-pressure gradients for the genesis of olivine veins in subducted metaserpentinite, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11319, https://doi.org/10.5194/egusphere-egu22-11319, 2022.

EGU22-13126 | Presentations | GMPV6.1

Chemistry breaks rocks and self-accelerate fluid flow in the lithosphere: Experimental insights from MgO–H2O system 

Masaoki Uno, Atsushi Okamoto, and Noriyoshi Tsuchiya

Hydration and carbonation reactions within the Earth cause an increase in solid volume by up to several tens of vol%, which can induce stress and rock fracture [e.g., 1]. Observations of naturally hydrated and carbonated peridotite and troctolite suggest that permeability and fluid flow are enhanced by reaction-induced fracturing [e.g., 2, 3]. However, permeability enhancement during solid-volume-increasing reactions has not been achieved in the laboratory, and the mechanisms of reaction-accelerated fluid flow remain largely unknown. Here, we present the first report of significant permeability enhancement by volume-increasing reactions under confining pressure [4]. The hydromechanical behaviour of hydration of sintered periclase [MgO + H2O → Mg(OH)2] depends mainly on the initial pore-fluid connectivity. Permeability increased by three orders of magnitude for low-connectivity samples, whereas it decreased by two orders of magnitude for high-connectivity samples. Permeability enhancement was caused by hierarchical fracturing of the reacting materials, whereas decrease was associated with homogeneous pore-clogging by the reaction products. These behaviours suggest the fluid flow rate, relative to reaction rate, is the main control on hydromechanical evolution during volume-increasing reactions. We suggest that an extremely high reaction rate and low pore-fluid connectivity lead to local stress perturbations, and are essential for reaction-induced fracturing and accelerated fluid flow during hydration/carbonation.

 

[References]

1: Kelemen and Hirth, 2012. EPSL 345–348, 81–89.

2: Jamtveit, Malthe-Sørenssen, Kostenko, 2008. EPSL 267, 620–627.

3: Yoshida, Okamoto et al., 2020 JGR 125, e2020JB020268.

4: Uno, Okamoto, Tsuchiya et al., 2022. PNAS 119, 3, e2110776118.

How to cite: Uno, M., Okamoto, A., and Tsuchiya, N.: Chemistry breaks rocks and self-accelerate fluid flow in the lithosphere: Experimental insights from MgO–H2O system, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13126, https://doi.org/10.5194/egusphere-egu22-13126, 2022.

In the Piemonte-Liguria ophiolites of the western Alps, the Zermatt-Saas unit is characterized by a widespread eclogite facies metamorphism. Eclogitic rocks are derived from basaltic or gabbroic protoliths. Peak metamorphic conditions are indicated by omphacite, almandine-rich garnet, rutile and Fe-poor epidote assemblages, which allow to infer temperatures between 550 and 600°C and pressures up to 2.5 GPa.
This aim of this contribution is to report the results of a petrologic analysis of an eclogitic breccia exposed in the Zermatt-Saas unit in the Monte Avic area, Aosta valley. The fragments consist of eclogitic gabbro, while the matrix is made of omphacite locally retromorphosed into blueschist to greenschist facies assemblages. Clasts are characterized by abundant atoll-shaped garnets. Two types of atoll-shaped garnets are distinguished: type I garnets consist of an almandine-rich unzoned core, a finely oscillatory zoned rim with alternating grossular-rich and almandine-rich overgrowths, and omphacite between core and rim. Type II garnets are similar to type I garnets, the only difference being titanite (+/- epidote) between core and rim. The atoll-shaped garnets result from two episodes of fluid-mineral interactions. For type I garnets, these interactions took place under high-pressure conditions (stability of omphacite), and under medium-pressure conditions (stability of titanite) for type II garnets.
Brecciation is characterized by pervasive fracturing. The two types of atoll-shaped garnets are fractured. The fractures are sealed by omphacite. This shows that brecciation took place after the formation atoll-shaped garnets. On-going investigations aim at identifying the chemical signature of the reacting fluids and estimating precise pressure and temperature conditions of fluid-mineral interactions.

How to cite: Lecacheur, K., Fabbri, O., Hertgen, S., and Leclere, H.: Fluid-rock interactions at high-pressure metamorphic conditions: An analysis of atoll-garnets preserved in eclogitic breccias from the Zermatt-Saas zone, Italian Alps., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13241, https://doi.org/10.5194/egusphere-egu22-13241, 2022.

EGU22-162 | Presentations | EMRP1.17

Viscoplastic Rheological Modelling- A Realistic Approach to Natural Ductile Shear Zones 

Arnab Roy, Puspendu Saha, and Nibir Mandal

Crustal deformations generally undergo a brittle-ductile transition with depth, producing fault-dominated structures at shallow depths, replaced by ductile shear zones at middle and lower crustal levels. One of the keys to shear zone modelling concerns the choice of rheological approximations that can successfully reproduce the characteristic features of natural ductile shear zones in the models.  With the help of 2D FE (finite element) simulations, this study shows viscoplastic rheology as a suitable rheological approximation to predict the competing growth and orientations of multiple sets of secondary shear bands in a ductile shear zone. The viscoplastic rheology is modelled by combining bulk viscous weakening of the shear zone material and plastic yielding (Drucker-Prager criterion) to replicate strain-softening behaviour, where the instantaneous viscosity decreases nonlinearly with increasing strain. The cohesive strength of the material is also assumed to reduce with progressive plastic strain. This rheological combination allows us to replicate the various shear band networks found in crustal-level ductile shear zones. It also addresses the conditions for fluid flow into ductile shear zones, which leads to metamorphic reactions, mineralisation, etc. We validate our model results with field observations of similar shear band structures from the Eastern Indian Precambrian craton. The present study finally leads us to conclude that a pressure-dependent viscoplastic rheology is an ideal rheological approximation to model ductile shear zones extensively found in this craton.

How to cite: Roy, A., Saha, P., and Mandal, N.: Viscoplastic Rheological Modelling- A Realistic Approach to Natural Ductile Shear Zones, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-162, https://doi.org/10.5194/egusphere-egu22-162, 2022.

EGU22-3971 | Presentations | EMRP1.17

On the stability of carbonate-bearing faults at the brittle-to-ductile transition 

Francesco Figura, Carolina Giorgetti, Gabriel Meyer, and Marie Violay

The majority of the seismic events in the Mediterranean region are hosted in carbonate-bearing rocks at depths representative of the semi-brittle regime. Within this regime, both brittle behavior (i.e. deformation is localized on the fractures and on the faults) and ductile one (i.e. deformation is distributed and accommodated in the rock core) coexist. The influence of this interplay on the nucleation and propagation of seismic events is poorly studied. Up to now, most experimental work has been conducted far from in-situ conditions, mostly at room temperature and low confining pressure.

Here we constrain the frictional behavior of faults in carbonate rocks under conditions relevant for their brittle-to-ductile transition. Velocity-step experiments are performed through the HighSTEPS (Strain, TEmperature, Pressure, Speed) biaxial apparatus installed at EPFL, investigating sliding velocities from 10-6 m/s to 10-2 m/s. Experiments are conducted under different values of confining pressure (Pc 15 MPa and Pc 50 MPa) and normal stress (σn 29 MPa and σn 95 MPa) on the experimental faults, keeping the ratio between them constant (around 2). The local strain field along the fault was measured with strain gauges. The collected data were modeled with rate-and-state friction laws (RSFLs) to define the rate and state parameters relate to the critical condition for fault stability. Moreover, microstructural observations of the post mortem sample were conducted at the SEM, to investigate the deformation mechanisms active during the experiments.

These results shed light on the evolution of rate-and-state frictional parameters with depth, as well as their dependence on the strain partitioning between on-fault slip and bulk-accommodated deformation with increasing depth.

How to cite: Figura, F., Giorgetti, C., Meyer, G., and Violay, M.: On the stability of carbonate-bearing faults at the brittle-to-ductile transition, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3971, https://doi.org/10.5194/egusphere-egu22-3971, 2022.

EGU22-5029 | Presentations | EMRP1.17

The localized to ductile transition in porous rocks : experimental investigation on Volvic basalt. 

Gabriel Meyer, Marie Violay, and Michael Heap

With increasing depth, the rheology of rocks gradually transitions from brittle (localized, fractures) to ductile (homogeneous flow). Recently, it was demonstrated that, in the crust, the transitional zone might extend to shallower depth than previously thought (2km) with a zone where the deformation regime can be both localized and ductile (the LDT). In this regime, both extremely localized (fault slip) and distributed (cataclastic flow and/or plasticity) deformation may occur concurrently. This observation had great importance since the ductile regime is commonly thought to be aseismic and to mark the maximum depth of earthquake nucleation.

However, this observation was made experimentally in non-porous rocks; porous rocks on the other hand display an additional characteristic in that their ductile behaviour may consist in the formation of compactions bands which greatly impact the behaviour of porous reservoirs and systems (e.g., volcanoes). Moreover, ductile rocks are commonly believed to be aseismic, the potential coexistence of both ductile and localized regimes in reservoir rocks might therefore have great implications for induced seismicity mitigation.

Here, we present three conventional triaxial experiments on Volvic basalt (homogeneous, istropic, fine grain). We deformed cylindrical cores equipped with strain gages at 5MPa and room temperature until a sample-scale fracture nucleated and propagated. Subsequently, we increased confining pressure step wise, loading the sample every step until 0.2% irrecoverable strain was accumulated in the sample. In between confinement steps, the differential stress was unloaded. A pair of Linear Variable Differential Transformers (LVDTs) was used along with the strain gauges to accurately monitor the deformation behaviour of the samples.

We show that Volvic basalt transitions from being purely localized to being purely ductile over a rather narrow pressure range from 40 to 80 MPa. The transition initiates when the frictional strength of the fault equates the yield strength of the bulk and terminates when it becomes greater than the maximum strength of the bulk. In this pressure range, deformation is initially accommodated in the bulk (most likely by compaction bands) until strain hardening eventually leads to fault reactivation. Once both fault sliding and bulk flow are active, the partitioning of strain between the two can be described by the same empirical ratio as that already established for non-porous rocks, i.e. (σf - σy)/ (σflow - σy).

We conducted a second experiment at a faster strain rate (10-4 s-1) and show that faster deformation promotes brittle behaviour which pushes the LDT to greater confinement (i.e., greater depth).

Additionally, we conducted a similar experiment in the presence of water. In this case, the LDT occurs at lower confinement, showing that, fluids, by promoting ductile processes such as stress-corrosion, bring the LDT to shallower depth.

Our results are crucial for the understanding of reservoirs where ductile deformation (compaction bands) and induced earthquake mitigation have to be finely tuned.

How to cite: Meyer, G., Violay, M., and Heap, M.: The localized to ductile transition in porous rocks : experimental investigation on Volvic basalt., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5029, https://doi.org/10.5194/egusphere-egu22-5029, 2022.

EGU22-5863 | Presentations | EMRP1.17

Velocity-dependent friction of granitoid gouge under hydrothermal conditions: A contribution to understanding of fault zone seismicity 

Weijia Zhan, André Niemeijer, Natalia Nevskaya, Alfons Berger, Chris Spiers, and Marco Herwegh

Fault gouges of granitoid composition represent the principal non-cohesive tectonites within fault zones in the continental crust. Their velocity-dependent friction is crucial for understanding earthquake nucleation and the depth distribution of fault-related seismicity in granitoid shear zones (Wehrens et al. 2016; Blanpied et al. 1998). In the framework of rate-and-state friction laws (RSF), the friction parameter (a-b) is measured in sliding experiments to describe the velocity dependence of friction in fault gouges (Scholz, 1998). A velocity-strengthening system is frictionally stable, (a-b) >0, whereas a velocity-weakening system can be frictionally unstable, (a-b) <0. In earthquake mechanics, velocity weakening is prerequisite for stick-slip deformation, i.e. the nucleation of earthquakes. Although (a-b) values of granitoid gouge are sensitive to varying temperature conditions and sliding velocities, only a few studies have examined this velocity-dependence under hydrothermal conditions.

To address this issue, we conducted velocity stepping sliding experiments under hydrothermal conditions by using a ring shear apparatus. The powdered starting gouge was derived from a granitoid mylonite collected at the NAGRA Grimsel Test Site (Central Swiss Alps). The applied velocity steps were 1-3-10-30-100 μm/s. Pore fluid pressure and the effective normal stress were 100 MPa. Temperatures explored ranged from 20-650 °C. Values of (a-b) were obtained from RSF model inversions of the evolution of friction coefficients at mechanical steady state conditions. Our experiments showed pronounced changes in (a-b) values with across the full range of temperatures up to 650 °C and velocities investigated. At temperatures below ~100 °C and above ~400 °C, we observed mostly velocity strengthening with positive (a-b). In contrast, velocity weakening with negative (a-b) was observed between ~100 °C and ~400 °C. Samples deformed at a sliding velocity of 100 μm/s deviated slightly from this trend, as (a-b) values were negative between ~200 °C and ~400 °C.

The presented experimental study demonstrates a significant influence of temperature and sliding velocity on velocity-dependence during deformation of granitoid gouge. We suggest that the observed transitions in velocity dependence reflect an interplay of interactions. In terms of crustal faulting, our data suggest the existence of a seismogenic window that limits the depth distribution of earthquakes on faults in granitoid shear.

 

REFERENCES

Wehrens, P. C., Berger, A., Peters, M., Spillmann, T., Herwegh, M. 2016: Deformation at the frictional-viscous transition: Evidence for cycles of fluid-assisted embrittlement and ductile deformation in the granitoid crust, Tectonophysics, 693, 66-84.

Blanpied M. L., Tullis T. E., Weeks J. D. 1998: Effects of slip, slip rate, and shear heating on the friction of granite.

Scholz, C. H. 1998: Earthquakes and friction laws, Nature, 391, 37-42.

How to cite: Zhan, W., Niemeijer, A., Nevskaya, N., Berger, A., Spiers, C., and Herwegh, M.: Velocity-dependent friction of granitoid gouge under hydrothermal conditions: A contribution to understanding of fault zone seismicity, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5863, https://doi.org/10.5194/egusphere-egu22-5863, 2022.

Amphibole is an important mineral in rocks of the lower crust and in subduction zones, forming as the product of metamorphic reactions and hydration of mafic rocks. As such, the textural and rheological properties of amphibole are of relevance for assessing the physical properties of these tectonic provinces. Aggregates containing amphibole grains often exhibit a strong texture, i.e., a crystallographic preferred orientation (CPO). Since amphibole possesses inherent anisotropic properties, the CPO will affect the bulk strength and elastic properties. However, amphibole’s rheological behavior is not well understood as its capability to deform purely via plastic deformation remains unresolved, previous studies suggesting numerous deformation mechanisms such as semi-brittle and cataclastic flow, dissolution precipitation, dislocation creep, recrystallization, micro-twinning, and diffusion assisted creep. Here, we use pre-textured natural samples cored at 60° to the foliation and lineation to investigate the deformation mechanism/s activated in a polycrystalline aggregate/rock of well-oriented amphibolite-rich hornblende. Samples from the Mamonia complex (Cyprus) with hornblende as the dominant mineral (> 70 % modal fraction) and strong initial alignment of the [001] axis were deformed using a Griggs-type solid-medium apparatus. Experiments were run at 1 GPa confining pressure, temperatures of 400 to 800 °C, and a strain rate of ~10-5 1/s. Samples show temperature-dependent differential stress that falls below the Goetze criteria (i.e., below the confining pressure, 1 GPa) - ~700, 500, and 200 MPa for samples deformed at 400, 600, and 800 °C, respectively. Microstructural analysis using Electron backscatter diffraction (EBSD) reveals folding and kink bands, accommodated by both plastic mechanisms, via dislocation glide on the hornblende easy slip system, and brittle mechanisms, via micro-fracturing along the crystal cleavage (110). We discuss the implications of the interplay and contribution of different deformation mechanisms for our ability to translate laboratory experiments to flow laws for the lower mantle and subduction zone interfaces.

How to cite: Boneh, Y., Sarah, I., and Renner, J.: Mechanism/s of deformation and strength of experimentally deformed hornblende-rich amphibolite with a strong pre-existing texture, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6966, https://doi.org/10.5194/egusphere-egu22-6966, 2022.

EGU22-7954 | Presentations | EMRP1.17

Experimental study of the impact of hydration extent on the strength of the lower continental crust 

Lisa Katharina Mohrbach, Joerg Renner, and Sarah Incel

Previous experimental data and field observations demonstrate that fluids have a significant influence on rock strength. The relation between strength and hydration extent of the lower continental crust is still poorly constrained and thus a matter of an ongoing debate. We tested the impact of hydration extent on the strength of rocks representing the lower continental crust by performing deformation experiments on various plagioclase-epidote mixtures as well as on natural granulite samples in a Grigg's type deformation apparatus. In these samples, the plagioclase component represents rocks of the lower continental crust and epidote reflects hydration extent, because, alongside with quartz, kyanite and jadeite or albite, it forms as a decomposition product of plagioclase at high-pressure/ high-temperature conditions in the presence of even small amounts of fluids. To quantify the relation between strength and epidote content, we conducted the tests on plagioclase-epidote powders with a grain size of 90-135 mm and plagioclase-epidote ratios of 100:0, 99:1, 98:2, 95:5, 90:10, 85:15, and 0:100. The pre-dried powders were first hot-pressed at 550 °C and a confining pressure of 1 GPa for 3 h in the Griggs apparatus. Mixtures were subsequently deformed at 1 GPa and 550 to 650 °C at strain rates of 5·10-6 to 5·10-5 s-1. All stress-strain curves show pronounced maxima followed by strain softening towards a final strength. The deformation data yield an exponential decrease of the ultimate strength with increasing epidote content. Investigations of the microstructures of samples deformed at 550 °C and 5·10-5 s-1 using the SEM and polarized light microscopy reveal cataclastic flow by grain-scale fracturing of both epidote and plagioclase and the rotation and alignment of epidote grains at angles between 60° and 70° to the maximum principal stress  σ1. In addition, plagioclase grains show pronounced undulatory extinction but we found no evidence for deformation twinning. Some samples exhibit networks of conjugate bands of fine-grained plagioclase surrounding larger plagioclase grains oriented at an angle of around 50° towards σ1. These bands are mostly visible in samples without epidote.

How to cite: Mohrbach, L. K., Renner, J., and Incel, S.: Experimental study of the impact of hydration extent on the strength of the lower continental crust, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7954, https://doi.org/10.5194/egusphere-egu22-7954, 2022.

EGU22-8320 | Presentations | EMRP1.17

The effects of grain size on semi-brittle flow in calcite rich rocks 

Christopher Harbord and Nicolas Brantut

Grain size is in an important microstructural parameter affecting both brittle and plastic deformation processes. In the low temperature brittle regime, larger grain size materials typically have lower strength, whereas in the plastic flow regime smaller grain size materials tend to be weaker. It is not clear how grain size impacts at intermediate conditions where deformation of rock is accommodated by coupled brittle and plastic deformation processes.

To investigate the role of grain size in the semi brittle regime we deformed three calcite-rich rocks, spanning 3 orders of magnitude in grainsize (0.006-2 mm). A gas medium triaxial apparatus was used at a range of confining pressures (200-800 MPa) and temperatures (20-400°C), and samples were loaded at a constant axial strain rate (1×10-5 s-1). Axial measurements of P-wave speed were performed during tests in order to infer the in-situ microstructural state of the sample.

Nearly all tests show strain hardening behaviour after yield, typical of semi-brittle deformation, which is quantified using the hardening modulus (h = ∂σ/∂ε). Grain size has a first order control on rock strength, with yield stress and h following a Hall-Petch type relationship at all P-T conditions. For a given temperature, h is low at low pressure (200 MPa) and accompanied by large decreases in wavespeed, and h increases at high pressure (>400 MPa) whereas velocity decreases by a smaller magnitude. This suggests that, at low temperature, strain hardening is relieved by microcracking. At constant pressure, wavespeed decreases significantly at 20°C with progressive deformation, but remains nearly constant at 400°C indicating a transition from dominatly brittle to fully plastic deformation with increasing temperature, in some cases with little change in the macroscopic strength.

Given that both strength and strain hardening behaviour depend on grain size, our data suggests that grain size dynamically impacts the long term rheology of the crust. Larger grain sizes will broaden the depth distribution of the brittle ductile transition and result in a weaker peak crustal strength.

How to cite: Harbord, C. and Brantut, N.: The effects of grain size on semi-brittle flow in calcite rich rocks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8320, https://doi.org/10.5194/egusphere-egu22-8320, 2022.

EGU22-8365 | Presentations | EMRP1.17

Weakening mechanisms in dry, lower-crustal pseudotachylytes 

Kristina G. Dunkel, Luca Menegon, and Bjørn Jamtveit

Earthquakes are often regarded as agents of rheological weakening of the dry and mechanically strong lower crust. The weakening is typically attributed to fluid infiltration and resulting fluid-mediated metamorphism along the seismic fault.

On Moskenesøya in SW Lofoten (Northern Norway), we observe lower-crustal pseudotachylytes (frozen frictional melts that record fossil earthquakes) that are unusually dry. This presents us with an exceptional opportunity to study the processes affecting the rocks during and after an earthquake:

  • We can observe the pristine microstructures of the pseudotachylytes, not overprinted by later metamorphism, to elucidate the earthquake-generating mechanism.
  • We can study the further development of these dry pseudotachylytes after the seismic event.

We have previously described the composition and microstructures of the pristine pseudotachylytes, and concluded that transient stress pulses caused by shallower earthquakes are the most likely explanation for the occurrence of fossil earthquakes in the analysed rocks from Lofoten, with no evidence of other mechanisms such as thermal runaway or dehydration embrittlement.

In this contribution, we focus on the evolution of the pseudotachylytes after their formation. We study their development from the initial, pristine pseudotachylytes, via pseudotachylytes with slightly mylonitized margins, to ultramylonites. We use compositional and microstructural analyses, including electron backscatter diffraction (EBSD), to understand the weakening mechanisms in this dry system.

In the mylonitized margins of the pseudotachylytes, a slight shape-preferred orientation is developed and the quenching microstructures, such as microlites, are lost. The mineralogical composition (dominantly feldspars and pyroxenes) stays the same as in the pristine pseudotachylytes. In the ultramylonite, quartz and amphibole appear as accessory minerals, which means that we cannot completely exclude the presence of minor amounts of hydrous fluids; however, feldspars and pyroxenes persist as the main components of the rock. The foliation of the ultramylonite is not defined by phyllosilicates, but by a compositional banding, which suggest a phase separation and aggregation during shearing. EBSD data indicate that the main constituent phases deformed dominantly by grain size sensitive creep.

Our preliminary results suggest that even in the absence of fluids, pseudotachylyte-bearing seismic faults represent weak zones in the lower crust that are localizing viscous shear during post- and interseismic deformation, presumably due to the intense grain size reduction that facilitates grain-size sensitive mechanisms. 

How to cite: Dunkel, K. G., Menegon, L., and Jamtveit, B.: Weakening mechanisms in dry, lower-crustal pseudotachylytes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8365, https://doi.org/10.5194/egusphere-egu22-8365, 2022.

EGU22-10023 | Presentations | EMRP1.17

Seismic attenuation across the brittle-ductile transition 

Maria Aurora Natale Castillo, Magdala Tesauro, Mauro Cacace, Francois X. Thibault Passelegue, Lucas Pimienta, and Marie Violay

Rocks mechanical behaviour, and in particular, their transition from a brittle to a ductile deformation has been prevalently investigated through rheological experiments and numerical models. In conjunction with rocks mechanical studies, the analyses of seismic wave propagation can improve our knowledge of physical rocks behaviour and provide an alternative assessment of the brittle ductile transition (BDT).

In this study, we investigate the quantitative relationships between seismic attenuation and viscous rocks' rheology, especially across the BDT domain. For this purpose, we rely on the Burgers and Gassmann mechanical model to derive shear wave attenuation (1/Qs ), for several dry and wet crustal rheology, thermal conditions, and different strain rates values. This allows us to establish geothermal and mechanical conditions at which the BDT occurs and to cross-correlate this transition to computed shear seismic wave attenuation values. We observe that the variation with depth is related much more to the input strain rate than to the rock‘s rheology and thermal conditions, so that a fixed amount of Qs reduction can identify the average BDT depths for each strain rate used. Below the BDT depth, we observe a significant increase of the Qs reduction (up to 10-4 % of the surface value), depending also on rocks temperature and rheology. Since the greatest Qs reduction is estimated for the greatest input strain rate (10-13 s-1) and hot thermal conditions, the proposed method can find more applicability in tectonically active/geothermal areas.

We tested the obtained results by performing triaxial lab experiments, while monitoring ultrasonic P-waves, on a sample of Carrara marble, at ambient temperature and 180 MPa confining pressure. The transition from brittle to semi-brittle conditions is characterized by the increase of crack-density with a progressive rate reduction. At the same time, both the seismic velocity and energy significantly decrease during the first phase of deformation (brittle regime) and tend towards an asymptotic value, when the sample approaches the ductile deformation. We interpret the absence of an increase of energy loss at the BDT, as due to the persistent effect of the microfracturation. The last one usually accompanies the deformation mechanisms that occur at the BDT (e.g., pressure solution, twinning), masking the expected increase of attenuation at the beginning of the ductile conditions. This is a matter that still needs to be investigated.

How to cite: Natale Castillo, M. A., Tesauro, M., Cacace, M., Passelegue, F. X. T., Pimienta, L., and Violay, M.: Seismic attenuation across the brittle-ductile transition, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10023, https://doi.org/10.5194/egusphere-egu22-10023, 2022.

We provide here in situ evidence from a network of well-preserved extensional shear zones cutting a rift related lower crustal Reinfjord Ultramafic Complex, Seiland Igneous Province, that formed in the late Ediacaran. Our results can explain seismic events well below the seimic zone of continental rifts and associated CO2 emissions. Processses leading to catastrophic failure of the weakened rocks led to extremely high strain rates and the formation of pseudotachylites can be traced from a netwok og mm-m scale steeply dipping transtensional shearzones associated with gabbronoritc dykes to a 2km long low angle extensional shearzone. Deformation, initiated through a priming of the dyke-host rock interface by magmatic fluids, exploits subgrains and microfractures in olivine, with reactive CO2-bearing fluids leading to volume expanding reactions such as olivine + diopside + CO2 = Dolomite + enstatite, enhancing olivine grain fracturing. Fragmentation of the olivine grains and addition of weaker phases facilitated strain localization and local increases in strain rate by two orders of magnitude. Catastrophic failure of the weakened rocks led to extremely high strain rates and the formation of pseudotachylites in several cyclic events. The frictional heat raised the temperature above the dolomite forming reaction, causing release of CO2 and H2O along the fault, but also in the surrounding mafic-ultramafic rocks, forming veins around the shearzone. Fluid-rock interaction surrounding shear zones is highly variable and depends on bulk rock compositions. Thermodynamic modelling demonstrates that mineral reactions involving hydration and carbonation differ between dunitic rocks and the pyroxenitic dykes which intersect them. Alteration of dunitic rocks results in the formation of dominantly magnesite-anthophyllite-talc and talc-magnesite assemblages causing approximately 12% volume expansion, resultinig in a sharp reaction front contacts with the host rock. When the alteration zones cross the dunite-pyroxenite boundary the associated alteration has a more gradual boundary towards the unaltered rock and the alteration zone widens by approximately 40%. In contrast to the simpler dunite alteration assemblage, the pyroxenenitic dykes are altered to a complex mixture of cummingtonite-anthophyllite, magnetite and chlorite. Additionally, orthopyroxene is completely pseudomorphed by a mixture of cummingtonite and magnetite, whereas olivine xenocrysts are partly preserved and surrounded by a magnesite-anthophyllite assemblage. Other, open cavity-like areas are filled by chlorite, amphibole, and Mg-MgCa carbonates, indicating volume reduction during alteration of the pyroxene.Accordingly, dunite alteration effectuates a significant volume expansion, and are therefore only altered locally during seismic creep events. The pyroxenites are near volume neutral throughout interaction with the same fluids, and are thus more homogeneously altered. The formation of chlorite in hybrid compositions, such as the dykes in the lower crust, may create weak permeable zones that are consequently exploited as pathways for fertile mantle fluids and will hence also be the locus of ore bearing fluids moving to the upper crust.  We conclude that catastrophic failure along shear zones in lower crustal continental rifts is possible without remote stress events in the presence of pre-existing heterogeneities and volatiles. These zones also acted and transport conduits for volatiles from the lower crust to atmosphere.

How to cite: Sørensen, B. E., Ryan, E. J., Larsen, R., and Grant, T.: Infiltration of volatile-rich mafic melt in lower crustal peridotites provokes deep earthquakes, initiates km scale shearzones and volatile transfer from the lower crust to the atmosphere, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10545, https://doi.org/10.5194/egusphere-egu22-10545, 2022.

EGU22-12465 | Presentations | EMRP1.17

Diopside microfabric development in lower-crust oceanic detachment fault zones 

Rhander Taufner, Claudia Trepmann, and Gustavo Viegas

Exhumation of oceanic core complexes occurs through large-scale extensional shear zones that expose parts of the deformed gabbroic lower crust. However, it is not well understood how these high-temperature shear zones nucleate and develop. Since diopside is traditionally described as a load bearing phase in deforming systems, its microstructures may record the deformation mechanisms involved in the progressive stages of shear zone development. In this study, we focus on the fabrics of diopside in both the host coarse-grained gabbro and the adjacent high-temperature shear zone from the Atlantis Bank (IODP Exp 360), in order to better constrain the role of diopside during strain localization in deep crustal detachment fault zones.

In the host rock directly in contact to the shear zone, diopside porphyroclasts display microfractures filled with fine-grained diopside (~ 65 µm) and minor amounts (~10%) of plagioclase, amphibole and Fe-Ti oxides with grain size ~ 30 µm that occur as interstitial phases. Diopside grains in the microfractures have little internal deformation and are interpreted as “new” grains. On the other hand, fragments of the host diopside within the fracture are distinguished by their larger diameters of ~200 µm and dominant cleavage planes that is systematically missing in the new grains. These microstructures indicate cataclastic deformation with later precipitation of plagioclase, amphibole and Fe-Ti oxides. Other diopside porphyroclasts in the host rock show undulatory extinction, low-angle grain boundaries and new grains with crystallographic orientations controlled by the host, indicating dislocation creep.

Diopside porphyroclasts within the shear zone show undulatory extinction as well as bent cleavage planes and exsolution lamellae. New grains of diopside (~35 µm) that occur rimming the porphyroclasts - concentrated at sites of strong undulatory extinction - have long axes correlating the orientation of the bent cleavages within the host. These new grains have a crystallographic orientation with poles of (100) planes close to the X-axis and [001] axes close to the Z-axis, and high angle boundaries (>140º) with misorientation axes clustered between [001] and [100]. We propose that these new grains are a result of dislocation glide and growth due to bending of the host diopside during the early stages of shear zone nucleation.

In the strain shadow of the porphyroclasts within the shear zone, new grains of diopside (~20µm) occur together with amphibole, plagioclase and Fe-Ti oxides. They are rounded, strain free, have random orientations and the amount of diopside decreases with distance from the host. These grains are interpreted to have precipitated from the pore fluid during ongoing deformation of the shear zone.

We suggest that diopside in the host rock was deformed by cataclasis associated with dislocation glide during nucleation of the shear zone at probably high stress, as indicated by the similar microfabric of diopside porphyroclasts in the shear zone compared to those in the host rock. Unlike, ongoing deformation localized within the shear zone is due to dissolution and precipitation, as indicated by the polyphase aggregates in the strain shadows and in the matrix. 

How to cite: Taufner, R., Trepmann, C., and Viegas, G.: Diopside microfabric development in lower-crust oceanic detachment fault zones, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12465, https://doi.org/10.5194/egusphere-egu22-12465, 2022.

EGU22-13212 | Presentations | EMRP1.17

Experimental deformation of talc at near-seismic deformation rates 

Charis Horn and Philip Skemer

Talc is a hydrous magnesium silicate with an extremely low coefficient of friction.  In recent years, the recognition that talc is present in many fault systems has led to the suggestion that talc strongly influences the strength of faults.  To understand the role of talc in the seismic cycle, we conducted high pressure and temperature torsional deformation experiments on specimens of natural talc at shear strain rates relevant to slow-slip earthquakes (~10-4 s-1).  Scanning transmission electron microscopy revealed decreasing talc grain sizes (from ~3-5 mm to <100 nm), alongside delamination and kinking of individual talc grains.  This microstructural evolution with progressive strain greatly increases the density of planar defects (including grain-boundaries), and is consistent both with observations of natural, talc-rich faults, and prior experimental work.  Nanoindentation tests at room temperature were performed on deformed specimens to assess precisely whether the observed microstructural changes also affect rheology. At these conditions, nanoindentation is assumed to produce deformation predominantly by intercrystalline frictional slip.  However, bulk hardness data determined from nanoindentation show that there is no change in indentation hardness with increasing strain or defect density, both for indents made parallel to and perpendicular to the shear plane.  Although the talc grains become increasingly damaged with strain, the overall strength of deformed talc does not change.  This suggests that accumulated slip on talc-bearing faults does not change their mechanical response or hazard potential.

How to cite: Horn, C. and Skemer, P.: Experimental deformation of talc at near-seismic deformation rates, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13212, https://doi.org/10.5194/egusphere-egu22-13212, 2022.

TS3 – Faults: imaging, kinematics and mechanics

EGU22-617 | Presentations | TS3.1

A Bayesian probabilistic approach to estimate the focal mechanism of micro-earthquakes occurring at the Irpinia fault system, southern Italy. 

Stefania Tarantino, Antonio Emolo, Guido Maria Adinolfi, Gaetano Festa, and Aldo Zollo

We developed a Bayesian technique to infer the double-couple, focal mechanism parameters (strike, dip and slip angles) of an earthquake source. The method uses 3 independent datasets: P-wave peak amplitude and polarity and S-to-P amplitude ratio wherever it is available.

The Bayesian technique works even in absence of one dataset and easily integrates any prior information about the region of study. The parameter space is explored thanks to an octree strategy. The method estimates the Posterior pdf, where the maximum likelihood parameter values (MAP model) both for the principal and auxiliary plane are chosen as the final fault mechanism solution. Furtherly, the uncertainties as the projections of the semi-axis of the 68% confidence ellipsoid centred on the MAP model are provided.

The joint use of the three datasets allows to determine a solution even in the case of a limited number of stations that have recorded the event, which is the case for example for small magnitude earthquakes (M<3).

We applied and tested the methodology to a microearthquake sequence (ML 0.4-3.0) occurred in the Irpinia region, South Italy, using an uninformative prior distribution for the parameters. In this area, the background seismicity occurs in a volume delimited by the faults activated during the 1980 Irpinia M 6.9 earthquake. This faults system is complex and composed of northwest–southeast striking normal faults along the Apennines chain. A network of 3-component accelerometers and velocimeters is currently monitoring the area (Irpinia Seismic NETwork).

We inferred the focal mechanism of the earthquakes of the sequence. Our results show fault mechanism solutions which are consistent with previous studies, well reflecting the regional stress field. The focus on micro-seismicity can reveal characteristics useful to highlight behaviours of larger scale seismicity.

How to cite: Tarantino, S., Emolo, A., Adinolfi, G. M., Festa, G., and Zollo, A.: A Bayesian probabilistic approach to estimate the focal mechanism of micro-earthquakes occurring at the Irpinia fault system, southern Italy., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-617, https://doi.org/10.5194/egusphere-egu22-617, 2022.

EGU22-991 | Presentations | TS3.1

High-resolution reflection seismic imaging of fault systems in Metropolitan Seoul, South Korea 

Samuel Zappalá, Alireza Malehmir, Tae-Kyung Hong, Junhyung Lee, Bojan Brodic, Dongchan Chung, Christopher Juhlin, Byeongwoo Kim, Myrto Papadopoulou, Seongjun Park, Jeongin Lee, and Dongwoo Kil

The Korean peninsula is considered a stable intraplate setting with few large magnitude earthquakes and in terms of seismic risk, a low-risk region. However, the peninsula is crosscut by crustal-scale fault systems, some of which may be active or have a potential of reactivation. After the Tohoku-Oki earthquake (Mw 9.0, 2011) offshore Japan, subsequent larger magnitude seismic events were registered along some of the fault systems in the South Korean portion of the peninsula. Following these, seismic risk in the area has been given more attention with several initiatives to study the current state of the seismicity in the region and to better understand the geometry and role of these crustal-scale fault systems.

To provide information on the geometry of subsurface structures causing the seismic events, a number of locations were identified for high-resolution reflection seismic imaging. In November 2020, the first active-source seismic profiles in the region (P1 and P2) were acquired with a total length of approximately 14 km with the aim to better understand the correlation between one of the main faults, the Chugaryeong fault system, and the seismicity in the area. A novel data acquisition survey consisting of a 120-unit micro-electromechanical sensors (MEMS-based) seismic landstreamer and 290 wireless recorders was employed to allow both near-surface and deep imaging of structures. Profile P1, 5 km long, was acquired on the outskirt of Seoul and P2, 9 km long, was acquired in the central part of the city. Acquiring P2 was a significant challenge given that the Seoul metropolitan area is densely populated. Difficulty to obtain good geophone-ground coupling and anthropogenic noise severely degraded the data quality. Nonetheless, final seismic sections from both profiles show encouraging results, particularly along P1 where much deeper imaging was possible (up to 9 km depth). An integrated processing work flow was required to take advantage of both the landstreamer and wireless data and this proved to be instrumental for improved imaging and subsequent interpretation.

Along P1 a clear correlation between seismic event clusters and reflection intersections (at two depth intervals of 4.5-5 km and 8-9 km) is observed, suggesting that seismic triggering is coupled to the fault intersections at depth. P2 shows strong westerly-dipping reflections with similar characteristics to the ones seen along P1, but only visible from the near surface to around 1200 m depth. It was not possible to map these faults deeper along P2, probably due to the noise conditions, thus no correlation between fault intersections and seismicity could be made. The encouraging reflection seismic results from both profiles, motivated the acquisition of a much longer profile (P3, 40 km) crossing three major fault systems in 2021. It lies in between P1 and P2 and a similar acquisition strategy was used as before. Preliminary results are ready and these are currently being interpreted together with other seismological and geological information from the area.

How to cite: Zappalá, S., Malehmir, A., Hong, T.-K., Lee, J., Brodic, B., Chung, D., Juhlin, C., Kim, B., Papadopoulou, M., Park, S., Lee, J., and Kil, D.: High-resolution reflection seismic imaging of fault systems in Metropolitan Seoul, South Korea, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-991, https://doi.org/10.5194/egusphere-egu22-991, 2022.

EGU22-1403 | Presentations | TS3.1

Seismic anisotropy structure of the northern Hikurangi margin, New Zealand, and its significance for subduction fault systems 

Ryuta Arai, Shuichi Kodaira, Stuart Henrys, Nathan Bangs, Koichiro Obana, Gou Fujie, Seiichi Miura, Daniel Barker, Dan Bassett, Rebecca Bell, Kimihiro Mochizuki, Richard Kellett, Valerie Stucker, and Bill Fry

The NZ3D OBS experiment performed in 2017-2018 in the northern Hikurangi margin off the east coast of North Island, New Zealand, provided the highest-resolution seismic refraction/wide‐angle reflection data with multi-azimuth ray coverage in subduction zones to date (Arai et al., 2020). The study area extending 60 km in the trench-normal direction and 14 km in the trench-parallel direction covers source regions of a variety of slow earthquake phenomena, such as shallow slow slip events and tectonic tremor (e.g., Wallace, 2020), and thus offers an ideal location to link our understanding of structural and hydrogeologic properties at subduction faults to slip behavior. We applied an anisotropic traveltime tomography analysis to this active-source dataset from 97 ocean bottom seismographs deployed with an average spacing of 2 km on four parallel lines and dense air gun shooting with a 25 m interval, and succeeded in quantitatively constraining the P-wave velocities (Vp) of the upper plate forearc and the subducting slab and their azimuthal anisotropy in three dimensions. The velocity models revealed some locations with significant Vp azimuthal anisotropy over 5 % near the splay faults in the low-velocity accretionary wedge and the deformation front. This finding suggests that the anisotropy is not ubiquitous and homogeneous within the upper plate, but more localized in the vicinity of active thrust faults. While the fast axes of Vp are mostly oriented in the trench-normal direction in the accretionary wedge, which is interpreted as results of preferentially oriented cracks in a compressional stress regime associated with the plate convergence, they are rotated to the trench-parallel direction on the seaward side of the trench and in the landward backstop. This regional variation is consistent with the results of shear-wave splitting analysis (Zal et al., 2020) and the directions of maximum horizontal stress inferred from the borehole breakouts at two IODP drilling sites (Wallace et al., 2019). The significant magnitudes of anisotropy may indicate that in addition to the crack orientation, clay-rich sedimentary sequences that stack and form coherent strata along the accretionary wedge also contribute to seismic anisotropy in the subduction margin.

 

How to cite: Arai, R., Kodaira, S., Henrys, S., Bangs, N., Obana, K., Fujie, G., Miura, S., Barker, D., Bassett, D., Bell, R., Mochizuki, K., Kellett, R., Stucker, V., and Fry, B.: Seismic anisotropy structure of the northern Hikurangi margin, New Zealand, and its significance for subduction fault systems, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1403, https://doi.org/10.5194/egusphere-egu22-1403, 2022.

EGU22-1926 | Presentations | TS3.1

Geological imaging of a crustal-scale seismogenic source in the continental crust (Bolfin Fault Zone, Atacama Fault System, Chile) 

Simone Masoch, Michele Fondriest, Rodrigo Gomila, Erik Jensen, Giulia Magnarini, Javier Espinosa, Karin Hofer, Tom Mitchell, José Cembrano, Giorgio Pennacchioni, and Giulio Di Toro

Fault zone architecture controls, for instance, the nucleation, propagation and arrest of individual seismic ruptures, the moment magnitude of the mainshocks and the evolution in space and time of foreshock and aftershock seismic sequences. Nevertheless, the architecture of crustal-scale seismogenic sources is still poorly known. Here, we examine the architecture of the >40-km-long, Mesozoic seismogenic Bolfin Fault Zone (BFZ) of the Atacama Fault System (Northern Chile). The exceptionally well-exposed BFZ cuts through plutonic rocks of the Coastal Cordillera and was seismically active at 5-7 km depth and ≤ 300 °C in a fluid-rich environment. The BFZ includes multiple fault core strands consisting of chlorite-rich cataclasites-ultracataclasites and pseudotachylytes, surrounded by chlorite-rich protobreccias to protocataclasites over a zone as wide as 75 m. These cataclastic units are associated with a damage zone, up to 150-m-thick, which comprises strongly altered and brecciated rock volumes, and with clusters of epidote-rich fault-vein networks located at the linkage of the BFZ with other faults. The architecture of the BFZ is the result of fault core widening by cyclic co-seismic frictional melting and post-to-inter-seismic fault healing due to hydrothermal (chlorite + epidote ± K-feldspar) mineral precipitation plus pervasive, possibly associated with mainshocks and aftershocks, damaging of the surrounding rocks. Additionally, we interpret the epidote-rich fault-vein networks as an exhumed seismic source of fluid-driven earthquake swarm-type sequences in agreement with seismological observations of presently active magmatic and hydrothermal regions. 

How to cite: Masoch, S., Fondriest, M., Gomila, R., Jensen, E., Magnarini, G., Espinosa, J., Hofer, K., Mitchell, T., Cembrano, J., Pennacchioni, G., and Di Toro, G.: Geological imaging of a crustal-scale seismogenic source in the continental crust (Bolfin Fault Zone, Atacama Fault System, Chile), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1926, https://doi.org/10.5194/egusphere-egu22-1926, 2022.

EGU22-2202 | Presentations | TS3.1

Unraveling the complexity of the Pollino (Italy) seismic gap fault system. 

Ferdinando Napolitano, Ortensia Amoroso, Mario La Rocca, Luca De Siena, Danilo Galluzzo, Vincenzo Convertito, Raffaella De Matteis, Toshiko Terakawa, and Paolo Capuano

The Mt. Pollino area has been affected by a 4-year long seismic sequence, occurred between 2010 and 2014 and characterized by low-to-moderate seismicity and two moderate events (ML 4.3 and ML 5.0). The sequence developed as a combination of swarm-like and aftershocks. The two main earthquakes occurred late in the sequence, with a slow-slip event starting 3-4 months before the largest earthquake and lasting for a year. Despite the lack of historical and instrumental recordings of strong earthquakes (M>6), paleo-seismological investigations confirm the occurrence in the last 10,000 years of at least two M 6.5-7 earthquakes on the Pollino and Castrovillari faults, located in the SE sector of the Mt. Pollino area. Thus, the area has been marked as the widest high seismic hazard gap in Italy.

In this study we present the most recent advancements in the comprehension of the main peculiarities of the last seismic sequence and of its space and time evolution.   

New local 3D P- and S-wave tomographic images offered a detailed picture of the main lithological units involved in the sequence and more reliable earthquake hypocenter locations. The inferred velocity contrasts have been compared with 2D scattering and absorption maps computed for the area, along with total direct wave attenuation. Clusters of events of similar waveforms (cross-correlation higher than 0.8) have been selected and located applying the master-slave relative location technique. New fault mechanisms have been computed. These mechanisms allowed modeling the local stress field and performing a Focal Mechanism Tomography. Its result was an evaluation of the excess of pore fluid pressure in the volume interested by the sequence. A 1D diffusivity analysis suggests a pore fluid pressure diffusion which, in addition to the Coulomb static stress transfer, can explain the delayed triggering of the two larger events.

This work has been supported by the CORE (“sCience and human factor for Resilient sociEty”) project, funded from the European Union’s Horizon 2020 - research and innovation program under grant agreement No 101021746 and by PRIN-MATISSE (20177EPPN2) project funded by Italian Ministry of Education and Research.

How to cite: Napolitano, F., Amoroso, O., La Rocca, M., De Siena, L., Galluzzo, D., Convertito, V., De Matteis, R., Terakawa, T., and Capuano, P.: Unraveling the complexity of the Pollino (Italy) seismic gap fault system., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2202, https://doi.org/10.5194/egusphere-egu22-2202, 2022.

EGU22-2940 | Presentations | TS3.1

Constraints on Fracture Distribution in Geothermal Fields Using Seismic Noise Beamforming 

Heather Kennedy, Amy Gilligan, and Katrin Löer

Faults and fractures are crucial parameters for geothermal systems as they provide secondary permeability allowing fluids to circulate and heat up in the subsurface. In this study, we use an ambient seismic noise technique referred to as the three-component (3C) beamforming to detect and monitor faults and fractures at a geothermal field in Mexico.

Three-component (3C) beamforming extracts the polarizations, azimuths, and phase velocities of coherent waves as a function of frequency, providing a detailed characterisation of the seismic wavefield. In this study, 3C beamforming of ambient seismic noise is used to determine surface wave velocities as a function of depth and propagation direction. Anisotropic velocities are assumed to relate to the presence of faults giving an indication of the maximum depth of permeability, a vital parameter for fluid circulation and heat flow throughout a geothermal field.

We perform 3C beamforming on ambient noise data collected at the Los Humeros Geothermal Field (LHGF) in Mexico. The LHGF is situated in a complicated geological area, being part of a volcanic complex with an active tectonic fault system. Although the LHGF has been exploited for geothermal resources for over three decades, the field has yet to be explored at depths greater than 3 km. Thus, it is currently unknown how deep faults and fractures permeate and the LHGF has yet to be exploited to its full capacity.

3C beamforming was used to determine if the complex surface fracture system permeates deeper than is currently known. Our results show that anisotropy of seismic velocities does not decline significantly with depth, suggesting that faults and fractures, and hence permeability, persist below 3 km. Moreover, estimates of fast and slow directions, with respect to surface wave velocities, indicate the orientation of faults with increasing depth. The North-East and North-West orientation of the fast direction corresponds to the orientation of the Arroyo Grande and Los Humeros faults respectively. Various other orientations of anisotropy align with other major faults within the LHGF at depths permeating to 6 km.

How to cite: Kennedy, H., Gilligan, A., and Löer, K.: Constraints on Fracture Distribution in Geothermal Fields Using Seismic Noise Beamforming, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2940, https://doi.org/10.5194/egusphere-egu22-2940, 2022.

EGU22-4047 | Presentations | TS3.1

Complex fault growth controls 3-D rift geometry: Insights from deep learning of seismic reflection data from the entire northern North Sea rift 

Thilo Wrona, Indranil Pan, Rebecca Bell, Christopher Jackson, Robert Gawthorpe, Haakon Fossen, and Sascha Brune

Understanding how normal faults grow is critical to an accurate assessment of seismic hazards, for successful exploration of natural (including low-carbon) resources and for safe subsurface carbon storage. Our current knowledge of fault growth is, in large parts, derived from seismic reflection data of continental rifts and margins. These seismic datasets do however suffer from limited data coverage and resolution. In addition, detailed fault mapping in increasingly large seismic reflection data requires a large amount of expertise and time from interpreters. Here we map faults across the entire northern North Sea rift using a combination of supervised deep learning and broadband 3-D seismic reflection data. This approach requires us to interpret <0.1% of the data for training and allows us to extract almost 8000 individual normal faults across a 161 km wide (E-W), 266 km long (N-S) and 20 km deep volume. We find that rift faults form incredibly complex networks revealing a previously-unrecognised variability in terms of fault length, density and strike. For instance, while we observe up to 75.9 km long faults extending from the Stord Basin and Bjørgvin Arch in the south into the Uer and Lomre Terrace to the north, most faults (>90%) are closely spaced (< 5 km) and relatively short (<10 km long). Moreover, these faults show a large range of strikes varying from NW-SE to NE-SW with two dominant fault strikes (NE-SW & NW-SE) almost perpendicular to each other. This observation is difficult to reconcile with previous studies on the extension directions during rifting of the northern North Sea. While previous studies suggest that pre-existing shear zones control faulting in the northern North Sea, we only observe faults aligning with the southern parts of the Lomre shear zone and the eastern parts of the Ninian shear zones, but none of the other eight previously mapped shear zones. Instead we think that these variations in fault strike could occur naturally through the complex evolution of fault networks. As such our innovative approach allows us to map faults across the entire northern North Sea revealing complex networks, which challenge many conventional views of fault growth during continental rifting.

How to cite: Wrona, T., Pan, I., Bell, R., Jackson, C., Gawthorpe, R., Fossen, H., and Brune, S.: Complex fault growth controls 3-D rift geometry: Insights from deep learning of seismic reflection data from the entire northern North Sea rift, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4047, https://doi.org/10.5194/egusphere-egu22-4047, 2022.

EGU22-4446 | Presentations | TS3.1

2-D Sn attenuation tomography of Arunachal Himalaya 

Sukanta Sarkar, Chandrani Singh, M. Ravi Kumar, Ashwani Kant Tiwari, Arun Kumar Dubey, and Arun Singh

In this study, we have presented the first high-resolution 2-D Sn attenuation tomography image of
Arunachal Himalaya to enlighten the lithospheric structure of the area. The region is one of the
active segments of the Himalaya and least understood because of the inaccessibility and difficult
working conditions. 37 regional earthquakes within the epicentral distance of 250 - 1650 km were
recorded by 29 broadband seismic stations operated in Arunachal Himalaya covering the majority
portions of the eastern Himalaya are used in the present study.
Sn is the uppermost mantle refracted phase travelled with a velocity of 4.3 - 4.7 km/s. It
is highly sensitive to the velocity gradient and attenuation in the uppermost mantle. We have
categorised the propagation efficiencies of Sn as efficient, inefficient and blocked based on a
visual inspection. The inefficient and blocked Sn phases are observed mainly in the western side
of our study region. Further, we have obtained the Sn Q tomography model to examine lateral
variations in attenuation characteristics, employing the Two Station Method (TSM) using 567 station
pairs as input data. The central Arunachal Himalaya exhibits a low Q value (≤ 50) whereas
Tawang and the western part of Arunachal Himalaya show a high value of Q ≤ 300. The obtained
results are well correlated with the tectonic fabric of the area.

How to cite: Sarkar, S., Singh, C., Kumar, M. R., Tiwari, A. K., Dubey, A. K., and Singh, A.: 2-D Sn attenuation tomography of Arunachal Himalaya, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4446, https://doi.org/10.5194/egusphere-egu22-4446, 2022.

EGU22-6589 | Presentations | TS3.1

Early results from 3D full-waveform inversion imaging of the slow slip region at the shallow Hikurangi Subduction Margin 

Richard Davy, Laura Frahm, Rebecca Bell, Joanna Morgan, Ryuta Arai, Nathan Bangs, Stuart Henrys, and Daniel Barker

The northern Hikurangi subduction margin hosts shallow slow-slip events (SSEs) and multiple historic tsunami earthquakes. The physical mechanisms and properties of the subduction interface which enable these dual modes of fault rupture remain largely enigmatic. In 2017-2018, the NZ3D seismic experiment was conducted offshore of Gisborne to image the structure of the overriding plate and subduction interface and infer the physical properties within the region of shallow SSEs. This experiment included a 3D seismic volume collected with four 6 km long streamers, ocean-bottom seismometers, and land stations. Early results from this project have demonstrated the successful application of 2D full-waveform inversion (FWI) to high frequencies along selected seismic inlines.

Here, we present the initial results of acoustic 3D FWI on the collected streamer data. Compared with 2D FWI, 3D FWI benefits from greater azimuthal coverage and the ability to relocate out-of-plane arrivals accurately but is restricted by increased calculation times and file sizes. Velocity models reveal a complex system of thrust faulting, horst and graben structures and bottom-simulating reflectors within the accretionary prism, as well as the decollement below the accretionary prism. Velocity inversions across the imaged thrust faults in the accretionary prism indicate the presence of fluids, potentially supporting the hypothesis that the subduction interface has elevated pore-fluid pressures, which are drained along some thrust faults. Velocity inversions are also observed across bottom-simulating reflectors, which indicate the presence of gas hydrates and free gas. Imaging the shallow decollement reveals an acoustically transparent region of low velocity contrasts in the inferred location of a subducted seamount.

How to cite: Davy, R., Frahm, L., Bell, R., Morgan, J., Arai, R., Bangs, N., Henrys, S., and Barker, D.: Early results from 3D full-waveform inversion imaging of the slow slip region at the shallow Hikurangi Subduction Margin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6589, https://doi.org/10.5194/egusphere-egu22-6589, 2022.

EGU22-7059 | Presentations | TS3.1

A Monte Carlo-Based Approach to Image Active 3D Fault Systems from Relocated Hypocenters 

Sandro Truttmann, Tobias Diehl, and Marco Herwegh

Despite the generally accepted concept that most earthquakes occur along pre-existing faults, the complex 3D geometries of seismically active fault systems at depth often remain unresolved. However, earthquake nucleation and migration processes are heavily influenced by the geometries and properties of such pre-existing structures, which limits our general understanding of earthquake nucleation and fault interactions.

Under the assumption that faults are reactivated at spatially and temporally different localities, previous studies have attempted to derive fault geometries from hypocenter locations, but were usually limited by the precision of relocation techniques. Enabled by the recent advances in hypocenter relocation techniques, we present a novel Monte Carlo-based method that uses relatively relocated hypocenters and their uncertainties to image geometries, stress states and kinematics of seismically active fault systems. The application of the developed Python toolbox on a natural earthquake sequence along the Rhone-Simplon fault zone in the northern Valais (Swiss Alps) reveals active strike-slip faults with a contractional stepover. Performed stress analyses indicate varying stress states along the fault system, which has direct implications for fault properties such as the reactivation potential or the fluid transmissivity. Overall, we document the migration of an earthquake swarm across a complex strike-slip fault system at an unprecedented spatiotemporal resolution.

Our toolbox can be applied to high-precision hypocenter catalogs of natural earthquake sequences or hydraulic stimulation experiments, which could help to improve our understanding of the role of pre-existing faults on earthquake nucleation and migration processes at various scales.

How to cite: Truttmann, S., Diehl, T., and Herwegh, M.: A Monte Carlo-Based Approach to Image Active 3D Fault Systems from Relocated Hypocenters, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7059, https://doi.org/10.5194/egusphere-egu22-7059, 2022.

EGU22-7998 | Presentations | TS3.1

3D Scattering and Absorption model during the 2016-2017 Central Italy Seismic Sequence 

Simona Gabrielli, Aybige Akinci, Ferdinando Napolitano, Edoardo Del Pezzo, and Luca De Siena

The Amatrice-Visso-Norcia seismic sequence struck the Central Apennine (Italy) in 2016. Previous works brought to light how fluid movements likely triggered the sequence and reduced the stability of the normal fault network following the first earthquake (Amatrice, Mw6.0), and the subsequent events of Visso (Mw5.9) and Norcia (Mw6.5) mainshocks.
Seismic attenuation has the potential to visualize fluids presence and fractures in a seismic sequence and to image the effect of fluid migration in the events nucleation.

This work aims to provide 3D images of scattering and absorption at different frequency bands for two datasets, one before the sequence (March 2013-August 2016) and a second from the Amatrice-Visso-Norcia sequence (August 2016-January 2017). To measure scattering and absorption we used peak delay mapping and coda-attenuation tomography, respectively.
Previous 2D imaging of scattering and absorption showed a difference between the pre-sequence and the singular sequences at different frequency bands. Structural discontinuities and lithology control scattering losses at all frequencies, while a single high-absorption anomaly developed NNW-SSE across the seismogenic zone during the seismic sequence, probably related to the migration of deep-CO2 fluids from a deep source of trapped CO2 near the Amatrice earth.
The 3D preliminary results are in agreement with the 2D mapping, with high-scattering anomalies following the main structural and lithological elements of the Central Apennines (e.g. Monti Sibillini thrust), both during the pre-sequence and the sequence, also in depth. As for the 2D, the high absorption anomaly is widespread in the area before the Amatrice event, while it is mainly focused on the seismogenic zone during the sequence. This spatial expansion can be related to the deep migration of CO2-bearing fluids across the fault network also at seismogenic depths.

How to cite: Gabrielli, S., Akinci, A., Napolitano, F., Del Pezzo, E., and De Siena, L.: 3D Scattering and Absorption model during the 2016-2017 Central Italy Seismic Sequence, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7998, https://doi.org/10.5194/egusphere-egu22-7998, 2022.

Ongoing under-thrusting between Indian and Eurasian plate poses a serious concern to millions of human lives residing in the foreland Himalayan. A devastating earthquake in the Central Seismic Gap (CSG) is anticipated in various studies with a possible estimated slip of ~10 m, thereby a thorough analysis of the foreland set up is essential. Present study aims the Kumaon Himalaya of the CSG using the high-resolution seismic sections along profiles PGR4, PGR5 and PGR6. Profiles PGR4 and PGR5 trend N-S direction across the Kaladungi Fault (KF) and Himalayan Frontal Thrust (HFT), whereas the PGR6 trends E-W in the Indo-Gangetic plain. Here we mostly observe Siwalik formation and alluvial deposits of the Dabka and Baur rivers. PGR4 and PGR5 clearly show evidence of south verging faults that displace the Siwalik formation. We observe Upper, Middle and Lower Siwalik rocks at ~0.82 and 0.62 s, ~1.38 and 1.27s, and ~1.88 and 1.85 s TWTT in the footwall and hanging wall sides of KF, respectively. Sedimentary deposits near the KF is highly fractured and host multiple traces of the Fault among which two reach to the surface inferring these are active. We further observe highly folded top sediments with evidence of fault bend folding at North of the KF. In the Indo-Gangetic plain, we observe gentle folding in the Lower Siwalik deposits and trace of a south verging fault that meets the Main Himalayan Thrust (MHT) at ~3 s TWTT displacing the Lower Siwalik deposits by ~ 0.0368 s TWTT. Evidence of such folding and displacements in the formation reveal that foreland Himalaya is conducive to rupture propagation of any major earthquakes developed along MHT over the CSG.

How to cite: Verma, S. and Ghosal, D.: Shallow crustal architecture of the foreland Kumaon Himalaya analysing high-resolution seismic data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9287, https://doi.org/10.5194/egusphere-egu22-9287, 2022.

EGU22-9588 | Presentations | TS3.1

Seismic attenuation tomography in the Carpathian-Pannonian region from ambient seismic noise analysis 

Felix Borleanu, Laura Petrescu, Fabrizio Magrini, Anica Otilia Placinta, Bogdan Grecu, Mircea Radulian, and Luca De Siena

The Carpathian-Pannonian region (CPR) is one of the geotectonically most exciting areas of Europe due to a diversity of tectonic processes activating in close proximity: extensional basin evolution, oceanic subduction, post-collisional volcanism, as well as active crustal deformation associated with the push of the Adria plate or the pull of the actively detaching Vrancea slab. This makes CPR an excellent natural laboratory to study the behavior of the lithosphere-asthenosphere system in a special tectonic setting. To emphasize the lateral heterogeneity and physical properties of the crust in the CPR we investigate noise data recorded by the vertical components of broadband stations that have been operational in 2007, 2009, 2010, 2011 and 2020 in Eastern Europe, kindly provided by the Romanian Seismic Network and EIDA-European Integrated Data Archive. With the advent of this large amount of data and by applying a new processing method of ambient seismic noise field based on the continuous wavelet transform, we computed cross-correlations between various station pairs to transform every available seismic station into a virtual source. The inter-station cross-correlograms were used to determine the coda quality factors (Qc) in three different period ranges (2.5–5 s, 5–10 s and 10–20 s) and invert them using a modified version of the open-access code MURAT2D to construct the highest resolution attenuation tomography of the region. By mapping the attenuation features, within the study region, our results reveal high attenuation features throughout the Bohemian Massif, Alcapa unit, and Vrancea area, as well as a strong difference in attenuation between the Pannonian Basin, and stable platform regions located in front of the Carpathians. In addition, Qc variations are larger at short period in agreement with the strong heterogeneities in the uppermost crust. Finally, our findings demonstrate that noise correlation approaches are more efficient in analyzing Qc at lower frequencies than those previously proposed for earthquake data analyses.

How to cite: Borleanu, F., Petrescu, L., Magrini, F., Placinta, A. O., Grecu, B., Radulian, M., and De Siena, L.: Seismic attenuation tomography in the Carpathian-Pannonian region from ambient seismic noise analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9588, https://doi.org/10.5194/egusphere-egu22-9588, 2022.

EGU22-10564 | Presentations | TS3.1

Decade-long monitoring of seismic velocity changes at the Irpinia Fault System (southern Italy) 

Guido Russo, Grazia De Landro, Ortensia Amoroso, Nicola D'Agostino, Raffaella Esposito, Antonio Emolo, and Aldo Zollo

Repeated tomographic inversions in time (the so called 4D tomography) track physical properties and stress changes in the medium hosting fault systems by measuring changes in P and S seismic velocities. These changes may provide insights on fault system dynamics and earthquake triggering mechanisms. We applied 4D tomography to the volume embedding the Irpinia Fault System (IFS, southern Italy) using more than ten years of continuous seismicity monitoring. The IFS is one of the Italian most hazardous fault systems, being able to generate the 1980 Ms 6.9 earthquake, characterized by a multi-segmented rupture. Seismicity was divided into uneven epochs having almost the same spatial resolution of the volume hosting the IFS.

The resulting images show time-invariant features, clearly related to crustal lithology, and time-changing (up to 20%) velocity anomalies in the central region. Vp, Vs and Vp/Vs anomalies are referred to the tomographic model obtained using all the data set, and occur at depths ranging between 1 and 5 km, and between 8 and 12 km. These anomalies are temporally well-correlated with groundwater recharge/discharge series and geodetic displacements during the same time intervals. This correlation provides evidence for the existence of pulsating pore pressure changes in a fractured crustal volume at depth of 8-12 km, saturated with a predominant gas phase (likely CO2) and correlated with groundwater recharge processes,  

We suggest that tomographic measurements of the Vp-to-Vs spatiotemporal changes are a suitable proxy to track the pore pressure evolution at depth in highly sensitive regions of fault systems.

How to cite: Russo, G., De Landro, G., Amoroso, O., D'Agostino, N., Esposito, R., Emolo, A., and Zollo, A.: Decade-long monitoring of seismic velocity changes at the Irpinia Fault System (southern Italy), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10564, https://doi.org/10.5194/egusphere-egu22-10564, 2022.

EGU22-1624 | Presentations | ERE5.3

Hydraulic fracture interactions with mineral grains 

Keita Yoshioka, Masafumi Katou, Kohei Tamura, Yutaro Arima, Yoshiharu Ito, Youqing Chen, and Tsuyoshi Ishida

Hydraulic fractures often turn or branch, interacting with pre-existing discontinuities (e.g. natural fracture, grain boundary). Such fracture complexities, especially in the proximity of borehole, impact the subsequent well conductivity. When a fracture finds a discontinuity, it either penetrates or deflects depending supposedly on the in-situ stress and the discontinuity geometry. However, our hydraulic fracture experiments on carbonates show that the fractures deflected more frequently at a grain boundary as they propagated farther away from the borehole. In other words, the fracture complexity consistently increases with the propagation distance. In this study, using energy release rate analyses, we show that the energy dissipation of a penetrating fracture increases with the distance away from the borehole. This means, the farther away the hydraulic fracture propagates, the more easily it deflects at a grain boundary from the energetic point of view. This tendency was also confirmed by numerical hydraulic fracture simulations based on a successive energy minimization approach. Our findings challenge the conventional hydraulic fracture penetration/deflection criteria based only on the in-situ stress and the discontinuity geometry. 

How to cite: Yoshioka, K., Katou, M., Tamura, K., Arima, Y., Ito, Y., Chen, Y., and Ishida, T.: Hydraulic fracture interactions with mineral grains, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1624, https://doi.org/10.5194/egusphere-egu22-1624, 2022.

EGU22-2089 | Presentations | ERE5.3

Anisotropic fault permeability upscaling and modeling of fault CO2 migration scenarios during geologic carbon sequestration 

Lluís Saló-Salgado, Steve Davis, and Ruben Juanes

Accurate assessment of fault-related CO2 migration hazard is required to deploy geologic carbon storage at the gigaton scale. First, we present a novel methodology, PREDICT, to model the intrinsic permeability of faults in siliciclastic sequences. PREDICT models realizations of the fault core consistent with the stratigraphy, and computes the probability distributions for the directional components (dip-normal, strike-parallel and dip-parallel) of the fault-scale permeability tensor. PREDICT accounts for uncertainty in the geologic variables influencing fault permeability and was developed for scenario building and risk management.

Second, we show how to leverage PREDICT to build geologically-realistic fault leakage scenarios using a model of the Miocene offshore Texas, Gulf of Mexico. The process includes selection of anisotropic, upscaled fault permeability values from PREDICT’s output, upscaling of multiphase-flow fault properties (relative permeability and capillary pressure), and CO2-brine numerical simulation for hundreds of years. CO2 migration through the fault and into overlying units is tracked in each scenario, and results are compared with SGR-based fault property modeling.

How to cite: Saló-Salgado, L., Davis, S., and Juanes, R.: Anisotropic fault permeability upscaling and modeling of fault CO2 migration scenarios during geologic carbon sequestration, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2089, https://doi.org/10.5194/egusphere-egu22-2089, 2022.

Temperature estimation in hydrothermal reservoirs is a critical point for the feasibility of geothermal projects and subsequent processes, such as chemical and biological activity as well as thermal stresses. As flowing fluid and surrounding host rock locally diverge in temperature until equilibrium occurs, heat transfer between phases needs to be described. However, this is a challenging task, especially in fractures, because the heat transfer coefficient depends on various parameters, such as flow velocity and aperture. Heat transfer characteristics in fracture networks, and their dependence on fracture network characteristics, have been rarely studied so far.

Starting from a newly developed analytical solution of heat transfer in single fractures, a consistent formulation for heat transfer in fractured reservoirs is presented. Using an intermediate step of bench-scale experiments, the sensitivity of the temperature field in the fracture network with respect to the heat transfer coefficient is investigated. Due to multiple flow paths within a reservoir, the heat transfer capabilities of individual fractures can become less relevant in well-connected reservoirs. On the other hand, single fractures with uncommon velocity or aperture values can cause local heterogeneities in the temperature field due to the velocity-dependent heat transfer.

Bridging the gap between well-defined networks with a limited number of fractures and large-scale fracture networks of arbitrary shape requires a change in the parameters used. On large scale, effective values such as fracture density and anisotropic permeability are more suitable and accessible than single fracture apertures. To incorporate such a change in parameterization, a new theoretical framework based on the assumption of fracture networks with a regular geometry is presented.

The presented work sheds new light on the heat transfer mechanisms in fractures and fracture networks and is the first attempt to derive a consistent mathematical framework for heat transfer in fractures across scales.

How to cite: Heinze, T.: Heat transfer across scales: from single fractures to fracture networks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2163, https://doi.org/10.5194/egusphere-egu22-2163, 2022.

EGU22-3960 | Presentations | ERE5.3

Pore-scale modeling of acid etching in a carbonate fracture 

Renchao Lu, Xing-Yuan Miao, Olaf Kolditz, and Haibing Shao

Acid fracturing has been widely used in the oil and gas industry to increase permeability in carbonate reservoirs. In recent years this chemical stimulation technique has been borrowed from the oil and gas industry, employed in the enhanced geothermal systems at Groß Schönebeck, Germany (Zimmermann et al., 2010), and at Soultz-sous-Forêts, France (Portier et. al., 2009). In concept, acid fracturing utilizes strong acids that react with acid-soluble rock matrix in order to non-uniformly etch fracture surfaces. The permeability-enhancing effect depends upon the degree of surface irregularity after pore-scale acidizing which is affected by the compositional heterogeneity of the reacting rock matrix, fracture aperture heterogeneity, and flow and transport heterogeneity. In order to have an insight into these impacts on the acid etching process with the final goal of determining optimum operating conditions (e.g., acid type and acid injection rate), a pore-scale acid-fracturing model is needed. The core components of the pore-scale acid-fracturing model consist in tracking the motion of the fluid-matrix boundary surface induced by acid etching. To date, a number of front tracking approaches (e.g., local remeshing technique, embedded boundary method, immersed boundary method, and level-set method) have been proposed by many researchers in order for moving boundary problems. Each approach has its pros and cons. In this work, we propose employing the phase-field approach as an alternative to the existing front tracking approaches to capture the physically sharp concentration discontinuities across the liquid-solid interface. The developed pore-scale acid-fracturing model includes the Stokes-Brinkmann equations for fluid flow in the fracture-matrix system, the multi-component reactive transport equation for transport of solute species in the rough-walled fracture, and the phase-field equation for the reaction-driven motion of the fluid-matrix boundary surface. Through this numerical study, we demonstrate that the phase-field approach is viable to track recession of carbonate fracture surface by acid etching and to capture the solute concentration jump (w.r.t., Ca2+, H+, and HCO3) across the solid-liquid interface.

 

Reference

Zimmermann, G., Moeck, I. and Blöcher, G., 2010. Cyclic waterfrac stimulation to develop an enhanced geothermal system (EGS) — conceptual design and experimental results. Geothermics, 39(1), pp.59-69.

Portier, S., Vuataz, F.D., Nami, P., Sanjuan, B. and Gérard, A., 2009. Chemical stimulation techniques for geothermal wells: experiments on the three-well EGS system at Soultz-sous-Forêts, France. Geothermics, 38(4), pp.349-359.

How to cite: Lu, R., Miao, X.-Y., Kolditz, O., and Shao, H.: Pore-scale modeling of acid etching in a carbonate fracture, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3960, https://doi.org/10.5194/egusphere-egu22-3960, 2022.

EGU22-4116 | Presentations | ERE5.3

Towards validating numerical simulations of drawdown in unconfined fractured rocks with field experiments: A comparative study at sub-seismic scale 

Maximilian O. Kottwitz, Anton A. Popov, Simon Freitag, Wolfgang Bauer, and Boris J. P. Kaus

Quantifying the effective permeability structure of fault and fracture zones is crucial for numerous geo-energy applications, especially at sub-seismic scales. However, the multi-scale presence of fractures and the structural heterogeneity of faults and host rocks often cause highly non-stationary and anisotropic hydraulic properties. This usually impedes the definition of representative elementary volumes and complicates the upscaling process. Thus, progressively integrating these multi-scale complexities into 3D numerical models of exploration targets has gained increasing scientific interest in recent years and is crucial to make predictions of flow and transport through reservoirs.

Here, we aim to reproduce multiple drawdown curves obtained in analog field pumping tests with numerical models of fluid flow in order to develop a proof of concept for generating correct hydraulic representations of fault and fracture zones in numerical models with the final goal to upscale their effective permeabilities for numerical simulations above the sub-seismic scale.

The test subject is a 30- by 30-meter-wide area in a quarry in the Franconian Alb, Germany, featuring an intensively deformed Upper Jurassic limestone formation, frequently explored for geothermal energy production in the southern German Molasse Basin. First, an initial 3D structural model of the main faults, fractures, and layer surfaces, based on multiple borehole logs and pavement traces is constructed with the GemPy software. In the next step, we employ a newly developed discretization method to convert the initial 3D GemPy model into various equivalent continuum models of the test field by parameterizing fracture, fault, and rock matrix permeabilities/porosities, resulting in high-resolution 3D voxel models with individual, anisotropic permeability tensors. Those serve as input for numerical simulations of a pumping test, where we solve for transient, unsaturated/saturated Darcy-flow using a newly developed parallel, 3D finite element code that utilizes a van Genuchten approximation for the arising non-linearities, i.e., relative permeability and water content. As a final step, we compare the drawdown curves logged in three observation wells in an analog constant-head hydraulic test in the field to the ones obtained from the numerical simulations by computing a cumulative misfit. While changing the parameters of the employed permeability-porosity parametrizations for faults, fractures, and rock matrix in a classical forward-approach manner, we can determine a range of best-fitting models. Preliminary results show that with some educated initial guesses on the hydraulic properties of the reservoir, we could reproduce the drawdown curves in two observation wells with a relative error below one percent after a couple of tens of simulations. The uniqueness of those results will be assessed during the discussion.

How to cite: Kottwitz, M. O., Popov, A. A., Freitag, S., Bauer, W., and Kaus, B. J. P.: Towards validating numerical simulations of drawdown in unconfined fractured rocks with field experiments: A comparative study at sub-seismic scale, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4116, https://doi.org/10.5194/egusphere-egu22-4116, 2022.

EGU22-4620 | Presentations | ERE5.3

Discrete fracture network analysis of Devonian carbonate rocks in Western Germany: Implications for deep geothermal energy, heat exploitation and anthropogenic fault reactivation 

Alessandro Verdecchia, Chelsea Pederson, Luca Smeraglia, Kevin Lippert, Adrian Immenhauser, and Rebecca Harrington

Faults and fractures in carbonate reservoirs strongly influence subsurface fluid movement and can determine the success or failure of geothermal energy and heat production projects. Characterizing their physical and hydraulic properties is therefore crucial. Firstly, because they strongly control the secondary porosity and permeability of the reservoir, which are key parameters for the estimation of the reservoir quality, and for the planning of injection/extraction strategies. Secondly, because upon anthropogenic reactivation, they can lead to felt seismic activity, which could interrupt operations and potentially lead to damage to infrastructure and endanger the population.

Devonian carbonate rocks underlie a vast portion of North Rhine-Westphalia in Western Germany. Their stratigraphic thickness (up to 1,300 m), location, and depth, make them a potential reservoir for deep geothermal heat and energy exploitation. While estimated at depths between 1.3 km and 6 km, outcrop analogues of these Devonian carbonates are exposed in a number of quarries in the region.

This work quantitatively characterizes the fracture and fault distribution and permeability of the Devonian limestones and dolostones exposed at the the Steltenberg quarry, located at the northern margin of the Remscheid-Altena Anticline. The units outcropping in the quarry are tectonically affected by splays of the WSW-ENE-trending Ennepe thrust (Variscan), and by post-Variscan NNW-SSE-trending normal faults. We combine field structural analyses and fracture characterization using scan lines with a 3D digital outcrop model and fracture analyses using UAV imagery, to produce 3D Discrete Fracture Network (DFN) models. Preliminary results show three main fracture sets: WSW-ENE-trending and S-dipping fractures parallel to the Ennepe Thrust, WSW-ENE-trending and N-dipping bedding-parallel fractures, and NNW-SSE-trending sub-vertical fractures parallel to the regional post-Variscan normal faults. Our DFN modeling suggests that the latter represent the main pathways for fluid flow with permeability values up to 10-14 m2.

As next steps we will use the DFN modeling results (e.g., fractures sets, permeability tensor) as input for a 3D thermo-hydro-mechanical finite element model aimed at predicting fluid flow, pressure, and stress changes in a potential geothermal reservoir. Modeling, together with fault-related parameters such as slip tendency and fracture susceptibility, will help estimate the potential for fault reactivation and induced seismicity in the region.

How to cite: Verdecchia, A., Pederson, C., Smeraglia, L., Lippert, K., Immenhauser, A., and Harrington, R.: Discrete fracture network analysis of Devonian carbonate rocks in Western Germany: Implications for deep geothermal energy, heat exploitation and anthropogenic fault reactivation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4620, https://doi.org/10.5194/egusphere-egu22-4620, 2022.

EGU22-5614 | Presentations | ERE5.3

Phase Field Modelling of Interactions Between Hydraulic Fractures and Natural Fractures 

Xiaoxuan Li, Hannes Hofmann, Keita Yoshioka, Yongjiang Luo, and Yunpei Liang

Hydraulic fracturing is widely applied in unconventional reservoirs to generate fracture networks for productivity enhancement. Interactions between hydraulic fractures and natural fractures have a great impact on fracture propagation. In this study, we use a two-dimensional phase field model to investigate interactions between hydraulic fractures and different frictional or cemented fractures under different in-situ stress, injection rate, natural fracture orientation and strength. We find that with the increasing stress anisotropy, hydraulic fracture is more likely to cross natural fracture and leads to a lower fracture complexity. A moderate injection rate is conducive for complex fractures. The approaching angle between the hydraulic fracture and natural fracture impact fracture topology. Complex fractures are formed when the angles are not so steep. With the increasing strength contrast between natural fractures and the rock matrix, the material heterogeneity increases for hydraulic fractures to generate complex fractures. Compared with frictional NFs, opening stronger cemented NFs requires more pressure than hydraulic fracture propagating outside the interface. The numerical investigations in this study can provide theoretical support and design guidance for fracturing operations in complex geological conditions.

How to cite: Li, X., Hofmann, H., Yoshioka, K., Luo, Y., and Liang, Y.: Phase Field Modelling of Interactions Between Hydraulic Fractures and Natural Fractures, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5614, https://doi.org/10.5194/egusphere-egu22-5614, 2022.

EGU22-5748 | Presentations | ERE5.3

A numerical study on the thermo-mechanical response of deformable fractured systems to advective-diffusive heat transport 

Silvia De Simone, Benoit Pinier, Olivier Bour, and Philippe Davy

Geothermal energy applications involve heat circulation in naturally fractured reservoirs, which are in general difficult to characterize due to the multiscale complexity of the fracture network and therefore the flow. In this context, numerical modeling is key to forecast the performance of geothermal energy applications under a number of scenarios. Numerical modeling is challenging because fractures represent the main pathway for flow and advective transport, but diffusive thermal exchange with the host rock controls the geothermal performance - the two processes occurring on very different length and time scales. Moreover, the host rock cooling provokes thermal contraction which tends to increase the fracture aperture, with direct effects on the flow and the advective transport. Quantify these processes is crucial but in general computational demanding when dealing with large reservoirs with hundreds of thousands of fractures.

In this study we present a novel methodology to simulate thermo-mechanical (TM) heat transport. The method is based on the particle tracking approach in Discrete Fracture Networks (DFN) and it has been implemented in the DFN.Lab software platform. The contribution of the host rock matrix in terms of diffusive heat exchange and thermal contraction/expansion is analytically evaluated, which directly impacts the fracture aperture and therefore the advective heat transfer. The methodology enables investigating the reservoir behavior and optimizing the geothermal performance while keeping the computational effort within reasonable values. Results from simulations of cold fluid injection show that rock contraction accelerates the advective transport resulting in a faster recovery of cold fluid at the outlet. We analyze systems of fractures with different characteristics (density, aperture, geometrical patterns, ...) and we identify the parameters that mostly impact the TM response.

How to cite: De Simone, S., Pinier, B., Bour, O., and Davy, P.: A numerical study on the thermo-mechanical response of deformable fractured systems to advective-diffusive heat transport, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5748, https://doi.org/10.5194/egusphere-egu22-5748, 2022.

EGU22-9292 | Presentations | ERE5.3

The real potential of fractured aquifers for CO2 storage 

Giampaolo Proietti, Valentina Romano, Rajesh Pawar, and Sabina Bigi

The CCS (Carbon Capture & Storage) process involves the capture of CO2 produced by energy production plants, cement factories and refineries, transport to storage sites and injection into deep geological structures with physical and chemical characteristics suitable for long-term confinement. This technology can significantly assess the containment of CO2 emissions into the atmosphere, with an estimated reduction between 12% and 14%. One of the most important phases in which the role of the geoscientist is necessary is the screening of the structures with the suitable geological characteristics for CO2 trapping and the estimation of the injectable mass.

Storage capacity estimates are usually approximate and are based on the average geometric and physical values of the geological formations. Furthermore, not knowing in detail the heterogeneity and complexity of geological structures, many storage efficiency scenarios are presented, which consequently propose very different values. Fractured rocks are one of the largest resources on the earth's surface, and host many of the most important reserves of water, oil and natural gas, and can also be exploited for the storage of gas or carbon dioxide. Determining the dynamic behaviour of fluids within a fractured rock mass is a necessary step in the characterization and definition of a potential site for CO2 injection.

In this work a Discrete Fracture Network (DFN) approach is used to quantify the efficiency of fracture systems to the fluid transport, quantifying the mass of supercritical CO2 injectable in a volume of rock with different fracture intensity in a purely discrete approach, with the utilization of dfnWorks and FEHM software. Using multi-phase reservoir simulations of CO2 injection, we determine the efficiency and storage capacity of fractured rocks. The main result this approach is the introduction of the Efr index which quantifies the efficiency of fracture systems for supercritical CO2 injection. This index allows, starting only from the fracture intensity data and using the equations proposed in the literature for the calculation of the storage capacity, to obtain an immediate and reliable estimate of the volume of the aquifers, which consider the efficiency of fractured aquifers to the fluid flow.

How to cite: Proietti, G., Romano, V., Pawar, R., and Bigi, S.: The real potential of fractured aquifers for CO2 storage, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9292, https://doi.org/10.5194/egusphere-egu22-9292, 2022.

EGU22-11289 | Presentations | ERE5.3

A numerical model for CO2 gas migration in a fault zone. 

Valentina Romano, Sabina Bigi, Heeho Park, Albert J. Valocchi, Jeffrey De'Haven Hyman, Satish Karra, Michael Nole, Glenn Hammond, Giampaolo Proietti, and Maurizio Battaglia

In a geological CO2 storage site, the main migration pathways in case of leakage would be compromised boreholes or gas permeable faults or fractures. In this work we propose a modeling workflow based on detailed field data acquired on a fault exposed in the Roman Valley Quarry (Majella Mountain, Italy), to simulate the three-dimensional migration of gas CO2 in the fault zone. The numerical modeling is performed using the open-source multiphase flow simulator PFLOTRAN. This study provides a new methodology to characterize the hydraulic behavior of a fault including all its components, the core and the damage zone, capturing in detail the impact of the fault zone architecture to the migration of CO2. Simulation test results point out the robustness of the modeling approach, highlighting its strong predictive power, and show how most of the gas migrates through the high permeable footwall damage zone, where the injection occurs, whereas some of the gas also migrates through the hanging wall damage zone and the fault core. The buildup of gas pressure in the vicinity of the injection wells demonstrates the need of increasingly accurate modeling of the injection conditions to avoid possible faults reactivation and CO2 leakage. While the technique presented here is applied to a case scenario on carbonate rocks, the proposed methodology can be extended to other geological scenarios, by the appropriate calibration of the geometric and petrophysical parameters of fractures and host rock, to understand the conditions under which faults can promote fluid flow from a reservoir and mitigate the risk of CO2 migration via faults.

How to cite: Romano, V., Bigi, S., Park, H., Valocchi, A. J., Hyman, J. D., Karra, S., Nole, M., Hammond, G., Proietti, G., and Battaglia, M.: A numerical model for CO2 gas migration in a fault zone., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11289, https://doi.org/10.5194/egusphere-egu22-11289, 2022.

EGU22-11415 | Presentations | ERE5.3

Counterintuitive fracturing in a multilayer of more or less competent rocks: Examples in porous carbonates and metamorphic rocks, and explanation with numerical modelling 

Andrea Bistacchi, Mattia Martinelli, Riccardo Castellanza, Gloria Arienti, Giovanni Dal Piaz, Bruno Monopoli, and Davide Bertolo

Characterizing and modelling geometrical and topological characteristics of fracture networks, both in fault zones and in the less-fractured background, is essential for the analysis and modelling of mechanical and hydraulic properties of rock masses (i.e. rock plus fractures). Here we present evidence of a counterintuitive behavior in mechanically layered sequences of different kinds of rocks, from porous carbonates to metamorphic rocks. In our case studies the more intense fracturing, both in terms of fracture density/intensity and number of fracture sets, is observed in the more competent layers, that can be therefore considered the more permeable ones.

In large outcrops of the Island of Gozo (Malta) we have characterized several damage zones in the Lower Globigerina Member (LGM) and Lower Coralline Limestone (LCL). A complete petrophysical and geomechanical characterization of these rocks shows the following properties (LGM vs. LCL): porosity 33% vs. 23%; Young’s modulus 2.4GPa vs. 5.5GPa; Poisson’s coefficient 0.18 vs. 0.15; UCS 14MPa vs. 36MPa; tensile strength 2.3MPa vs. 4.4MPa. Despite the LGM being by far the “softer” mechanical layer, we see that the thickness of the damage zone is about 1/30 in this unit with respect to the LCL, and that, comparing sections at the same distance to the fault core, fracture intensity is about 1/10.

In large outcrops in the Breuil-Cervinia area, at the foots of the Italian side of the Cervino-Matterhorn, we have observed a strikingly similar situation in uniformly fractured rocks (no major fault here) of the Dent Blanche and Combin Nappes. These are, in order of decreasing competence, greenschist facies (possibly formerly blueschist) meta-gabbros and meta-granitoids (Dent Blanche), and prasinites and calcschists (Combin). As in the Gozo case study, our quantitative characterization of fracturing reveals an inverse correlation between competence and fracturing parameters.

To understand the physics behind these observations, we have performed simulations with a geomechanical finite element code. During horizontal extension of a multilayer with variable elastic properties, deviatoric stresses build up much more quickly in less compliant, stiffer rocks. This is because all the different layers are subject to the same strain (horizontal stretching), and stress is controlled by the elastic moduli, resulting in higher deviatoric stresses in more rigid layers. At some point, brittle failure (simulated as plastic yield in continuous FEM codes) takes place in the stiff layers, well in advance with respect to failure in the soft ones. At this point, the simulation reveals a situation where fracturing is confined in the stiff layers. As horizontal stretching continues, failure can occur also in the soft layers, but always in a more limited way.

Even if in the Cervino-Matterhorn case study also pressure solution should have played a role in inhibiting fracturing in calcschists, we feel that this mechanical behavior, observed in very different tectonic environments and lithological units, can be of general relevance and might result in a reevaluation of paradigms used to predict fracturing and hydraulic properties of mechanically layered reservoirs in general.

How to cite: Bistacchi, A., Martinelli, M., Castellanza, R., Arienti, G., Dal Piaz, G., Monopoli, B., and Bertolo, D.: Counterintuitive fracturing in a multilayer of more or less competent rocks: Examples in porous carbonates and metamorphic rocks, and explanation with numerical modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11415, https://doi.org/10.5194/egusphere-egu22-11415, 2022.

EGU22-11868 | Presentations | ERE5.3

Using fractured outcrops to calculate permeability tensors. Implications for geothermal fluid flow within naturally fractured reservoirs. 

Ruaridh Smith, Martin Lesueur, Ulrich Kelka, Daniel Koehn, and Thomas Poulet

Naturally fractured systems are an important component to fluid flow for a variety of applications, in particular geothermal energy extraction. Geothermal reservoirs often have low rock permeability (e.g. limestone reservoirs) where permeability anisotropy is governed at first order by fractured networks controlled by fracture density, orientation and connectivity. These are often difficult to assess and as such permeability estimates can lead to high uncertainties. Understanding how fracture networks influence permeability of reservoirs is an important aspect to geothermal exploration.

Where subsurface data (e.g. seismic and well) are limited, other data sources for characterising the reservoirs are required. Outcrop analogues are excellent areas for the analysis and characterisation of fractures within the host rocks found at depth. 2D fractured cliff faces and pavements provide information on variation in fracture arrangement, distribution and connectivity which can be utilised in thermohydraulic modelling of the geothermal system.

Through imaging of 2D fractured faces within target reservoir rocks and using efficient discretisation and homogenisation techniques, reliable predictions on permeability distributions in the geothermal reservoirs can be made. Using an example from an open pit quarry within the Franconian Basin, Germany, fracture network anisotropy in a geothermal reservoir (Malm) is assessed using detailed structural analysis and numerical homogenisation modelling of outcrop analogues.

Structural analysis shows several events affected the limestone reservoir unit in the area. The first major phase of deformation recorded are steep-angled reverse thrust and strike-slip faulting (stress orientated NNE-SSW) attributed to the Late Cretaceous Inversion. A second deformation phase causing normal faulting and fracturing within a NW-SE stress field is related to the European Cenozoic Rift System (e.g. Eger Rift). The final deformation phase recorded corresponds to the Alpine Orogeny where strike-slip faults and conjugate fractures are formed under a NW-SE compression and NE-SW extension. The faults and fractures are heavily influenced by the Kulmbach Fault, part of the Franconian Lineament Fault System that is observed 10m north of the quarry and active during the multiphase deformation culminating with a reverse throw of 800m.

2D imagery is used to capture the fracture networks interpreted through the structural analysis from which different sets of similar fractures are extracted. These are then digitised and meshed for numerical modelling and homogenisation using MOOSE Framework. Three fractured faces are imaged at increasing distance from the Kulmbach Fault to determine the fault impact on the potential flow within the system. The calculated permeability tensors from the homogenisation show differences in fluid transport direction where fracture permeability is controlled by orientation compared to a constant value which would be more pronounced for larger scale simulations. Therefore, for reliable predictions of geothermal flow within the networks, assigning permeabilities for sets is vital. As a result, it is observed that the orientation of the tensor is influenced by the Kulmbach Fault, and thus faults within the reservoirs at depth should be considered as important controls on the fracture flow of the geothermal system.

How to cite: Smith, R., Lesueur, M., Kelka, U., Koehn, D., and Poulet, T.: Using fractured outcrops to calculate permeability tensors. Implications for geothermal fluid flow within naturally fractured reservoirs., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11868, https://doi.org/10.5194/egusphere-egu22-11868, 2022.

Control volume finite element (CVFE) methods provide flexible framework for modelling flow and transport in complex geological features such as faults and fractures. They combine the finite element method that captures complex flow characteristics with the control volume approach known for its stability and mass conservative properties. The general approach of CVFE methods maps the physical properties of the system onto the element mesh (element-wise properties) while the node centred control volumes span element boundaries. In the presence of abrupt material interfaces between elements which are often encountered in fractured models, the method suffers from non-physical leakage in the saturation solution as the result of control volume discretization used for advancing the transport solution. In this work, we present a discontinuous pressure formulation based on control volume finite element (CVFE) method for modelling coupled flow and transport in highly heterogeneous porous media. We propose the element pair P(1,DG)-P(0,DG), a discontinuous first order velocity approximation combined with a discontinuous low order pressure approximation. The approach circumvents the non-physical leakage issue by incorporating a discontinuous, element-based approximation of pressure. Hence, the resultant control volume representation directly maps to the element mesh as well as to the projected physical properties of the system. Due to the low order nature of the formulation, low computational requirement per element and the improved control volume discretization, the presented formulation is proven more robust and accurate than classical CVFE methods in the presence of highly heterogeneous domains.

How to cite: Al Kubaisy, J., Salinas, P., and Jackson, M.: Discontinuous low order pressure formulation in control volume finite element method for simulating flow and transport in highly heterogeneous porous media, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12372, https://doi.org/10.5194/egusphere-egu22-12372, 2022.

The Wenchang 9/8 area is one of the most promising hydrocarbon accumulation zones in the Pear River Mouth Basin, China. In this area, oil and gas are mainly accumulated in the Zhuhai and Zhujiang formations and their hydrocarbon reservoirs are generally related to faults, which are mainly located at the intersection area between NW-striking faults and NE-striking faults. Furthermore, previous petroleum exploration indicates that oil and gas are mainly sealed by faults. Therefore, high-resolution fault sealing calculation like shale-gauge-ratio (SGR) has a significant influence on further petroleum production. Present methods can only calculate single or discontinuous points of SGR for one fault and does not provide the SGR for the entire fault plane, which could impact future petroleum exploration. Testing several methods, we established the 3D fault plane SGR calculation method, which is based on the Petrel software platform. We then used this method on proven oil-bearing structures and target structures in the Wenchang 9/8 area. The results show that: (1) the 3D fault plane SGR of the fault, which controls the Wenchang 9-3 oil-bearing structure, reaches 35%-45%; the 3D fault plane SGR of the fault, which controls the Wenchang 9-7 oil-bearing structure, reaches 40%-55%. Therefore, the 3D fault plane SGR in Wenchang 9-3 and 9-7 oil-bearing structures are consistent with petroleum production; (2) For the target structures the 3D fault plane SGR in target 1 reaches 35%-55%. This is very high and supposed to be the next promising area in the study area, while the 3D fault plane SGR in target 2 is just 20-25%, which indicates high exploration risk at this target. Accordingly, we will promote this method for exploration targets in other petroliferous basins.

How to cite: Xu, L., Wu, Z., Cheng, Y., and Xu, B.: 3D fault plane SGR calculation for fault sealing in Petrel software: An example from Wenchang 9/8 area of the Pear River Mouth Basin, China, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13140, https://doi.org/10.5194/egusphere-egu22-13140, 2022.

The spectral boundary integral equation (SBIE) method is widely used for numerical modeling of earthquake ruptures at a planar interface between two elastic half-spaces. It was originally proposed by Geubelle and Rice (1995) based on the boundary integral formulation of Budiansky and Rice (1979). The distinguishing feature of the formulation is that it involves performing elastodynamic space-time convolution of the displacement discontinuities at the interface between the two solids. The method was extended to bi-material interfaces by Geubelle and Breitenfeld (1997) and Breitenfeld and Geubelle (1998). An alternative boundary integral formulation to that of Budiansky and Rice (1979) is that of Kostrov (1966), where the elastodynamic space-time convolution is done of the tractions at the interface between the two solids. A SBIE method based on the latter formulation was proposed by Ranjith (2015) for plane strain. In the present work, the SBIE method for antiplane strain based on the formulation of Kostrov (1966) is proposed and compared with other approaches. Illustrations of the use of the method for simulating dynamic antiplane ruptures at bi-material interfaces are given.

How to cite: Kunnath, R.: A new spectral boundary integral equation method for antiplane problems, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9, https://doi.org/10.5194/egusphere-egu22-9, 2022.

EGU22-349 | Presentations | SM8.1

Numerical Advances in Understanding the Behavior of Gravity Retaining Wall during Seismic Motions 

Prerna Singh, Priyanka Bhartiya, Tanusree Chakraborty, and Dipanjan Basu

The response of gravity retaining walls during ground motion is still a challenging field. Recent developments in computational methods have opened the possibility of enhancing the understanding of the non-linear nature of soil-structure systems, e.g., earth pressure thrust acting on the retaining wall, translational and rotational movements, propagation of waves in the soil more realistically and quickly. Till today, Mononobe Okabe (MO) method (pseudo-static) is the most used analytical method because of its simplicity. However, there are many limitations and gives over-conservative results in terms of earth pressure thrust, and many literatures have already justified such a response. Several improved studies are already available, but very few have considered proper soil-structure interaction, real-time input earthquake data (not sinusoidal), and a sufficient number of earthquakes to evaluate the response acting on the wall during dynamic loading.

We seek contribution by analyzing the problem numerically using FE software Plaxis 2D and studying the behavior of retaining wall during seismic loading (range of amax = 0.053g to 1.2g) in terms of acceleration, displacement, rotation, and earth pressure thrust of retaining wall. The main contribution observed is the acceleration was not uniform throughout the medium instead gets amplified up to around 0.6g and later gets attenuated with maximum amplification occurring at the top of the retaining wall followed by the top of backfill soil and base of the wall. The residual displacement and rotation showed an incremental trend with an increase in horizontal seismic coefficient (kh). The earth pressure thrust obtained using numerical analysis was comparatively less than predicted by the MO method.

Keywords: Gravity retaining wall; Acceleration amplification response; Earth pressure thrust; Finite element method; 

How to cite: Singh, P., Bhartiya, P., Chakraborty, T., and Basu, D.: Numerical Advances in Understanding the Behavior of Gravity Retaining Wall during Seismic Motions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-349, https://doi.org/10.5194/egusphere-egu22-349, 2022.

EGU22-508 | Presentations | SM8.1

Do Large Earthquakes along Major Faults Synchronize in Time? 

Eyup Sopaci and Atilla Arda Özacar

The triggering mechanism of earthquakes and their synchronization in time and space can be considered the two sides of the same coin. Our previous studies on earthquake triggering reveal sensitive parameters affecting the triggering mechanism using simple spring slider systems. We pursue our previous analyses by considering a simulation set-up for synchronizing three strong asperity patches on a vertically oriented strike-slip fault with initial slip heterogeneity separated by barriers and strong creeping regions at the edges. This analogy intends to explore earthquake synchronization in time and mimic observed sequences of large earthquakes that ruptured most of the North Anatolian Fault within short time intervals. Using the quasi-dynamic and full-dynamic pseudo-spectral Fast Fourier Transform (FFT) method, we apply a periodic fault model governed with Rate-and-State Friction (RSF) law embedded in a 2.5D continuum. Simulation results so far using the quasi-dynamic approach revealed that the earthquake synchronization is mainly affected by direct velocity effect parameters, barrier dimension/properties, and RSF law (aging and slip law), particularly the weakening terms. Lower direct velocity effect parameters, state evolutions with a stronger weakening term such as slip law, and shorter barrier lengths promote better synchronization. In this respect, we observed fast, slow, or no synchronization depending on the parameter sets. It is also worth noting that slip localizes in the continuum at small critical slip distances, which cannot be inferred from simple 1D models, suggesting the size dependence. In order to minimize inherent non-uniqueness and uncertainties, the same set-up will also be simulated with the full-dynamic approach in which wave-mediated stress transfer is taken into account, and the long-term earthquake histories will be correlated with case-specific simulations.

How to cite: Sopaci, E. and Özacar, A. A.: Do Large Earthquakes along Major Faults Synchronize in Time?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-508, https://doi.org/10.5194/egusphere-egu22-508, 2022.

It is widely accepted that the rupture area of earthquake is controlled by fault geometry and the interaction between segments. Besides, many earthquakes do not rupture the whole seismogenic depth but only some limited depth zone. It is not so often to observe that a moderate earthquake such as the 2019 Mw4.9 Le Teil, France, earthquake shows a clear surface rupture and the very shallow rupture area limited at the first 1-2 km depth. Aochi and Tsuda (EGU, 2021) propose the concept that the fault is not uniformly loaded along dip due to the 1D layered structure. Namely, the stress is loaded mainly on the stiff layers, while the soft layers play a role of barrier. We use a boundary element method and a spectral element method for simulating the dynamic rupture propagation and wave propagation. We then demonstrate that the shallowest soft layer can be slipped if the rupture at deeper portion is sufficiently developed. On the other hand, a depth soft layer is difficult to be ruptured, mainly because the absolute stress level is high. In our synthetic scenarios, we compare the ground motions around the fault. In the usual model where the stress is uniformly loaded on all the depths, we observe a strong coherent pulse as the rupture progresses fast to the ground surface. However, we observe more than one pulse in our setting. Such heterogeneous condition along dip should be important to investigate the causality of the seismic asperity and the influence on the resultant near-field ground motion.

How to cite: Aochi, H. and Tsuda, K.: Numerical simulation of dynamic rupture and ground motion on a fault non-uniformly loaded along dip, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1672, https://doi.org/10.5194/egusphere-egu22-1672, 2022.

Earthquakes occur by sudden slippage along pre-existing faults via a frictional instability. Laboratory-derived rate and state friction laws have emerged as powerful tools for investigating the mechanics of earthquakes. Two types of state‐variable evolution laws are commonly used to fit the experimental data, the aging and slip laws. The aging evolution law has been used extensively to model the earthquake cycle, including the nucleation, dynamic rupture propagation and arrest, and interseismic period. The slip law, which generally provides a better fit to rock friction experiments, has rarely been used in simulations of the whole seismic cycle. In addition, faults are zones with complex internal structure and non-planar geometry, which also affect the rupture process during the seismic cycle.

In this study, I examine the effects of fault geometry, state evolution law, and friction parameters on the earthquake source process with fully dynamic 2-D simulations of earthquake sequences on planar and non-planar faults. The numerical approach accounts for all stages in the seismic cycle and enables modeling slip that is comparable to the minimum wavelength of roughness. I test the statistics of the events in terms of static source parameters and analyze in detail the rupture process during the nucleation and dynamic propagation stages. For the same friction parameters and fault geometry, the slip law results in a more rapid weakening of the friction coefficient than the aging law. That leads to ruptures with smaller nucleation sizes, larger slip rates, and larger rupture speeds for the slip law, including transition to supershear. With the aging law, a small level of fault roughness is enough to introduce considerable complexity into the rupture process, with larger amount of aseismic slip and larger variability in earthquake sizes.  For the same level of roughness, those effects are significantly smaller in the case of the slip law.

How to cite: Tal, Y.: The Seismic Cycle on Rate and State Faults with Different Evolution Laws and Fault Geometries, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2368, https://doi.org/10.5194/egusphere-egu22-2368, 2022.

EGU22-2414 | Presentations | SM8.1

Epistemic uncertainty in fault geometry effects earthquake rupture behavior 

Olaf Zielke, Theodoros Aspiotis, and Paul Martin Mai

It is well established in the seismology community that geometric complexity plays an important role for a fault’s seismotectonic behavior. It affects the initiation, propagation and termination of an earthquake as well as influencing the stress-slip relationship, the size of fault segments, and the probability of multi-segment rupture. Consequently, fault geometric complexity is studied intensively and increasingly incorporated into computational earthquake rupture simulations. These efforts reveal a problem: While we may be able to constrain a natural fault’s geometry with a high level of detail at the surface (i.e., the fault trace), we cannot do the same for the buried portion of the fault -where most of the rupture takes place. How much does a fault’s seismotectonic behavior vary as a result of this epistemic uncertainty?

We address this question computationally with a physics-based multi-cycle earthquake rupture simulator (MCQsim), enabling us to investigate how (for example) earthquake recurrence, slip accumulation, magnitude-frequency distribution, and fault segmentation vary (looking at the entire fault as well as individual locations on the fault) as function of our insufficient knowledge about the fault’s geometric complexity. To simulate fault geometric complexity, we generate 2-D random fields, using the “random midpoint displacement” method (RMD), representing the fault’s non-planar, self-similar geometry. The advantage of using RMD is that it allows us to create a 2-D random field while also keeping one or more of the field’s edges at a prescribed value. Hence, this approach allows us to generate a random field to represent fault roughness while also allowing us to incorporate what is known about the fault geometry (i.e., the fault surface trace, representing one of the random field’s edges). In doing so, we can investigate how the aforementioned seismo-tectonic parameters vary as a function of fault roughness uncertainty.

For this purpose, we create 5000-year long earthquake catalogs for a 150x18km large strike slip fault that is parameterized by more than 40k fault cells (average cell size 0.07km^2), containing earthquakes with 3.5 < M < 7.8. We create these catalogs for 100 roughness realizations while keeping the simulated fault’s surface trace constant for all realizations. The results of these simulations will be presented in our presentation.

How to cite: Zielke, O., Aspiotis, T., and Mai, P. M.: Epistemic uncertainty in fault geometry effects earthquake rupture behavior, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2414, https://doi.org/10.5194/egusphere-egu22-2414, 2022.

EGU22-2676 | Presentations | SM8.1

Ground-motion simulation in the Calabrian accretionary prism (Southern Italy) using a 3D geologic-based velocity model 

Giulia Sgattoni, Irene Molinari, Lorenzo Lipparini, Licia Faenza, and Andrea Argnani

Ground motion prediction is one of the main goals in seismic hazard assessment. Empirical ground motion prediction equations may fail to reproduce the complexity of ground shaking in complex 3D media and therefore the use of full waveform modelling is increasingly adopted to model ground shaking. The knowledge of the 3D crustal structure in terms of geometries of the main discontinuities and velocities is fundamental to model wave propagation. However, we often lack detailed geological and geophysical information to build reliable models.

We exploit here a large set composed of high-resolution 2D and 3D seismic data and of about 40 wells with stratigraphic and velocity information, both onshore and offshore, to constrain a 3D crustal velocity model in a sector of the Calabrian accretionary prism (southern Italy). We interpret the main reflection discontinuities and constrain their depth at all available wells in the study area and we use well’s check-shots and velocity data to estimate interval-velocities of the main stratigraphic units. We then combine all depth and velocity information into a regional 3D crustal velocity model of the first 8-10 km. This is subsequently extended to a depth of ~50 km using available regional crustal models to obtain the final model used for ground motion simulation.

We implement our crustal model in the spectral-element code SPECFEM3D_Cartesian to simulate wave propagation in the 3D velocity model honoring surface topography. This allows reconstructing the low-frequency part of the waveforms (up to ~1 Hz), which is then combined with high-frequency seismograms obtained with a stochastic method following the hybrid broadband simulation approach by Graves and Pitarka (2010).

We evaluate the goodness of our model by simulating real earthquakes and comparing simulated and recorded waveforms at the available seismic stations in the area. We compare the results from our 3D model with the ones obtained using a local tomography model and the European crust model EPcrust. The maps of ground motion obtained from the simulated broadband waveforms are then compared with empirical ShakeMaps. These results will also be useful for earthquake scenario calculations, by simulating potential seismic sources identified from structural analysis of geological and seismic data.

How to cite: Sgattoni, G., Molinari, I., Lipparini, L., Faenza, L., and Argnani, A.: Ground-motion simulation in the Calabrian accretionary prism (Southern Italy) using a 3D geologic-based velocity model, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2676, https://doi.org/10.5194/egusphere-egu22-2676, 2022.

EGU22-3110 | Presentations | SM8.1

Numerical Modeling of Cascading Foreshocks and Aftershocks in Discrete Fault Network 

Kyungjae Im and Jean-Philippe Avouac

Earthquakes often come in clusters formed of foreshock-mainshock-aftershock sequences. This clustering is generally thought to result from a cascading process which is commonly modeled using either the phenomenological ETAS model or a stress-based model assuming an earthquake nucleation process governed by Coulomb stress changes and Rate-and-State friction (CRS). In this work, we numerically investigated the foreshock and aftershock sequence in a discrete fault network with rate and state friction law and compared the result with the ETAS model. We set a fault zone consisting of dense fault segments and an off-fault area consisting of sparsely distributed smaller faults in the simulation domain. The CRS simulations are conducted 100 times with 1000 discrete faults with randomly generated fault location, initial velocity, and fault length within the weighted distribution, yielding a Gutenberg-Richter law. The simulations produce realistic foreshocks and aftershocks sequences. Aftershocks occur in the area of increased Coulomb stress and decay following Omori law as observed in nature. Individual foreshock sequences do not show a clear trend, but once stacked, they show an apparent inverse-Omori law acceleration. The prediction from our CRS model can be fitted with the ETAS model. This is not surprising since ETAS incorporates the Omori and Gutenberg-Richter laws. However, our CRS model predicts significantly more foreshocks than would be expected from the ETAS model. This results from the fact that the triggering productivity is lower in the aftershock sequence than in the foreshocks due to the depletion of critically stressed faults in our simulations. In other words, the ETAS is not compatible with the CRS model because Coulomb stress changes result in a time advance (if positive) or delay (if negative). This clustering process is fundamentally different from the additive process assumed in ETAS. As a result, the claim made that foreshocks more frequent than expected based on ETAS imply pre-seismic slip might be incorrect. It could alternatively be a manifestation of the nucleation process.

How to cite: Im, K. and Avouac, J.-P.: Numerical Modeling of Cascading Foreshocks and Aftershocks in Discrete Fault Network, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3110, https://doi.org/10.5194/egusphere-egu22-3110, 2022.

EGU22-3555 | Presentations | SM8.1

Detection Limits and Near-Field Ground Motions of Fast and Slow Earthquakes 

Grzegorz Kwiatek and Yehuda Ben-Zion

We investigate theoretical limits to detection of fast and slow seismic events and discuss spatial variations of ground motion expected from an synthetic family of M6 earthquakes at short epicentral distances. The performed analyses are based on synthetic velocity seismograms calculated with the discrete wavenumber method assuming seismic velocities and attenuation properties of the crust in Southern California. The examined source properties include  magnitudes ranging from M -1.0 to M 6.0, static stress drops (0.1-10 MPa), and slow and fast ruptures (0.1-0.9 of shear wave velocity). For the M 6.0 events we also consider variations in rise times producing crack- and pulse-type events and different rupture directivities. We found slow events produce ground motions with considerably lower amplitude than corresponding regular fast earthquakes with the same magnitude, and hence are significantly more difficult to detect. The static stress drop and slip rise time also affect the maximum radiated seismic motion, and thus event detectability. Apart from geometrical factors, the saturation and depletion of seismic ground motion at short epicentral distances stem from radiation pattern, earthquake size (magnitude, stress drop), and rupture directivity. The rupture velocity, rise time and directivity affect significantly the spatial pattern of the ground motions. The results can help optimizing detection of slow and fast dynamic small earthquakes and understand the spatial distribution of ground motion generated by large events.

How to cite: Kwiatek, G. and Ben-Zion, Y.: Detection Limits and Near-Field Ground Motions of Fast and Slow Earthquakes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3555, https://doi.org/10.5194/egusphere-egu22-3555, 2022.

EGU22-4709 | Presentations | SM8.1

On the relation between the coefficient of friction of a fault and the variation of damage degree on the host rock: a numerical approach 

Ludovico Manna, Marcin Dabrowski, Matteo Maino, Leonardo Casini, Alessandro Reali, and Giovanni Toscani

We present a study on the dependence of the frictional properties of a fault rock on its degree of damage. The purpose is therefore to gain insight into frictional sliding, the governing force that controls earthquake nucleation, propagation and arrest. The focus on this topic is to try to find a reason for the experimental evidence that the friction coefficient seems to be almost independent on lithology. A possible explanation to investigate through the numerical modelling could be that the frictional properties of a realistic fault rock depend mostly on the concentration of micro- to macroscopic cracks and/or of lamellar phyllosilicates in the host rock, rather than on the composition of its bulk materials. The formalism of the Linear Elastic Fracture Mechanics (LEFM) can quantitatively reproduce the stresses and the strains on the interface propagating frictional rupture. The purpose is to use a Finite Element Method (FEM) numerical code in order to simulate the plane strain elastic deformation of a two-dimensional medium crossed by elliptical fractures and weak anisotropic inclusions. The analysis of the distribution and orientation of the stresses resulting from the interaction of a system of randomly oriented elliptical fractures under different loading conditions could provide information on the onset and propagation of frictional ruptures, such as real contact area reduction, slip velocity, number and length of global sliding precursors. The magnitude and orientation of the principal stresses around the tips of elliptical voids are crucial for the understanding of fracture coalescence and frictional reactivation of shear cracks in an elastic rock, which in turn is one of the main factors that govern the seismic cycle of natural faults. 

How to cite: Manna, L., Dabrowski, M., Maino, M., Casini, L., Reali, A., and Toscani, G.: On the relation between the coefficient of friction of a fault and the variation of damage degree on the host rock: a numerical approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4709, https://doi.org/10.5194/egusphere-egu22-4709, 2022.

EGU22-5309 | Presentations | SM8.1

The onset of faulting around geometrically irregular faults 

Amir Sagy, Doron Morad, Yossef H. Hatzor, and Vladimir Lyakhovsky

Geological and geophysical observations indicate that fault geometry is nonplanar, includes irregularities in all directions at many scales. The geometrical heterogeneity of faults is particularly critical during the interseismic stage of the earthquake cycle because it perturbs the stress field and thus affects the rupture nucleation along the fault zone and around it. We present a new analytical solution for the static stress field around a rough interlocked interface obtained under compressional stresses, and discuss its applications to faulting and seismic hazards. The model outputs are the local stress field and the Failure-Ratio, defined here as the susceptibility to failure of the bulk material around the interface. The calculations are then obtained by the following steps: First, the interface geometry is represented by a Fourier series. Then, the stress components around the irregular interface are calculated analytically using perturbation theory for any two dimensional far-field stress tensor. Finally, the Failure Ratio at any location near the interface is estimated by adopting a Coulomb failure criterion for the bulk material.

The model results can be applied to faulting mechanics because they demonstrate how the elastic stress field around rough fault is controlled by the geometry and by the tectonic stresses. We find that under a given tectonic stress state, stress heterogeneity increases with roughness. Therefore, some zones near rough faults are expected to yield at lower tectonic shear stress comparing to zones nearby smooth ones. However, the magnitudes of these events are expected to be relatively small, as they nucleate under relatively low tectonic stresses and fail as they propagating immediately to a stress shadow. This stress distribution promotes small seismic events near rough fault and therefore we suggest that increasing heterogeneity of the surface, contributes to increasing of the b-value in Gutenberg-Richter earthquakes distribution.

We compare the model predictions with results of experiments performed on rough rock surfaces and find good agreement between the locations of off-fault deformation zones and the calculated high Failure-Ratio values. We further test the model implications for stresses and failure around a natural fault system – the San Andreas Fault and find a first-order agreement between Failure-Ratio values and earthquake distribution around this fault system. We conclude that the proposed analytical approach is a useful and practical tool for evaluating the contribution of fault geometry to the seismic hazard potential around it.

 

How to cite: Sagy, A., Morad, D., H. Hatzor, Y., and Lyakhovsky, V.: The onset of faulting around geometrically irregular faults, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5309, https://doi.org/10.5194/egusphere-egu22-5309, 2022.

EGU22-5432 | Presentations | SM8.1

Simulation of pure qP-wave in vertical transversely isotropic media 

Yi Zhang, Luca De Siena, and Boris Kaus

Acoustic wave equations are widely employed in wavefield extrapolation and inversion due to their simplicity compared to the elastic wave equations. In anisotropic media, qP- and qSV-waves are coupled. Multiple acoustic approximations in the vertical transversely isotropic (VTI) media have been proposed during the last decades. A classic way is to set the vertical S-wave velocity zero. As such, the S-wave artefacts still exist, whose amplitude increases with anisotropy. Setting S-wave velocity zero in all propagating directions tackles the issue. However, the higher-order spatial derivatives in the pure qP-wave equation make it hard to solve in the space domain. The spatial derivatives in the denominator of the pure qP-wave equation make the solution by the spatial-domain finite-difference unstable.  In this study, we employed the time-domain pseudospectral method to solve both the classic acoustic wave equation and the pure qP-wave equation in VTI media. Hybrid absorbing boundary conditions are used. Both equations are applied to reverse time migration (RTM) for the anisotropic Marmousi model. The new qP-wave equation outperformed the classic qP-wave equation regarding the computational time. Further work can be extended to waveform inversion with the pure qP-wave equation.

How to cite: Zhang, Y., De Siena, L., and Kaus, B.: Simulation of pure qP-wave in vertical transversely isotropic media, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5432, https://doi.org/10.5194/egusphere-egu22-5432, 2022.

The 2018 Mw 7.5 Palu earthquake struck the Sulawesi island, Indonesia, in 2018 and was followed by an unexpected tsunami. Using a physics-based, coupled earthquake-tsunami model, Ulrich et al. (2019) showed that direct earthquake-induced uplift could have sourced the tsunami. The 3D dynamic rupture model of the earthquake captures key observations, including the supershear rupture speed and the deformation pattern derived from satellite data. Stress state and fault conditions were tightly constrained by observations combined with simple static analyses based on Mohr-Coulomb theory of frictional failure and a few trial models. The earthquake scenario predicts a combination of up to 6 m of left-lateral slip and 2 m of normal slip on a straight fault segment dipping 65 degrees beneath Palu Bay.

While most studies (e.g. Bai et al., 2018, Ulrich et al., 2019, Oral et al., 2019) suggest a very early supershear transition, the exact timing of the onset of supershear rupture and the driving mechanism of the supershear transition are elusive. Here we revisit the earthquake dynamic rupture modeling based on new high-resolution near-fault deformation maps derived from correlation of optical satellite data. We vary nucleation radius, fault geometry, and off-fault plasticity parametrization to obtain alternative dynamic rupture scenarios. Specific inputs allow delayed transition to supershear. The obtained scenarios are evaluated based on near-fault damage inference.

Additionally, we revisit the tsunami model, adopting advanced strategies for earthquake-tsunami linking and tsunami modeling. In Ulrich et al. (2019), a one-way linking approach with a shallow water equations solver allowed translating the time-dependent seafloor displacements into a tsunami model with wave amplitudes and periods matching those measured at the Pantoloan wave gauge and inundation that is consistent with field survey data. Such modeling workflow yet neglects tsunami generation complexity, acoustic waves, and dispersion, and only approximates horizontal momentum transfer.  We present a 3D fully coupled earthquake-tsunami model (Krenz et al., 2021), that releases these limitations. This allows us to assess how the standard earthquake-tsunami workflow affects our results, and to revisit our conclusions.

How to cite: Ulrich, T., Marconato, L., Gabriel, A.-A., and Klinger, Y.: Revisiting earthquake-tsunami models of the 2018 Palu events using near-fault high-resolution imaging and 3D fully-coupled earthquake-tsunami modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5488, https://doi.org/10.5194/egusphere-egu22-5488, 2022.

EGU22-6897 | Presentations | SM8.1

Fluid-driven earthquake sequences and aseismic slip in a poro-visco-elasto-plastic fluid-bearing fault structure 

Luca Dal Zilio, Betti Hegyi, Whitney Behr, and Taras Gerya

There is a growing interest in understanding how geologic faults respond to transient sources of fluid. However, the spatio-temporal evolution of sequences of seismic and aseismic slip in response to pore-fluid evolution is still poorly constrained. In this study, we present H-MEC (Hydro-Mechanical Earthquake Cycles), a newly-developed two-phase flow numerical code — which couples solid rock deformation and pervasive fluid flow — to simulate how crustal stress and fluid pressure evolve during the earthquake cycle on a fluid-bearing fault structure. This unified 2D numerical framework accounts for full inertial (wave) effects and fluid flow in a finite difference method and poro-visco-elasto-plastic compressible medium with rate-dependent strength. An adaptive time stepping allows the correct resolution of both long- and short-time scales, ranging from years to milliseconds during the dynamic propagation of dynamic rupture. We present a comprehensive plane strain strike-slip setup in which we test analytical benchmarks of pore-fluid pressure diffusion from an injection point. We then investigate how pore-fluid pressure evolution and solid–fluid compressibility control sequences of seismic and aseismic slip on a finite fault width. While the onset of fluid-driven shear cracks is controlled by localized collapse of pores and dynamic self-pressurization of fluids inside the undrained fault zone, subsequent dynamic ruptures are driven by solitary pulse-like fluid pressure wave propagating at seismic speed. Furthermore, shear strength weakening associated with rapid self-pressurization of pore-fluid can account for the slip–fracture energy scaling observed in large earthquakes. This numerical framework provides a viable tool to better understand fluid-driven dynamic ruptures — either as a natural process or induced by human activities — and highlight the importance of considering the realistic hydro-mechanical structure of faults to investigate sequences of seismic and aseismic slip.

How to cite: Dal Zilio, L., Hegyi, B., Behr, W., and Gerya, T.: Fluid-driven earthquake sequences and aseismic slip in a poro-visco-elasto-plastic fluid-bearing fault structure, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6897, https://doi.org/10.5194/egusphere-egu22-6897, 2022.

EGU22-7558 | Presentations | SM8.1

First calibration of the physics-based ground motion model of the 2019 Mw4.9 Le Teil earthquake (France) 

Fanny Lehmann, Filippo Gatti, Michaël Bertin, and Didier Clouteau

The seismic risk in France, a region of low to moderate seismicity, is of paramount importance given the large number of industrial and nuclear installations. However, the large uncertainties on the geology and the poor knowledge of active faults make the seismic hazard estimation a challenging task. Despite being a promising tool to explore the underlying uncertainties, numerical simulations must be duly calibrated by reproducing specific events.

In this work, we considered the 2019 Mw4.9 earthquake that occurred at Le Teil village in southern France. This event was recorded by 17 stations of 3-component accelerometers, within an area of 50 km around the epicenter (French Accelerometric Network). We used these records to calibrate the numerical simulation. The seismological P- and S-wave speed profiles used result from a 3D weighted average model for Metropolitan France. In addition, the topography was included in the spatial discretization. The uncertainties on dip, strike, and rake angles were explored in order to calibrate the far-field synthetic ground motion model by determining the eigenquakes that efficiently span a large diversity of sources.

A good agreement between synthetic and recorded time histories was found, despite the simplicity of the geological and source model.

How to cite: Lehmann, F., Gatti, F., Bertin, M., and Clouteau, D.: First calibration of the physics-based ground motion model of the 2019 Mw4.9 Le Teil earthquake (France), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7558, https://doi.org/10.5194/egusphere-egu22-7558, 2022.

EGU22-7627 | Presentations | SM8.1

The role of rheological heterogeneities in postseismic deformation 

James Moore, Sambuddha Dhar, Jun Muto, Daisuke Sato, and Youichiro Takada

Advances in modelling and access to InSAR and GNSS observations have highlighted the role that rheological heterogeneities play in postseismic deformation. Here we discuss three recent studies (Muto et al. 2019, Sambuddha et al. 2022, and Takada et al. in prep) following the 2011 Tohoku-Oki and 2008 Iwate-Miyagi earthquakes, which reveal both localised and along-strike rheological heterogeneities. We construct a self-consistent physical model of the postseismic deformation for these two events using the Unicycle code (Moore et al. 2019, Barbot, Moore, and Lambert 2017), with which we consider coupled fault slip and viscoelastic flow utilising laboratory-derived constitutive laws to simulate the time series of geodetic observations. All three studies illuminate a crustal low viscosity rheological heterogeneity in the vicinity of Mt Kurikoma / Mt Naruko. This is perhaps to be expected, given the proximity to known active volcanic centres, and is commensurate with observations following the 2016 Kumamoto earthquake (Moore et al. 2017) where we found low-viscosity anomalies beneath Mt Aso and Mt Kuju. However, the heterogeneities the data reveal are not restricted to known volcanic regions, because our results also suggest along-arc heterogeneity in the forearc mantle rheology of north-eastern Japan; specifically we find a narrower cold nose in the Miyagi region and wider for the Fukushima forearc. We also find evidence of interaction between the localized crustal heterogeneity and afterslip in both events, highlighting the importance of addressing mechanical coupling for long-term studies of postseismic relaxation. Variations in rheological properties in the lithosphere are not restricted to viscous and thermal effects, and observations of the Iwate-Miyagi earthquake suggest elastic heterogeneities may also play a role. We therefore conclude by presenting expressions for computing displacements and stress due to localised (faulting) and distributed inelastic deformation in heterogeneous elastic spaces with piece-wise constant homogeneous elastic subregions (Sato & Moore 2022), and their application in the context of the seismic cycle.

 

Muto J, Moore J D P, Barbot S, Iinuma T, Ohta Y, Horiuchi S, Hikaru I, 2019. Coupled afterslip and transient mantle flow after the 2011 Tohoku earthquake. Science Advances

Dhar S, Muto J, Ito Y, Muira S, Moore J D P, Ohta Y, Iinuma T, 2022. Along-Arc Heterogeneous Rheology Inferred from Postseismic deformation of the 2011 Tohoku-oki Earthquake.

Moore J D P, Barbot S, Feng L, Hang Y, Lambert V, Lindsey E, Masuti S, Matsuzawa T, Muto J, Nanjundiah P, Salman R, Sathiakumar S, & Sethi H, 2019. jdpmoore/unicycle: Unicycle. In Coupled afterslip and transient mantle flow after the 2011 Tohoku earthquake, Science Advances 2019. Zenodo. https://doi.org/10.5281/zenodo.5688288

Barbot S, Moore J D P, Lambert V, 2017. Displacements and stress associated with distributed anelastic deformation in a half-space. BSSA

Moore J D P, Yu H, Tang C, Wang T, Barbot S, Peng D, Masuti S, Dauwels J, Hsu Y, Lambert V, Nanjundiah P, Wei S, Lindsey E, Feng L, Shibazaki B, 2017. Imaging the distribution of transient viscosity after the 2016 Mw7.1 Kumamoto earthquake. Science

Sato D, Moore J D P, 2022. Displacements and stress associated with localised and distributed inelastic deformation with piecewise-constant elastic variations.

How to cite: Moore, J., Dhar, S., Muto, J., Sato, D., and Takada, Y.: The role of rheological heterogeneities in postseismic deformation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7627, https://doi.org/10.5194/egusphere-egu22-7627, 2022.

EGU22-8291 | Presentations | SM8.1

Seismic shaking scenarios for city of Dubrovnik, Croatia 

Helena Latečki, Marin Sečanj, Iva Dasović, and Josip Stipčević

The south-eastern part of Adriatic Sea is seismically highly active region where numerous strong events have occurred in historic times. Among these, the most significant is the infamous Great Dubrovnik earthquake of 1667. This event, whose magnitude was estimated to be in the vicinity of Mw 7.0, caused widespread devastation in the whole region. More recently, a large Mw 7.1 event happening in 1979 in Montenegro caused extensive damage along 100 km of coastline, including the area around Dubrovnik. From this it is obvious that the city of Dubrovnik is seismically highly vulnerable and that there is an acute need to better understand possible consequences if an event of such a magnitude would happen today.  
 
One of the major steps in reducing the seismic risk in any region is to simulate seismic shaking and to evaluate expected ground motion for plausible earthquake scenarios. Therefore, our aim in this work is to create several earthquake scenarios for the city of Dubrovnik and estimate seismically most endangered parts of the region. For that purpose, we first assemble a detailed 3D crustal model which includes information on physical parameters of interest (velocity and density) and which reflects all the important geological features of the studied area. Then, we test whether the model is suitable for simulation by computing and comparing broadband seismograms against the recorded data of several moderate events. We validate the results by assessing the goodness of fit for different metrics describing ground-motion. Next, by combining seismic and geophysical data, we define the geometry of the main active faults and parameters required for the rupture model used in the simulation. We calculate synthetic waveforms on a dense grid and then extract intensity measures to determine the expected ground-motion features of a strong seismic event such was The Great Dubrovnik earthquake.

How to cite: Latečki, H., Sečanj, M., Dasović, I., and Stipčević, J.: Seismic shaking scenarios for city of Dubrovnik, Croatia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8291, https://doi.org/10.5194/egusphere-egu22-8291, 2022.

EGU22-8698 | Presentations | SM8.1

Broadband strong ground motion modeling using planar dynamic rupture model with fractal parameters 

František Gallovič and Ľubica Valentová

Dynamic rupture modeling represents a preferable physics-based approach to strong ground motion simulations. However, its application in a broad frequency range (0-10Hz), interesting for engineering studies, is challenging. The main reason is that relatively simple models with smooth distributions of initial stress and frictional parameters on planar faults result in ground motions with depleted high-frequency content. Several studies suggested that nonplanar rupture surfaces can solve this issue. Nevertheless, fully accounting for rough ruptures typically requires supercomputers, preventing widespread use.

Here we test an efficient approach for the linear slip-weakening friction model on planar fault, based on the Ide and Aochi (2005) multiscale model, with a small-scale fractal distribution of the slip-weakening distance Dc. To intensify the incoherence of the rupture propagation, we also include a variation of the strength and initial stress correlated with Dc. We propose a way to combine the fractal variations of the dynamic parameters with a large-scale dynamic model. The planar fault assumption permits the use of the computationally very fast code FD3D_TSN (Premus et al., 2020). 

We illustrate the approach on a canonical elliptical model with linearly increasing fracture energy (i.e., constant rupture velocity) and the 2016 Mw6.2 Amatrice earthquake smooth rupture model from the dynamic source inversion by Gallovič et al. (2019). We demonstrate that the addition of the small-scale fractal properties results in sustained high-frequency radiation during the rupture propagation and omega-square (apparent) source time functions. The model improves the fit of the recordings of the Amatrice earthquake in the frequency range of 0-10Hz and generates synthetics agreeing with ground motion prediction equations up to 5Hz.

Our FD3D_TSN takes about 5 minutes to simulate the Mw6.2 rupture propagation on a single GPU. Nevertheless, the fractal dynamic model can be easily implemented in any dynamic rupture propagation code. This makes the proposed approach readily applicable in physics-based ground motion predictions for scenario earthquakes in seismic hazard assessment.

How to cite: Gallovič, F. and Valentová, Ľ.: Broadband strong ground motion modeling using planar dynamic rupture model with fractal parameters, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8698, https://doi.org/10.5194/egusphere-egu22-8698, 2022.

EGU22-10523 | Presentations | SM8.1

A Discontinuous-Galerkin approach to model non-classical nonlinearity observed from lab to global scales 

Zihua Niu, Alice-Agnes Gabriel, Dave May, Christoph Sens-Schönfelder, and Heiner Igel

Under dynamic perturbations, it has been observed that materials like sedimentary rocks show complex mechanical behaviors. They include the simultaneous dependence of the elastic moduli and attenuation on strain at the same time scale of the perturbations, as well as the conditioning and recovery of the elastic moduli that may happen at time scales that are much larger. The latter cases were recently referred to as non-classical nonlinearity. Aside from laboratory experiments, comparable observations of the non-classical nonlinearity have been made in the field over the past two decades with the development of long-term continuous monitoring of the velocity field inside the Earth using methods such as ambient noise interferometry.

 

A variety of mathematical models that can potentially quantify the non-classical nonlinearity have already been proposed, e.g., the Damage–Breakage Rheology Model, the Internal Variable Model and the Godunov–Peshkov–Romenski model. However, implementing them in numerical schemes suitable to reproduce nonlinear effects in wave propagation on the local, regional, or global scale is challenging. This can be of interest for constraining a more realistic dynamic rheology for the Earth with the field observations.

 

In this work, wave propagation in different non-classical nonlinear models is implemented in FEniCS using the discontinuous Galerkin (DG) method in 1D. Behaviors of the different models are systematically studied and quantitatively compared against measurements. This work lays the foundation for an extension to the simulation of 2D/3D wave propagation in the Earth on the large-scale DG simulation frameworks, e.g., SeisSol and ExaHyPE.

How to cite: Niu, Z., Gabriel, A.-A., May, D., Sens-Schönfelder, C., and Igel, H.: A Discontinuous-Galerkin approach to model non-classical nonlinearity observed from lab to global scales, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10523, https://doi.org/10.5194/egusphere-egu22-10523, 2022.

EGU22-10798 | Presentations | SM8.1

Numerical analysis of the seismic hazard in Sichuan-Yunnan region 

Di Yin, PeiYu Dong, and YaoLin Shi

    The Sichuan-Yunnan region is located in the southern part of Chinese north-south seismic belt and has strong seismic activity. The prediction of future strong earthquake activity in this region has always been a research hotspot. In this study, firstly, we established a quasi-three-dimensional finite element elastic model, combined with the regional geological background and GPS observation data. Then, based on the information of 30 M>6.7 historical earthquakes that occurred in the region over the past 100 years, and constrained by the Coulomb-Mohr rupture criterion, we inverted a possible reasonable initial stress field at a specific time. Secondly, we simulated the development process of each historical earthquake and reproduced the 30 events orderly, by comprehensively considering the tectonic stress loading in the seismogenic stage and the stress change in the co-seismic adjustment stage. However, it is worth noting that there were some uncertainties in the numerical simulation process. We used Monte Carlo random experiments to obtain 5000 kinds of different possible initial values, which all can reproduce the development process of historical events. Then we got different current reginal stress values and calculated earthquake risk coefficient. Finally, we used mathematical methods to investigate the current seismic hazard of the different models, and assembled them into a probability distribution map of possible seismic risk in the region. The preliminary result shows that the seismic risk in the rupture zone of historical earthquakes is greatly reduced, which means relatively safe. Mainly due to the stress change caused by the 2008 Wenchuan Ms8.0 earthquake, the seismic probability in the northeastern segment of the Longmenshan fault is as high as 30%. At the junction of the southwestern section of the Longmenshan fault and the Xianshuihe fault zone, the seismic probability is about 15-20%. In addition, near the Longling Ruili fault and the Lancangjiang fault in southwestern Yunnan, the value is about 10-15%. In recent years, small earthquakes have occurred frequently in southwestern Yunnan, and the seismic risk in this area is also worth noting.

How to cite: Yin, D., Dong, P., and Shi, Y.: Numerical analysis of the seismic hazard in Sichuan-Yunnan region, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10798, https://doi.org/10.5194/egusphere-egu22-10798, 2022.

EGU22-11092 | Presentations | SM8.1

Time-varying stick-slip behaviors described by dehydration kinetics of gypsum 

Mikihiro Kawabata, Yuto Sasaki, Masaaki Iwasaki, Rei Shiraishi, Jun Muto, and Hiroyuki Nagahama

Dehydration embrittlement was proposed to account for intermediate or deep earthquakes (e.g., Raleigh and Paterson, 1965). Many researchers have investigated the frictional instability induced by dehydration of hydrous minerals, such as gypsum (e.g., Milsch and Scholz, 2005; Brantut et al., 2011; Leclère et al., 2016). In addition, time dependence of dehydration of hydrous minerals has been studied based on reaction kinetics (e.g., Sawai et al., 2013). Since kinetics controls the dehydration rate, the effect of dehydration-derived pore fluid pressure on the mechanical strength of rocks can also be represented by kinetics. However, there is no experimental study to quantitatively investigate how pore fluid pressure builds up and controls the mechanical strength of fault gouges in terms of kinetics. Here, we derived time function of pore fluid pressure based on dehydration kinetics of simulated gypsum (bassanite) gouges. First, we conducted friction experiments of simulated gypsum gouges using gas apparatus under eight different conditions of pressures from 10 MPa to 200 MPa and temperatures from room temperature to 180 °C, spanning dehydration condition of gypsum. Each stress-strain curve showed stick-slip behaviors with almost constant stress drops and recurrence intervals depending on the effective pressures under the conditions of room temperature (RT): larger stress drops and longer intervals for higher effective stresses. On the other hand, stress drops and recurrence intervals gradually decrease with time under 200 MPa and 110 °C, close to the dehydration boundary. These results suggested that the elevated pore fluid pressure by dehydration decreases effective pressure and reduces the stress drops and the intervals. We tested this hypothesis as follows. Microstructural observations illuminated marked development of Riedel shears (R1 shear) in samples deformed under the stability field of gypsums (RT and 70 °C), while scarce development of Riedel shears in the sample deformed under 110 °C, being consistent with Leclère et al. (2016)’s observations on that the elevated pore pressure suppress the development of Riedel shears. Based on the equation of state for water (He and Zoller, 1991), we calculated the porosity of the sample deformed under 110 °C. Although the estimated value was smaller than that obtained from dehydration under hydrostatic conditions (Bedford et al., 2017), this result indicates that shear compaction may have occurred due to deformation caused by higher differential stress. Considering that the decrease in effective pressure modulates the amount of stress drops and recurrence intervals, we analyzed frictional coefficients with Mohr’s circle assuming pore fluid pressure. The estimated value of about 0.6 is consistent with Byerlee (1978)’s law. Based on the results, we created a time function for evolution of pore fluid pressure controlled by Avrami-type dehydration kinetics (Avrami, 1940). The estimated Avrami exponent, the important parameter for crystallization, of 3.121 indicated that the dehydration proceeded with nucleation and three-dimensional growth. This function enables more accurate prediction of pore fluid pressure evolution controlled by dehydration kinetics and may contribute to better understanding the effect of hydrous minerals on frequency of intermediate and deep earthquakes.

How to cite: Kawabata, M., Sasaki, Y., Iwasaki, M., Shiraishi, R., Muto, J., and Nagahama, H.: Time-varying stick-slip behaviors described by dehydration kinetics of gypsum, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11092, https://doi.org/10.5194/egusphere-egu22-11092, 2022.

We cross validate a numerical solver for wave propagation in 3-D elastic media written on Graphical Processing Units (GPUs) against the semi-analytical solver for earthquakes in axisymmetric media, using seismic full moment tensors as earthquakes sources, variable earthquake source durations, and comparing observed with synthetic seismograms. The GPU-based solver is based on a numerical formulation of elastodynamic wave equation and can capture isotropic and anisotropic media. The algorithm simulates wave propagation in elastic media in three dimensions and at very high spatial and temporal resolution, and can compute entire wavefields within seconds (Alkhimenkov et al., 2021). For example, the multi-GPU code for elastic wave propagation can compute the entire wavefield of a 1000^3 model (1 billion grid cells) in 40 seconds. We achieve a close-to-ideal parallel efficiency (98% and 96%) on weak scaling tests up to 128 GPUs by overlapping MPI communication and computations. Seismic full moment tensors are routinely used to model a range of seismic processes, natural and anthropogenic, including earthquakes (shear slip), volcanic events, explosions, cavity collapses, landslides, etc. The analytical solver is based on a Thompson-Haskell propagator matrix for layered axisymmetric media (Zhu and Rivera, 2002), with moment tensors as seismic sources, with seismic sources at depths 10s of km below the surface and seismic stations at distances over 2000 km, and has been successfully used in various earthquake source studies (e.g. Alvizuri et al 2018). We validate the GPU-based wave propagation solver through numerical experiments in homogeneous and in layered media, and with observed and synthetic seismograms for an M4.6 earthquake in Linthal, Switzerland on 2017-03-06 with seismic stations at distances up to 30 km. The seismograms from the numerical solver match the analytic and observed seismograms (within frequencies 0.02-0.10 Hz). In future work we will apply the solver to study earthquake source generation, wave propagation in anisotropic media, and seismic source determination.

References
Alkhimenkov, Y., Räss, L., Khakimova, L., Quintal, B., & Podladchikov, Y., 2021. Resolving wave propagation in anisotropic poroelastic media using graphical processing units (CPUs), J. Geophys. Res., 126, doi:10.1029/2020JB021175.
Alvizuri, C., Silwal, V., Krischer, L., & Tape, C., 2018. Estimation of full moment tensors, including uncertainties, for nuclear explosions, volcanic events, and earthquakes, J. Geophys. Res. Solid Earth, 123, 5099–5119, doi:10.1029/2017JB015325.
Zhu, L. & Rivera, L. A., 2002. A note on the dynamic and static displacements from a point source in multilayered media, Geophys. J. Int., 148, 619–627, doi:10.1046/j.1365-246X.2002.01610.x.

How to cite: Alvizuri, C., Alkhimenkov, Y., and Podladchikov, Y.: Cross-validation of a GPU-based wave propagation solver and application to seismic waveform modeling of an M4.6 earthquake in Linthal, Switzerland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11592, https://doi.org/10.5194/egusphere-egu22-11592, 2022.

EGU22-11610 | Presentations | SM8.1

Broadband Dynamic Rupture and Ground Motion Simulations (up to 5 Hz) of the 2016 Mw 6.2 Amatrice, Italy Earthquake 

Taufiq Taufiqurrahman, Alice-Agnes Gabriel, Thomas Ulrich, Lubica Valentová, and Frantisek Gallovič

Broadband earthquake ground motion simulations (>1 Hz) are of great interest to seismologists and the earthquake engineering community. The evolution of the earthquake ruptures related to the 2016 Mw 6.2 Amatrice earthquake and the uniquely dense seismological recordings provide an opportunity to understand better the processes controlling earthquake dynamics, strong ground motion, and the relation between earthquakes. We here propose a novel approach to design data-driven broadband (up to 5 Hz) dynamic rupture scenarios from 0.5-1 Hz Bayesian dynamic finite-fault inversion (Gallovič et al., 2019). We analyze the effects of enhancing the best-fitting smooth dynamic source inversion result by subsequent adding of complexity such as non-planar fault geometry (i.e., fault listricity and surface roughness), topography, inelastic off-fault rheology, and visco-elastic attenuation. We utilize the open-source software package SeisSol (www.seissol.org), suited explicitly for incorporating such geometrical complexities and high-resolution simulations performed on modern supercomputers. The obtained scenarios reproduce synthetics resembling the observations in terms of velocity and accelerations waveforms and Fourier-amplitude-spectra (FAS) up to 5 Hz. The simulated peak ground velocity (PGV) maps show de-amplification of ground motion amplitudes on the foot-wall and amplification on the hanging-wall as a consequence of the wave-focusing effect caused by the listric fault curvature. This effect is seen mainly for distances up to 10 km from the fault. Our study suggests that the complexity of the earthquake source should not be neglected for the seismic hazard assessment for regions adjacent to active faults.

How to cite: Taufiqurrahman, T., Gabriel, A.-A., Ulrich, T., Valentová, L., and Gallovič, F.: Broadband Dynamic Rupture and Ground Motion Simulations (up to 5 Hz) of the 2016 Mw 6.2 Amatrice, Italy Earthquake, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11610, https://doi.org/10.5194/egusphere-egu22-11610, 2022.

Simulations of sequences of earthquakes and aseismic slip (SEAS) including more than one fault, complex geometries and elastic heterogeneities are challenging. We present a symmetric interior penalty discontinuous Galerkin (SIPG) method accounting for the complex geometries and heterogeneity of the subsurface. The method accommodates two- and three-dimensional domains, is of arbitrary order, handles sub-element variations in material properties and supports isoparametric elements, i.e. high-order representations of the exterior and interior boundaries and interfaces including intersecting faults.

We provide an open-source reference implementation, Tandem, that utilises highly efficient kernels, is inherently parallel and well suited to perform high resolution simulations on large scale distributed memory architectures. Further flexibility is provided by optionally defining the displacement evaluation via a discrete Green's function, using algorithmically optimal and scalable sparse parallel solvers and preconditioners. We highlight the characteristics of the SIPG formulation via an extensive suite of verification problems (analytic, manufactured and code comparison) for elasto-static and seismic cycle problems. We demonstrate that high-order convergence of the discrete solution can be achieved in space and time for elasto-static and SEAS problems.

Lastly, we apply the method to realistic demonstration models consisting of a 2D SEAS multi-fault scenario on a shallowly-dipping normal fault with four curved splay faults, and a 3D multi-fault scenario of instantaneous displacement due to the 2019 Ridgecrest, CA, earthquake sequence. We exploit the curvilinear geometry representation in both application examples and elucidate the importance of accurate stresses (or displacement gradients) representations on-fault. Our results exploit advantages of both the boundary integral and volumetric methods and is an interesting avenue to pursue in the future for extreme scale 3D SEAS simulations.

How to cite: May, D., Uphoff, C., and Gabriel, A.-A.: A discontinuous Galerkin method for sequences of earthquakes and aseismic slip on multiple faults using unstructured curvilinear grids, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12166, https://doi.org/10.5194/egusphere-egu22-12166, 2022.

EGU22-12539 | Presentations | SM8.1

Diffuse thick fault representation in 2D SEM for earthquake dynamic rupture simulations 

Jorge Nicolas Hayek Valencia, Dave May, Casper Pranger, and Alice-Agnes Gabriel

Natural fault system observations feature complexity that includes damage variation from the outer damage zone to the fault core and associated rheological degradation (e.g. variation in the frictional strength and spatio-temporal slip localisation). In earthquake dynamic rupture simulations, faults are typically treated as infinitesimally thin interfaces with distinct on- versus off-fault rheologies. Commonly, such faults are explicitly represented in the discretisation of the computational domain.

Here we present a diffuse interface approach for dynamic rupture modelling. We introduce a 2D spectral element method (SEM) with an embedded smeared discontinuity representing volumetric fault slip. Our diffuse fault SEM is inspired by the stress-glut method of Andrews, 1999. In our approach, a subdomain in which the tangential stresses are limited by a critical shear strength and an empirical friction law is embedded in a purely elastic domain, resembling classical discrete fault representations. Our approach is implemented on a structured quadrilateral mesh within an SEM framework for elastic wave propagation, with PETSc (Balay et al. 2019) as a linear algebra back-end.

Our method collapses volumetric complexities onto a distribution within a compact support instead of the traditional interface approach, making it a flexible inelastic zone alternative for mesh-independent fault representation in dynamic rupture simulations. We conduct 2D numerical experiments, including a kinematically driven Kostrov-like crack and spontaneous dynamic rupture as defined in SCEC community benchmarks (Harris et al., 2018) of increasing complexity. We extract the spectral response from seismograms at different receivers normal and along the fault. We also analyse the capacity of flexible fault representation by including mesh-independent fault geometries. 

Our approach will allow us to incorporate volumetric failure rheologies in SEM dynamic rupture simulations and is part of the TEAR ERC project (www.tear-erc.eu).

How to cite: Hayek Valencia, J. N., May, D., Pranger, C., and Gabriel, A.-A.: Diffuse thick fault representation in 2D SEM for earthquake dynamic rupture simulations, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12539, https://doi.org/10.5194/egusphere-egu22-12539, 2022.

EGU22-12624 | Presentations | SM8.1

Estimation of Rupture Scenarios along the Cascadia Megathrust from Interseismic Locking Models 

Yuk Po Bowie Chan, Hongfeng Yang, and Suli Yao

In the West of Northern America, the Cascadia subduction zone that extends over one thousand kilometers has well-documented geological records of megathrust earthquakes. The most recent one occurred in 1700 AD with a moment magnitude of 9. Hence, it has been more than 300 years since the last earthquake, suggesting that Southern Cascadia is mature for the next large earthquake. Estimating future rupture scenarios is therefore crucial for earthquake hazard assessment in the region. Multiple interseismic locking distributions have been proposed for Cascadia. Since each locking model differs from another, it remains unclear how to estimate future rupture extents from interseismic locking distributions. Here, we use 3-D dynamic rupture simulations to investigate the potential rupture segmentation in Cascadia and test the dependency of rupture propagation on hypocenter, especially for the Southern Cascadia. We process the slip deficit distributions from locking models by interpolation and smoothening with a gaussian filter. We then calculate the corresponding stress changes with the assumption that all slip deficits would be released during a coseismic event and derive different initial stress distributions by prescribing constant dynamic stress. For the northern segment, the stress-shadowing (Lindsey et al. 2021) and the viscoelastic (Li et al. 2018) interseismic locking models based respectively on elastic and visco-elastic deformation have similar stress levels, lower than those derived from the Gamma model (Schmalzle et al. 2014). In addition, the Gamma model displays a distinct low-stress gap in the central segment but the stress-shadowing and viscoelastic models show smooth transition stress changes. Since the stress-shadowing and the viscoelastic locking models bear a resemblance, dynamic simulations are then developed based on the initial stress conditions derived from the viscoelastic and the Gamma models by prescribing artificial nucleation zones on the fault plane with varied hypocentre locations. Preliminary results demonstrate three major rupture scenario types - self-arrested, segmented, and full-margin ruptures for both stress models. Given the same conditions, both models indicate that Southern Cascadia with a shorter recurrence interval has a lower potential of growing into a margin-wide rupture compared to the central segment. The southern segment mainly hosts self-arrested and segmented ruptures with Mw ranging from ~6.7 to >7.3. Another finding is strong along-strike variations in stress distribution flavor segmented ruptures while homogeneous stress field promotes margin-wide ruptures. For ruptures initiating from the central segment, several segmented ruptures with Mw 8.14 to larger than 8.25 are observed from the Gamma model but such features are absent in the viscoelastic model. Apart from segmented ruptures, the margin-wide ruptures have amplitudes of ground surface vertical displacement comparable to the subsidence record in the A.D. 1700 megathrust earthquake, particularly for the along-strike variation in the Gamma model.

How to cite: Chan, Y. P. B., Yang, H., and Yao, S.: Estimation of Rupture Scenarios along the Cascadia Megathrust from Interseismic Locking Models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12624, https://doi.org/10.5194/egusphere-egu22-12624, 2022.

EGU22-13390 | Presentations | SM8.1

Influence of pre-stress conditions in 2D plane strain simulations of a dynamic rupture with off fault damage 

Louise Jeandet Ribes, Marion Thomas, and Harsha Bhat

Understanding the mechanical properties of the off-fault medium and its interactions with earthquake rupture is essential for a better understanding of the behavior of fault zones. In this framework, two-dimensional, plane strain models are often used to investigate the interplay between seismic rupture propagation and inelastic deformation in the damage zone. The role of pre-stress conditions for faulting and damage has been studied, in particular the influence of Y, the angle between the largest principal stress and the fault strike. However, in plane strain conditions, the out-of-plane stress is often ignored when setting up the initial stress field, and its influence on dynamic rupture and stress evolution has not been inferred. In this study, we explore the role of the out-of-plane pre-stress for a 2D in-plane model in plane strain conditions. We model a 1D right-lateral, strike-slip vertical fault featuring slip-weakening friction law. We first demonstrate theoretically that if the out- of-plane stress is not considered properly in the initial stress field, pre-stress conditions may not correspond to actual strike-slip faulting. We then investigate how changing the initial stress field can influence the rupture and the stress evolution in the off-fault medium. Our results show that if it does not influence significantly the rupture dynamics, the out-of-plane stress is essential in controlling the evolution of the off-fault medium, especially the localization and extend of areas affected by plastic yielding. Therefore, our results demonstrate the importance of considering properly the initial out-of-plane stress to infer the extend, magnitude and distribution of damage in 2D plane strain simulations with off fault plastic deformation.

How to cite: Jeandet Ribes, L., Thomas, M., and Bhat, H.: Influence of pre-stress conditions in 2D plane strain simulations of a dynamic rupture with off fault damage, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13390, https://doi.org/10.5194/egusphere-egu22-13390, 2022.

EGU22-13551 | Presentations | SM8.1

A unified model for thermally-activated fault weakening during nonlinear dynamic earthquake rupture and off-fault fracturing in 3D diffuse fault zones 

Duo Li, Alice-Agnes Gabriel, Simone Chiocchetti, Maurizio Tavelli, Ilya Peshkov, Evgeniy Romenski, and Michael Dumbser

Earthquake fault zones are more complex, both geometrically and rheologically, than an idealized infinitely thin plane embedded in linear elastic material. Field and laboratory measurements have revealed intense fault weakening induced by flash heating and melting on natural fault (Di Toro et al., 2006; Goldsby & Tullis, 2011) and complex fault zone structure involving both tensile and shear fractures spanning a wide spectrum of length scales (e.g., Mitchell & Faulkner, 2009). Previous 2D numerical models explicitly accounting for off-fault fractures have demonstrated important feedback with rupture dynamics and ground motions (e.g., Thomas & Bhat 2018, Okubo et al., 2019). However, numerical studies of thermal-related weakening mechanisms usually avoid frictional melting due to the lack of the solid-fluid phase transition. 

In the work of Gabriel et al. (2021), we have presented our first-order hyperbolic and thermodynamically compatible mathematical model, namely the GPR model (Godunov & Romenski, 1972; Romenski, 1988), combined with a diffuse crack representation to incorporate finite strain nonlinear material behavior, natural complexities and multi-physics coupling within and outside of fault zones into dynamic earthquake rupture modeling. We compare our novel diffuse interface fault models of kinematic cracks, spontaneous dynamic rupture, and dynamically generated off-fault shear cracks to sharp interface reference models. Pre-damaged faults, as well as dynamically induced secondary cracks are therein described via a scalar function indicating the local level of material damage (Tavelli et al., 2020); arbitrarily complex geometries are represented via a diffuse interface approach based on a solid volume fraction function (Tavelli et al., 2019). 

Here we further extend the diffuse crack representation to more complicated scenarios including severe dynamic fault zone weakening as activated by flash heating, the effect of locally melting rocks, and off-fault cracks with complex topology in 3D materials, by taking advantage of adaptive Cartesian meshes (AMR) embedded in the extreme-scale hyperbolic PDE solver ExaHyPE (Reinarz et al., 2019). We intend to compare our thermally-weakened rupture in diffused fault zone with the semi-analytical thermal pressurization weakening implemented in the linear elastodynamic rupture on an infinitely-thin fault surface, using SeisSol (https://github.com/SeisSol). We will further qualitatively verify our model using the up-to-date observations in the 2020 M8.2 Chignik, Alaska, to illustrate the importance of thermal weakening on relatively deeper faults.

Our approach is part of the TEAR ERC project (www.tear-erc.eu) and will potentially allow to fully model volumetric fault zone shearing during earthquake rupture, which includes spontaneous partition of fault slip into intensely localized shear deformation within weaker (possibly cohesionless/ultracataclastic) fault-core gouge and more distributed damage within fault rocks and foliated gouges.

How to cite: Li, D., Gabriel, A.-A., Chiocchetti, S., Tavelli, M., Peshkov, I., Romenski, E., and Dumbser, M.: A unified model for thermally-activated fault weakening during nonlinear dynamic earthquake rupture and off-fault fracturing in 3D diffuse fault zones, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13551, https://doi.org/10.5194/egusphere-egu22-13551, 2022.

TS4 – Active tectonics, seismicity, and deformation

EGU22-164 | Presentations | TS4.1

Speleothem deformation due to the 2017 Mw 6.6 Bodrum–Kos earthquake in a cave on Pserimos (Dodecanese, Greece) 

Bernhard Grasemann, Lukas Plan, Ivo Baron, and Denis Scholz

Although damaged speleothems have been widely investigated to study paleo-earthquake records in caves, only few reports could directly link damages to specific recent earthquakes. We mapped before the 2017 Mw 6.6 Bodrum–Kos earthquake the so-far unexplored Korakia Cave on Pserimos island in the Dodecanese (Greece), which is located at the transition between the Aegean and Anatolian region and is known for its strong seismicity. The cave formed along an active normal fault and records numerous broken columns and flowstones sealed by younger speleothems. New 230Th/U-ages show that paleoseismic events occurred since the formation of the cave, which is older than the limit of the dating method. During a cave visit 2 months after the 2017 Mw 6.6 Bodrum–Kos earthquake we noted that c. 10 cm small stalactites, which were actively growing along fractures in the cave ceiling, have been chipped off by movements along the fractures and were lying on flowstones covered by greenish biofilms. Removal of the broken fragments demonstrated that the chlorophyll pigment below the position of the fragments did not show a colour difference to the surrounding area, which is exposed to the daylight of the cave entrance. The preservation of the photoautotrophic biofilm, which can survive only a few months without daylight, suggests that the stalactites have been broken by the 2017 Mw 6.6 Bodrum–Kos earthquake, which also caused the collapse of several buildings on the island of Kos only 4 km S of Pserimos. We conclude that earthquake capable of causing small shear displacements on fractures can damage speleothems. However, other delicate speleothems including long and slim stalactites remained undamaged.

How to cite: Grasemann, B., Plan, L., Baron, I., and Scholz, D.: Speleothem deformation due to the 2017 Mw 6.6 Bodrum–Kos earthquake in a cave on Pserimos (Dodecanese, Greece), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-164, https://doi.org/10.5194/egusphere-egu22-164, 2022.

Continental transform faults are generally known to have widely distributed structures and sparse seismicity, in opposite to their oceanic counterparts. The North Anatolian Shear Zone (NASZ) is an ideal example, where the total deformation is shared between multiple structures especially during its evolutionary stages. The North Anatolian Fault (NAF), the most prominent member of the NASZ, started to form of about 11 Ma in the east and propagated to the west, reaching to the Marmara Sea only a few hundred thousand years ago. This principal displacement zone generally extends as a single strand from its easternmost tip to the west until Bolu for about 900 km. To the west of Bolu, it bifurcates into two branches, Düzce and Mudurnu Valley segments, delimiting the Almacık Flake (AF) respectively to the north and south. Although there is a considerable number of multi-disciplinary studies on the kinematics and history of active faulting within and around the AF, we still have gaps in our knowledge on (a) the ratio of strain distribution, (b) time of formation of bounding fault segments and (c) their evolutionary stages.

In order to fulfil some parts of this gap, we studied the major morphometric indices, including hypsometric curve and integral (HI), asymmetry factor (Af), channel concavity (θ), chi (χ) and knickpoint analyses on drainage basins across the whole AF and all surrounding fault segments. Our goal is not only to document the comparative tectonic effect of the bounding fault segments on the topography, but also to test any potential cumulative morphological response to pre- and post-peak structures, especially along the Düzce Segment. Almost all of 83 extracted drainage basins yield high HI values, usually ranging between 0.4 and 0.72, and suggest a rejuvenating morphology compatible with the general ‘uplift hypothesis’ for the AF. In more details, θ and χ values point out the strong and confined effect of the active bounding faults. Moreover, knickpoints do not show evidence for any pre-peak structures rather than recent active faulting. This may be result of limited size, thus ages, of drainage basins, which are cut by bounding faults at both sides of the AF. Alternatively, these fault segments may be older than previous assumptions, whereas the effect of pre- and post-peak shear structures on topography has already been erased mainly by external processes. On the other hand, χ values, based on 0.45 reference θ, suggest a high incision along the western sections of the Mudurnu Valley Segment, which may indicate a strain transfer from north to south. Nevertheless, the breach of a landslide dam of about 5750 years ago and the strong incision of the Mudurnu River following this event to the south of the AF, as suggested by previous studies, can be another reason for this anomaly. Briefly, our preliminary results suggest a strong tectonic control on the AF’s topography mainly due to the activity of the bounding structures. We do not see any morphometric evidence for the secondary (pre- and post-peak) faults in the near past of the NASZ around the AF.

How to cite: Kiray, H. N., Sançar, T., and Zabcı, C.: Spatial strain distribution along continental transform faults: insights from morphometric analyses of the Düzce and Mudurnu Valley segments (North Anatolian Fault, NW Turkey), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-459, https://doi.org/10.5194/egusphere-egu22-459, 2022.

EGU22-1477 | Presentations | TS4.1

Incipient lithospheric collision throughout the East Mediterranean 

David Fernández-Blanco and César R. Ranero


We propose that lithospheric collision of Africa and Eurasia is incipient throughout the entire East Mediterranean. Our evidence confirms the incipient continent-continent collision that has been recently proposed for the Cyprus Arc and showcases how collision is expressed at depth and across the Hellenic Arc. We provide evidence of basin-wide lithospheric-scale collision by coupling, at tectonic scale (1.5M km2), quantitative joint analysis of submarine and terrestrial relief, and the interpretation of a compilation of regional vintage multichannel seismic data (>46.000 km), reprocessed with modern techniques. No megathrust surface marking a subduction interplate contact is imaged in any seismic line, and the relief across sedimentary piles is not shaped as mechanically-accreted wedges. Instead, continent-continent collision is expressed across plates in two modes along longitude. In the offshore regions south of Cyprus and Crete, submarine thrust systems with no frontal structure nor imbrication, and lacking latitudinal continuation, record collision stacking basin sediments vertically. Onshore, concurrent uplift and extension are recorded by uplifting strandlines, hanging valleys, and normal faulting, in both continents, and neatly so in the African margin in front of Crete. Joint plate deformation at lithospheric scale is further inferred as wavelengths of relief coherent across both plates. Regions located latitudinally to these collisional sites extrude away obliquely, either rigidly along transpressional systems, as immediately east of Cyprus and Crete, or through flow and halokinesis of Messinian salts, as on the eastern and western sectors of the Mediterranean Ridge. Our evidence typifies incipient lithospheric collision as expressed throughout the East Mediterranean.

How to cite: Fernández-Blanco, D. and R. Ranero, C.: Incipient lithospheric collision throughout the East Mediterranean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1477, https://doi.org/10.5194/egusphere-egu22-1477, 2022.

EGU22-1692 | Presentations | TS4.1

Slow-slip events destabilize upper-plate and trigger large-magnitude earthquake at the western-end of the Hellenic Subduction System 

Vasiliki Mouslopoulou, Vasso Saltogianni, Gian Maria Bocchini, Simone Cesca, Jonathan Bedford, Armin Dielforder, Onno Oncken, Michael Gianniou, and Gesa Petersen

Slow slip events (SSEs) in subduction zones can precede large-magnitude earthquakes and may therefore serve as precursor indicators, but the triggering of earthquakes by slow slip remains poorly understood. Here we report on a multidisciplinary dataset that captures a synergy of slow slip events, earthquake swarms and fault-interactions during the ~5 years leading up to the 2018 Mw 6.9 Zakynthos Earthquake at the western termination of the Hellenic Subduction System (HSS). We find that this long-lasting preparatory phase was initiated by a slow-slip event that released, over a period of 4-months, aseismic slip equivalent to a ~Mw 6.4 earthquake on the Hellenic plate-interface. This SSE, which is the first to be reported in the HSS, was associated with mild Coulomb failure stress changes (≤3 kPa) that were nevertheless sufficient to destabilize faults in the overriding plate. Tectonic instability was evidenced by a prolonged (~4 years) period of suppressed b-values (<1), an associated increase in upper-plate seismicity rates on discrete thrust, normal and strike-slip faults, including an earthquake swarm in the epicentral area of the Mw 6.9 earthquake, and another episode of slow-slip immediately preceding the Zakynthos mainshock. We show that this second SSE in 2018 caused stress changes up to 25 kPa in the epicentral area immediately prior to the mainshock, affecting a highly overpressured and mechanically weak forearc, whose state of stress fluctuated between horizontal deviatoric compression and tension during the years preceding the Zakynthos Earthquake. We conclude that this configuration facilitated episodes of aseismic and seismic deformation that ultimately triggered the Zakynthos Earthquake and may characterise other subduction zones globally.

How to cite: Mouslopoulou, V., Saltogianni, V., Bocchini, G. M., Cesca, S., Bedford, J., Dielforder, A., Oncken, O., Gianniou, M., and Petersen, G.: Slow-slip events destabilize upper-plate and trigger large-magnitude earthquake at the western-end of the Hellenic Subduction System, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1692, https://doi.org/10.5194/egusphere-egu22-1692, 2022.

EGU22-1972 | Presentations | TS4.1

​Studying the active tectonic in the northern flank of the Bozqush Mountains, NW Iran 

Ali Nasiri and Mahtab Aflaki

The NW-striking North Tabriz Fault is one of the most important basement faults in the northwest of the Iranian ‎plateau. This fault defines the boundary between the two tectonic ‎blocks with different stress regimes in its northern and southern parts as characterized with NW-SE and NE-SW direction of maximum horizontal compression, respectively. In the southern ‎termination of the North Tabriz fault, part of deformation is concentrated along its EW-striking splay faults extending along northern and southern boundaries of the Bozqush Mountains. The occurrence of medium-magnitude earthquakes, as ‎well as morphotectonic evidence reveal that modern deformation is dominantly concentrated along ~EW-striking dextral/reverse dextral and NNE-striking sinistral faults in the southern flank of the Bozqush Mountains. It is still not known to what extent the deformation is also accomodated in the northern flank of the Bozqush Mountain. The approach of this research is to ‎answer the question by studying the state of stress along the northern border of the Bozqush Mountains by applying the inversion method on the fault slip data measured during the field studies, studying their related ‎morphotectonic evidence, and comparing the results with ‎the state of stress and the morphotectonic evidence reported throughout the southern flank of the Bozqush Mountains. Fault kinematic data were collected at 35 sites ‎along the northern boundary of the Bozqush Mountains. Evidence of the modern NW-SE stress regime is found at five sites measured within the Quaternary detrital deposits in the western part of the study area. At the other ‎sites, evidence of the older stress regime, with NE-SW direction of maximum horizontal ‎compression is obtained. Also, the systematic deflection of the stream channels, especially in the eastern part of the region, ‎indicates the sinistral displacement along the EW-striking faults, consistent with the old ‎stress regime in the region. Evidence of dextral deflection was observed along few EW-striking faults cutting the Quaternary deposits only in the western parts of the region. Therefore, ‎by comparing these kinematic data and morphotectonic evidences with those reported from the southern flank of the Bozqush Mountains, it can be concluded that the modern deformation is dominantly absorbed along the splay faults in the southern flank of the Bozqush.‎

 

​Key Words: North Tabriz fault, Modern stress state, NW Iran, Northern flank of Bozqush Mountains, Stress inversion

How to cite: Nasiri, A. and Aflaki, M.: ​Studying the active tectonic in the northern flank of the Bozqush Mountains, NW Iran, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1972, https://doi.org/10.5194/egusphere-egu22-1972, 2022.

EGU22-2092 | Presentations | TS4.1

Rapid large-amplitude vertical motions generated by 3D subduction slab roll-back in the Valencia Trough, Western Mediterranean 

Penggao Fang, Julie Tugend, Geoffroy Mohn, Nick Kusznir, and WeiWei Ding

        The Cenozoic geodynamic evolution of the Western Mediterranean is complex comprising subduction, slab roll-back, back-arc extension, collision, and lithosphere delamination. We investigate the subsidence of a regionally observed unconformity in the Valencia Trough of the Western Mediterranean, here referred to as the Miocene Unconformity, which separates Mesozoic from latest Palaeogene to Neogene sediments. The mechanisms controlling its subsidence are poorly understood.

        We show, using a dense grid of seismic reflection data, well data and 3D flexural backstripping, that the Miocene Unconformity in the SW Valencia Trough subsided by more than 1.5 km to the present day at an average rate of 90 m/Myr. The absence of Cenozoic extensional faults affecting the basement shown by seismic data indicates that this rapid subsidence is not caused by Cenozoic rifting or remaining Mesozoic post-rift thermal subsidence. Neither can this subsidence be explained by subduction dynamic subsidence or flexural loading related to the thin-skin Betic fold and thrust belt which only affects subsidence observed near the deformation front.

        We interpret the 1.5 km subsidence of the Miocene Unconformity as the collapse of a back-arc transient uplift event. Erosion during this uplift, resulting in the formation of the Miocene Unconformity, is estimated to exceed 4 km. Transient uplift was likely caused by heating of back-arc lithosphere and asthenosphere, combined with mantle dynamic uplift, both caused by segmentation of Tethyan subduction resulting in slab tear. Subsidence resulted from thermal equilibration and the removal of mantle flow dynamic support Tethyan subduction slab roll-back. We propose that our observations and interpretation of rapid back-arc km-scale uplift and collapse have global applicability for other back-arc regions experiencing subduction segmentation and slab tear during subduction slab roll-back.

How to cite: Fang, P., Tugend, J., Mohn, G., Kusznir, N., and Ding, W.: Rapid large-amplitude vertical motions generated by 3D subduction slab roll-back in the Valencia Trough, Western Mediterranean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2092, https://doi.org/10.5194/egusphere-egu22-2092, 2022.

EGU22-2986 | Presentations | TS4.1

This Rift is on Fire: Volcano-Tectonic Evolution of the Christiana-Santorini-Kolumbo volcanic field, Aegean Sea 

Jonas Preine, Christian Hübscher, Jens Karstens, Emilie Hooft, and Paraskevi Nomikou

Many of the most hazardous volcanoes lie in rift systems, where tectonics often seems to exert control on magma emplacement. However, our current knowledge of the interplay between volcanism and tectonics is immature due to the lack of observations on geological time scales. Located in the southern Aegean Sea, the Christiana-Santorini-Kolumbo (CSK) volcanic field lies in a prominent continental rift zone caused by back-arc extension along the Hellenic Arc. Covered by numerous geophysical surveys, this area offers the unique possibility to reconstruct a volcanic rift in time and space. Previous studies have revealed that the CSK volcanic field developed during four distinct volcanic phases, which initiated in the Pliocene and only recently matured to form the vast Santorini edifice. Here, we combine P-wave velocity tomography models and high-resolution reflection seismic data to reveal the internal architecture and the spatio-temporal evolution of the rift basins as well as their relation to the evolution of the CSK volcanoes. Our joint analysis reveals a distinct NE-SW-directed horst-structure separating the volcanic rift into a volcanically active northwestern zone and a volcanically inactive southeastern zone. Using a refined seismo-stratigraphic framework of the internal architecture of the rift basins, we identify four distinct phases of the rift system that correspond to the volcanic phases of the CSK field. These phases reflect the gradual development of a Pliocene-Pleistocene NE-SW oriented fault system overprinting an older Miocene-Pliocene ESE-WNW oriented fault system. The latest volcanic phase, during which volcanism focussed on Santorini and became highly explosive, corresponds to a distinct shift in the tectonic behavior of the rift system after which enhanced subsidence at the Santorini-Anafi and Amorgos faults occurred that was rapidly filled up by thick volcano-sedimentary deposits. We conclude that the volcanism of the CSK field is fundamentally controlled by NE-SW-directed rifting, which lies parallel to the Pliny and Strabo trends of the southeastern Hellenic Arc. This volcanic system is bounded to the southeast by the Akrotiri-Anhydros horst, which seems to be a deep-rooted structural boundary for the volcanic plumbing system. The shift from ESE-WNW directed faulting to NE-SW directed faulting is an indication that the dominant direction of slab-rollback driving the extension of the CSK rift shifted from the southwestern to the southeastern Hellenic Arc with Santorini lying at the hinge of these trends.

How to cite: Preine, J., Hübscher, C., Karstens, J., Hooft, E., and Nomikou, P.: This Rift is on Fire: Volcano-Tectonic Evolution of the Christiana-Santorini-Kolumbo volcanic field, Aegean Sea, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2986, https://doi.org/10.5194/egusphere-egu22-2986, 2022.

Crustal deformation and seismic activity in the Levant is mainly related to the interplate Dead Sea Fault (DSF) and the intraplate Carmel-Gilboa Fault System (CGFS). In this study we analyze the interseismic deformation along these fault systems using 23 years of GPS measurements obtained from 209 campaign and 60 continuous stations. This GPS dataset is the longest record and the densest dataset for the DSF and the Levant region. We use this dataset to investigate the spatial variations of slip and creep rates along the southern and central sections of the DSF and the CGFS. Our inversion model results indicate that part of the tectonic motion is transferred from the DSF to the CGFS. We find that the left-lateral strike-slip motion along the DSF decreases in a rate of 0.9±0.4 mm/yr, from 4.8±0.3 mm/yr south to the intersection with the CGFS, to 3.9±0.4 mm/yr north to this intersection. Along the CGFS the left-lateral strike-slip motion ranges between ~0.3-0.5 mm/yr and the extension rate between ~0.6-0.7 mm/yr, indicating a total slip rate vector of 0.8±0.4 mm/yr in the DSF direction, in agreement with the reduction of slip rate along the DSF near the intersection with the CGFS. Shallow creep is found along the southern and central sections of the Dead Sea basin and the northern Jordan Valley section of the DSF, with creep rates of 3.4±0.4 and 2.3±0.4 mm/yr, respectively. These creeping sections were identified as areas with thick salt layers at the shallow subsurface. We suggest that shallow creep behavior along the DSF is govern by the presence and mechanical properties of the salt layers, which probably allows plastic deformation and the transition to velocity strengthening at the shallow subsurface and promotes creep.

How to cite: Hamiel, Y. and Piatibratova, O.: Spatial variations of slip and creep rates along the Dead Sea Fault and the Carmel-Gilboa Fault System, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3591, https://doi.org/10.5194/egusphere-egu22-3591, 2022.

EGU22-3939 | Presentations | TS4.1

Timing of rock-uplift and of the North Anatolian Fault development in the Central Pontides 

Simone Racano, Taylor Schildgen, and Paolo Ballato

The Central Pontide orogenic belt marks the northern margin of the Central Anatolian Plateau and is the result of several geodynamic processes, including the subduction of the Neo-Tethys crust, the opening of the Black Sea, the continental collision between the southern Eurasian margin and the Anatolide-Tauride block, and the development of the North Anatolian Fault (NAF). Transpressional deformation and crustal thickening along the North Anatolian fault zone are thought to have generated rock-uplift rates of 0.2 – 0.3 km/Myr since ca. 400 ka within the Central Pontides based on Quaternary marine and river terraces. Moreover, data from low-temperature thermochronology suggest that an enhanced exhumation phase in the Central Pontides occurred within the last 11 Mya. However, the precise onset of this faster uplift phase, which likely reflects the timing of the development of the NAF in the Central Pontides, is poorly constrained.

In this work we define the spatiotemporal pattern of rock-uplift rates within the Central Pontides over the last ca. 10 Myr by performing linear inversions of river profiles that drain the northern, external margin of the Central Pontides. We analyze 19 different catchments that drain from the Sinop Range to the Black Sea, first applying a non-dimensional inversion on the chi-plots of the selected stream channels. We then use 21 new basin-averaged denudation rates derived from 10Be concentrations in river sands to calibrate an erodibility parameter, which we use in turn to scale our chi-transformed river profiles. Our results document an increase in rock-uplift rates after 8 Ma, with peak uplift rates of around 0.15 – 0.25 km/Myr occurring between 4 and 2 Ma. Moreover, the spatiotemporal pattern of uplift suggests that faster rock uplift started first in the eastern part of the Sinop Range and migrated westward over a period of ca. 2 to 2.5 Myr. Overall, these results provide important new constraints on the timing of topographic development in the Central Pontides and the westward migration of the NAF from eastern Turkey.

How to cite: Racano, S., Schildgen, T., and Ballato, P.: Timing of rock-uplift and of the North Anatolian Fault development in the Central Pontides, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3939, https://doi.org/10.5194/egusphere-egu22-3939, 2022.

The origin and tectonic evolution of the Western Mediterranean region, specifically the Gibraltar Arc system, is the result of a complex geodynamic evolution involving the convergence of the Eurasia and Africa plates and the dynamic impact of the Gibraltar slab observed in tomographic studies. Although geologic and geophysical data collected in the last few years have greatly increased our knowledge of the Gibraltar Arc region, it is still unclear the mechanical links between the Gibraltar slab and the past deformation of the overriding Alboran lithosphere as well as present-day motion shown in detailed GPS observations. In this work, we use the code ASPECT to model the geodynamic evolution of the Alboran slab in 2D over the last 20 million years. The initial model setup simulates a vertical WE section at a latitude of about 36oN and represents the situation at 20 Ma, when the trench had already fully rotated to the southwest and the predominantly westward rollback of the Gibraltar slab started taking place. We conduct a parametric study varying the rheological parameters and the initial slab properties (dip angle and length) to properly fit the robust current slab features, particularly, its position and its curved morphology extending eastward. We show how after 20 Myr of model evolution, i.e. at present time, the slab pull appears to have a still significant influence on surface velocities. We find a westward surface motion in the Gibraltar arc caused by the negative buoyancy of the slab. These velocities increase westwards from 1 to 4 mm/yr consistently with geodetic observations. Our models roughly reproduce the Alboran basin evolution, initially developing the West Alboran Basin and then the East Alboran Basin. Finally, preliminary 3D models further support these results and properly the main trends of the coupled dynamics of the Gibraltar slab and Alboran basin evolution during the last 20 Myr.

How to cite: Gea, P. J., Negredo, A., and Mancilla, F. D. L.: The Gibraltar slab dynamics and its influence on past and present-day Alboran domain deformation: Insights from thermo-mechanical numerical modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4234, https://doi.org/10.5194/egusphere-egu22-4234, 2022.

EGU22-5227 | Presentations | TS4.1

Present strain partitioning in SE Spain. Insights from CGNSS data 

Ivan Martin-Rojas, Alberto Sánchez-Alzola, Ivan Medina-Cascales, María Jesús Borque, Pedro Alfaro, and Antonio Gil

SE Iberia Tectonics is presently dominated by the NNW-SSE convergence between the Eurasian and Nubian plates. Farther east, the eastern Spanish coast and the Valencia Trough are dominated by ENE-WSW extension related to thermal subsidence. This extension has been interpreted as the final stage of abort rift responsible for the ENE motion of the Balearic promontory. Our data from 11 CGNSS stations permit us to discuss the deformation partitioning in SE Iberia related to the two abovementioned processes.

We identify three kinematic domains: a relatively stable domain, a domain moving towards NNW and undergoing NNW-SSE shortening, and a third domain relatively moving towards ENE and experiencing ENE-WSW extension. Our results indicate that plate convergence-related NNW-SSE shortening is mainly absorbed by the Eastern Betic Shear Zone (EBSZ), in agreement with previous studies, but also show that a significant fraction of this shortening is accommodated south of the EBSZ.

We also identify and quantify for the first time ENE-WSW extension northeast of the EBSZ. We propose that this extension could be absorbed by basement normal faults whose surface expression is obscured due to decoupling of deformation between the basement and the cover. Our results shed light on the tectonic puzzle of SE Spain.

How to cite: Martin-Rojas, I., Sánchez-Alzola, A., Medina-Cascales, I., Borque, M. J., Alfaro, P., and Gil, A.: Present strain partitioning in SE Spain. Insights from CGNSS data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5227, https://doi.org/10.5194/egusphere-egu22-5227, 2022.

EGU22-5335 | Presentations | TS4.1

Delayed lithosphere tearing along STEP Faults 

Taco Broerse, Rob Govers, and Ernst Willingshofer

Tearing of the lithosphere at the lateral end of a subduction zone is a consequence of ongoing subduction. The location of active lithospheric tearing is known as a Subduction-Transform-Edge-Propagator (STEP). The transcurrent plate boundary system lengthens with time and is referred to as the STEP Fault. Lithospheric tearing was taken to start at the trench in the classical STEP model of Govers and Wortel (2005). They show that active STEPs and STEP Faults can be found alongside many subduction zones. However, recent seismicity studies show results near the active STEPs that are difficult to reconcile with the classical STEP model: there is significant and deep seismicity along the STEP Fault near to the west of Trinidad in the southeast Caribbean; a Wadati-Benioff zone perpendicular to the Pliny-Strabo trenches (the STEP Fault) in the eastern Mediterranean reaches 180 km depth; STEP Fault perpendicular earthquake slip vectors are observed along the northern termination of the South Sandwich trench. We seek to understand these discrepancies by studying the tearing process.  

We show results of new physical analog lab models that aim to elucidate what controls lithospheric tearing and the resulting geometry of the lithospheric STEP. We study the ductile tearing in the process of STEP evolution, which is dynamically driven by the buoyancy of the subducting slab. In our experiments, the lithosphere as well as asthenosphere are viscoelastic media in a free subduction setup. A stress-dependent rheology plays a major role in localization of strain in tearing processes of lithosphere such as slab break-off. 

We find that complete tearing of the lithosphere typically occurs later than in the classical model, at 100-150 km depth. The slab is consequently highly curved near the lateral end of the trench. However, not all STEPs show evidence for such delay, e.g., the north end of the Tonga trench. In our model experiments we therefore investigate the influence of age and integrated strength of the lithosphere and its contrasts across the passive margin, on the timing, depth, and the degree of localization of the tearing process. Furthermore, we relate the tearing at depth to deformation at the surface along and across the STEP fault and we discuss potential consequences for STEP evolution for a number of subduction zones worldwide. Delayed lithospheric tearing explains the observations qualitatively. 

How to cite: Broerse, T., Govers, R., and Willingshofer, E.: Delayed lithosphere tearing along STEP Faults, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5335, https://doi.org/10.5194/egusphere-egu22-5335, 2022.

EGU22-5475 | Presentations | TS4.1

Insights into the 3D lithospheric structure below the Sea of Marmara region from seismic tomography and forward gravity modeling 

Naiara Fernandez, Magdalena Scheck-Wenderoth, Judith Bott, Mauro Cacace, and Ershad Gholamrezaie

The North Anatolian Fault Zone (NAFZ) extends for about 1500 km in the Eastern Mediterranean region, from eastern Anatolia to the northern Aegean. The NAFZ is characterized by strong and frequent seismic activity, increasing the seismic hazard in the region. In the Sea of Marmara area (NW Turkey), the North Anatolian Fault splits into three main branches. The northern branch of the fault, the Main Marmara Fault (MMF), has produced several major earthquakes (M7+) in the past, with a recurrence time of about 250 years. At present, there is a 150 km seismic gap along the MMF which has not ruptured since 1766. The observed fault segmentation, with creeping and locked segments, is indicative of along-strike variability in the fault strength along the seismic gap.

Previous modeling studies in the Sea of Marmara have revealed how crustal heterogeneities effectively affect the thermal and mechanical states of the lithosphere and can likely explain the observed fault segmentation in the area. Therefore, constraining the 3D structure of the deeper crust and upper mantle below the Sea of Marmara is crucial to better assess the mechanical stability of the fault and the possible seismic hazards in the area. In this study, we make use of seismic tomography models and forward gravity modelling to gain insights into the 3D lithospheric structure below the Sea of Marmara. Two tomographic models are used to compute a 3D density model of the area relying on two distinct approaches for the crust and the lithospheric mantle. The results showcase a heterogeneous and rather complex crustal density distribution in the study area[m1] . The 3D density distributions are used in a second step to forward model the gravity response. The results from this new tomography-constrained 3D gravity modelling are then compared to published gravity data and iteratively corrected to fit the overall gravity signals. The final 3D lithospheric-scale density model of the study area will be the basis for thermo-mechanical modeling experiments aimed at improving our current understanding of the present-day geomechanical state of the Sea of Marmara and the MMF and its implications for the seismic hazard of the region.

How to cite: Fernandez, N., Scheck-Wenderoth, M., Bott, J., Cacace, M., and Gholamrezaie, E.: Insights into the 3D lithospheric structure below the Sea of Marmara region from seismic tomography and forward gravity modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5475, https://doi.org/10.5194/egusphere-egu22-5475, 2022.

EGU22-5479 | Presentations | TS4.1

Kinematic and tectonic analysis of the Baza and Galera Fault (S Spain). Insights from GNSS data 

Frank García-Tortosa, Pedro Alfaro, Alberto Sánchez-Alzola, Ivan Martin-Rojas, Jesus Galindo-Zaldívar, Manuel Avilés, Angel Carlos López Garrido, Carlos Sanz de Galdeano, Patricia Ruano, Francisco Jose Martínez-Moreno, Antonio Pedrera, Maria Clara de Lacy, Maria Jesus Borque, Ivan Medina-Cascales, and Antonio Jose Gil

We here discuss the results of a local GNSS episodic network from the Baza sub-Basin (S Spain). This network including six sites, was established in 2008 and has been measured seven times since then. Our data permit us to present the first short-term slip rates for the two active faults in this area. The main active structure is the normal Baza Fault. We estimate slip rates for this fault ranging between 0.3±0.3 mm/yr and 1.3±0.4 mm/yr. For the strike-slip Galera Fault, we quantify the slip rate as 0.5±0.3 mm/yr. These values are higher than previously reported long-term slip rates. We postulate that the discrepancy for the Baza Fault between short-term and long-term slip rates could indicate that the fault is presently in a period with a displacement rate higher than the mean of the magnitude 6 seismic cycle. Moreover, the velocity vectors that we obtained also show the regional tectonic significance of the Baza Fault, as this structure accommodates one-third of the regional extension of the Central Betic Cordillera.

Our results also show that the Baza and Galera Faults are kinematically coherent and they divide the Baza sub-Basin into two tectonic blocks. This points to a likely physical link between the Baza and Galera Faults; hence, a potential complex rupture involving both faults should be considered in future seismic hazard assessment studies.

How to cite: García-Tortosa, F., Alfaro, P., Sánchez-Alzola, A., Martin-Rojas, I., Galindo-Zaldívar, J., Avilés, M., López Garrido, A. C., Sanz de Galdeano, C., Ruano, P., Martínez-Moreno, F. J., Pedrera, A., de Lacy, M. C., Borque, M. J., Medina-Cascales, I., and Gil, A. J.: Kinematic and tectonic analysis of the Baza and Galera Fault (S Spain). Insights from GNSS data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5479, https://doi.org/10.5194/egusphere-egu22-5479, 2022.

EGU22-5691 | Presentations | TS4.1

Reconstruction of tectonically driven Quaternary fluvial dynamics of the Western Kura Fold-Thrust Belt (Eastern Caucasus, Georgia) 

Lasha Sukhishvili, Giorgi Boichenko, Giorgi Merebashvili, Zurab Javakhishvili, Adam Forte, and Tea Godoladze

Since the Plio-Pleistocene, southward migration of shortening in the Eastern part of the Greater Caucasus (GC) into the Kura foreland basin has formed the Kura fold–thrust belt (KFTB) and Alazani piggyback basin between the GC and KFTB, modifying the drainage network within the southern foreland. The northern, eastern and south-eastern flanks of the Western KFTB (Gombori range) expose the predominantly alluvial Alazani series, while the central (highest) part of the range is covered by Tsivi suite. The base of the Alazani series is estimated to be 2.7-2.5 Ma and deposition spanned the Akchagyl and Apsheronian regional stages. The KFTB likely initiated during the Akchagyl-Apsheronian period, and thus the paleocurrents of the alluvial Alazani series sediments represent potential archives for tracking resulting drainage reorganization within the foreland. Previous measurements of paleocurrents from the Alazani series revealed a reversal from south to north flow directions, but the measurements were limited to the northern flank of the Gombori range. Here we present new observations from the central and southern flanks of the Gombori. Results from the eastern and southeastern regions are consistent with the currents from the northern flank, but paleocurrents from the Tsivi suite are more complex and raises additional questions regarding its depositional context and age. The new results help to build a more complete picture of fluvial dynamics driven by Quaternary tectonic deformations within the GC foreland.

How to cite: Sukhishvili, L., Boichenko, G., Merebashvili, G., Javakhishvili, Z., Forte, A., and Godoladze, T.: Reconstruction of tectonically driven Quaternary fluvial dynamics of the Western Kura Fold-Thrust Belt (Eastern Caucasus, Georgia), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5691, https://doi.org/10.5194/egusphere-egu22-5691, 2022.

EGU22-6407 | Presentations | TS4.1

Morphological and paleoseismic evidence of surface faulting in the coastal Zagros, southwestern Iran 

Aram Fathian, Hamid Nazari, Mohammad Ali Shokri, Morteza Talebian, Manouchehr Ghorashi, and Klaus Reicherter

The Zagros Mountains accommodate intense seismicity due to the ongoing deformation; however, surface faulting has been rarely observed and/or documented. The earthquakes of Furg (November 6th, 1990) and Qir-Karzin (April 10th, 1972) are unique events in the Zagros associated with a surface rupture. We use tectonic geomorphology and paleoseismology to document a previously unknown outcropped fault within the Zagros. This ~ 20 km fault zone lies between the Khormuj and Khaki anticlines, where the Simply Folded Belt (SFB) of the Zagros is physiographically known as the coastal Zagros as well. The Khormuj anticline, located in the northeast of the city of Khormuj, was previously linked to the Main Front Fault (MFF) on the southern limb of the anticline. Further to the south, the oblique-slip Khormuj fault zone with a strike of N120°–N125° cut the Quaternary sediments and displaced the streams and ridges laterally and vertically. Opposite to the dip of the MFF, the Khormuj fault dip is inclined to the southwest—approximately 75°—where the southern block is uplifted and marks an obvious trace on the ground. We carried out a kinematic GPS survey along the deflected ridges to measure the horizontal and vertical components. Our observations indicate significant dextral strike-slip displacements compared to the dip-slip offset. We observed a sequence of fluvial risers in three different levels along the Khormuj fault. We additionally studied a paleoseismological trench perpendicular to the Khormuj fault scarp evidencing at least two paleoearthquakes. The OSL age of the bottom of the colluvium wedge correlated with the older event indicates the latest event is younger than 25±8 ka considering the fault cuts these deposits up to the ground surface.

How to cite: Fathian, A., Nazari, H., Shokri, M. A., Talebian, M., Ghorashi, M., and Reicherter, K.: Morphological and paleoseismic evidence of surface faulting in the coastal Zagros, southwestern Iran, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6407, https://doi.org/10.5194/egusphere-egu22-6407, 2022.

EGU22-7451 | Presentations | TS4.1

A revision of the main active fault systems of the Alboran Basin: their significance in plate tectonics and a first appraisal of its seismogenic and tsunamigenic potential. 

Laura Gómez de la Peña, César R. Ranero, Guillermo Booth-Rea, José Miguel Azañón, Eulàlia Gràcia, Francesco Maesano, Roberto Basili, and Fabrizio Romano

The Alboran Basin is located in the westernmost Mediterranean Sea. This basin was formed during the Miocene, and since the late Miocene, has been deformed due to the Iberia – Africa tectonic plates convergence, producing the contractive reorganization of some structures at the basin. Thus, the Alboran Basin is a seismically active area, which hosts the plate boundary between the European and African tectonic plates. This plate boundary has been traditionally considered a wide deformation zone, in which several small faults are accommodating the deformation.

Based on a modern set of active seismic data, we were able for the first time to quantify the total slip accommodated by the most prominent tectonic structures of the area, late Miocene - early Pliocene in age. Our results show that the estimated total slip accommodated by the main fault systems may be similar (with error bounds) to the estimated plate convergence value since the Messinian time (~24 km). Thus, slip on that faults may have accommodated most of the Iberian – African plate convergence during the Plio-Quaternary, revealing that the contractive reorganization of the Alboran basin is focused on a few first-order structures that act as lithospheric boundaries, rather than widespread and diffuse along the entire basin.

These results have implications not only for kinematic and geodynamic models, but also for seismic and tsunami hazard assessments. Using the most complete dataset until the date, we performed a revision of the geometry and characteristics of the main fault systems offshore. Based on this data, we perform a first appraisal of the seismogenic and tsunamigenic potential of the main fault systems offshore. Our simulations show that the seismogenic and tsunamigenic potential of the offshore structures of the Alboran Basin may be underestimated, and a further characterization of their associated hazard is needed.

How to cite: Gómez de la Peña, L., R. Ranero, C., Booth-Rea, G., Azañón, J. M., Gràcia, E., Maesano, F., Basili, R., and Romano, F.: A revision of the main active fault systems of the Alboran Basin: their significance in plate tectonics and a first appraisal of its seismogenic and tsunamigenic potential., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7451, https://doi.org/10.5194/egusphere-egu22-7451, 2022.

EGU22-7780 | Presentations | TS4.1

The vertical movement of Karpathos: Competing hypotheses  

Violeta veliz borel, Onno Oncken, Vasiliki Mouslopoulou, John Begg, and Johannes Glodny

Karpathos is a roughly north-south oriented island that emerges between Crete and Rhodes in the forearc of the eastern Hellenic subduction system. It extends for ~60 km to the north of the 40 km contour of the plate interface depth. Further, the northern part of the island is confined to a N-S trending Horst bounded by two large normal faults that shape the seafloor off both, the eastern and western shore.  Furthermore, many normal faults, mainly in the north, strike parallel to the Horst and shape the topography onshore. Given the location and the structural configuration of the island, we expect that multiple processes are reflected in both the sedimentary and morphological record of vertical movement. Marine terraces and paleo-cliffs are observed all around the island recording its vertical movements over the last ~1 Ma. Moreover, sedimentary basins in the southern and central parts of the island are excellent archives of long-term uplift interrupted by subsidence over the last ~4.5 Ma. Twenty-five samples were collected at elevations between 1 and ~310 masl. We have gathered six (n=6) age/elevation data-points obtained by Sr-isotope dating, and nineteen (n=19) age/elevation data-points by radiocarbon dating. We explored the likelihood of different hypotheses on what drives the uplift:  whether it is driven by upper-crust normal faults, megathrust earthquakes, underplating, or a combination of these phenomena. We present preliminary results on both the temporal and spatial fluctuations of the vertical movement of Karpathos.

How to cite: veliz borel, V., Oncken, O., Mouslopoulou, V., Begg, J., and Glodny, J.: The vertical movement of Karpathos: Competing hypotheses , EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7780, https://doi.org/10.5194/egusphere-egu22-7780, 2022.

EGU22-7890 | Presentations | TS4.1

Knickpoints and faulted alluvial fans: evidence of orogen parallel active extension related to delamination in the Western Betics 

Marcos Moreno-Sanchez, Daniel Ballesteros, Guillermo Booth-Rea, José Vicente Pérez-Peña, Carlos Pérez-Mejías, Cristina Reyes-Carmona, José Miguel Azañón, Jorge P. Galve, and Patricia Ruano

We present the first results of the MORPHOMED project, in order to deepen the chronology, uplifting rate, and tectonic forcing of different sectors of the Betic Cordillera since the Pliocene. Our initial morphotectonic analysis in the Western Betics, at the active termination of the Betic dextral STEP fault, highlights the location of active orogen-parallel normal faults cutting Pliocene marine sediments, uplifted above 600 masl, and Quaternary alluvial fans. The morphometric study we carried out includes normalized river steepness (ksn) and other geomorphic indices calculated in GIS using our own code designed in python. The fieldwork developed comprises the identification of uplifted Pliocene marine deposits, faulted alluvial fans and remnants of uplifted planation surfaces. The alluvial fans are related to travertine deposits older than 350 ka, which would be associated with hot springs. Geochronological studies involve previous and new U-Th dating on travertines and speleothems from caves in the high areas. The preliminary morphometric analyses reveal the occurrence of knickpoints that coincide with normal faults affecting marine Pliocene deposits and alluvial fans. These fans show vertical displacement of more than 20 m and their age remains unknown albeit the associated travertines are being dated. These results support previous works concerning of active tectonics in the Central and Western Betic Cordillera and they will serve to define new active faults, driving tectonic uplift of the Western Betics, which are the key to understand the landscape evolution forced probably by deep mantle rooted tectonics like slab tearing and edge delamination.

How to cite: Moreno-Sanchez, M., Ballesteros, D., Booth-Rea, G., Pérez-Peña, J. V., Pérez-Mejías, C., Reyes-Carmona, C., Azañón, J. M., Galve, J. P., and Ruano, P.: Knickpoints and faulted alluvial fans: evidence of orogen parallel active extension related to delamination in the Western Betics, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7890, https://doi.org/10.5194/egusphere-egu22-7890, 2022.

The occurrence of earthquake-repeaters, i.e. co-located seismic events of comparable magnitude with highly similar waveforms breaking the same fault patch with an almost identical mechanism, is generally regarded as an indication that the fault surrounding the earthquake asperity is (aseismically) creeping. Earthquake repeaters can either occur during transient loading, e.g. within the afterslip of large earthquakes, or during the constant tectonic loading of tectonic faults. In this study we consider the latter.

The Main Marmara Fault (MMF) belongs to the western part of the North Anatolian Fault Zone (NAFZ) between the Anatolian and Eurasian plates and runs close to the population centre of Istanbul below the Marmara Sea. While the main NAFZ branches to the east and west of the MMF ruptured in M>7 earthquakes in the last century, the MMF itself is regarded as a seismic gap with the potential to host an M>7 event in the near future. Knowledge about the amount of aseismic creep of the off-shore MMF strand is important for a better seismic hazard assessment for the city of Istanbul and is heavily debated.

Building on earlier studies that identified repeating earthquakes in the western part of the MMF, we investigate a newly compiled seismicity catalogue of the Sea of Marmara for repeating events along the complete MMF. The catalogue spans the time period 2006-2020, comprises almost 14,000 events in the magnitude range M0.3-M5.7 and was compiled from regional permanent stations operated by AFAD and KOERI. Phase onset times were automatically picked with a two-step procedure using higher-order statistics and an AIC-representation of the waveforms for crude and fine-tuned estimation of the P- and S-onsets. The resulting onset-times were used in the Oct-tree location algorithm of the probabilistic NLLoc software using a regional velocity model and station corrections to obtain the final hypocentres.

To search for earthquake repeaters, we divide the MMF into overlapping segments and perform a station-wise cross-correlation analysis for all available event waveforms in each segment. Correlated waveforms start 1 s before the P-wave arrival and include the complete waveform including the S-wave coda. Waveforms were bandpass filtered between 2 and 20Hz to retain a rather wide frequency spectrum. We apply strict selection criteria and identify repeating events only as those with a normalized cross-correlation coefficient larger than 0.9 at at least 3 stations and a temporal separation of more than 30 days to exclude bursts of highly similar events in aftershock sequences or earthquake swarms.

The highest density of repeating earthquakes is found below the western Marmara Sea (Central Basin and Western High) with a systematic decrease of repeaters towards the east (Kumburgaz Basin) and none at all in the presumably locked Princess Islands section of the MMF immediately south of Istanbul. These results for the first time provide a consistent image of the amount of creep along the entire overdue Marmara section of the NAFZ derived from permanent onshore stations refining earlier results obtained from individual spots using local seafloor deployments.

How to cite: Becker, D., Martínez-Garzón, P., Wollin, C., and Bohnhoff, M.: Systematic variations of fault creep along the Marmara seismic gap, north-western Turkey, based on the observation of earthquake repeaters obtained from a high-resolution regional earthquake catalogue, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8142, https://doi.org/10.5194/egusphere-egu22-8142, 2022.

EGU22-8675 | Presentations | TS4.1

Subduction hints from the northeastern Mediterranean Sea 

Nicolò Bertone, Lorenzo Bonini, Eugenia Colin, Anna Del Ben, Giuseppe Brancatelli, Angelo Camerlenghi, Edy Forlin, and Gian Andrea Pini

The eastern Mediterranean is shaped by the interaction between the African, Arabian, and Eurasian plates resulting in a complex tectonic framework. The Hellenic subduction is well documented and studied but, the northeast corner of the eastern Mediterranean Sea remains enigmatic. It is a tectonically active region where different plate boundary conditions coexist (i.e., oceanic subduction, continental collision, extension, and strike-slip movements). An active and tsunamigenic system has been interpreted west and east of Cyprus by using deep seismic reflection lines. Vintage deep-penetrating seismic reflection profiles of the Mediterranean Sea project (MS project) - acquired during the ’70 - were re-analyzed and merged with a synthesis of available subsurface data from the scientific literature. This study focuses on two transects (MS53 and MS56) that cross the major offshore structures (i.e., Florence Rise, Latakia Ridge, and Kyrenia Ridge) from north to south. The western transect (MS53) shows the Herodotus oceanic crust subducting northward beneath the Eurasian plate. The Florence Rise is the leading edge of the system, and the Antalya Basin is its forearc basin. Close to the Turkish coast, a buried block seems to act as a backstop for the offshore system, and north of it, some out-of-sequence thrusts have been interpreted. The strain is partitioned between the Florence Rise and the Taurides front. The eastern transect (MS56) crosses the Latakia Ridge, i.e., the northern boundary of the Levant Basin, where shortening is greater than in the western area. The seismic line continues northward into the Cyprus – Latakia Basin, crossing the Kyrenia Ridge, and reaching the Turkish coast. On the seismic section, we interpreted the Mesozoic subduction front now hindered by strike-slip movements on the Latakia Ridge. Another prominent transpressive structure is the Kyrenia Ridge, which is interpreted as an active structure with a well-imaged thrust system in front of it. The seismic sections were depth converted to provide a regional geologic model for the northeastern Mediterranean Sea. Active subduction fronts, which are only partially imaged, were structurally modeled and then crosschecked with previous studies to better constrain their geometry. In the northeastern Mediterranean Sea, a plate boundary is buried offshore with active subduction west of Cyprus and mainly transpressional tectonics to the east. A better understanding of its nature and kinematics would be useful to assess the tsunami hazard in this area.

How to cite: Bertone, N., Bonini, L., Colin, E., Del Ben, A., Brancatelli, G., Camerlenghi, A., Forlin, E., and Pini, G. A.: Subduction hints from the northeastern Mediterranean Sea, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8675, https://doi.org/10.5194/egusphere-egu22-8675, 2022.

EGU22-9537 | Presentations | TS4.1

New constraints on the kinematics of the western Sinai Microplate: geodynamic implications 

Roi Granot, Oded Katz, Mor Kanari, Orit Hyams, and Yariv Hamiel

The tectonic nature of the Sinai Microplate's western boundary is clouded with uncertainties. Early studies suggested that the western edge of Sinai is fully connected to the African Plate, thus concluding that Sinai is a sub-plate. Later, bathymetric analyses of prominent lineated faults straddling across the western edge of the Levant Basin have suggested that, in fact, this area is a plate boundary that accommodates dextral motion between the African Plate and the Sinai Microplate. However, this inference contradicts geological and geophysical observations across the Gulf of Suez, the southern continuation of the same plate boundary. Here we present preliminary results from a recent geophysical cruise aboard the R/V Bat Galim. We focused our investigation on one of the major faults, oriented in an NW-SE direction (located ~80 km southwest of the Eratosthenes Seamount), creating the plate boundary. We collected high-resolution shallow multichannel seismic reflection data complemented with multibeam bathymetry data. We also acquired two piston cores near the trace of the fault. These observations unravel the shallow three-dimensional structure of the fault system whereby several curved and steeply dipping normal fault segments are splayed from the main fault trace in a westerly direction. These secondary faults display a back-tilted and step-like morphology. This structure is best explained by a sinistral motion acting along the master fault. Independently, we present an updated Africa-Sinai Euler pole based on the motion of GPS stations recorded between 1996 and 2019. The results suggest that Sinai is moving in a northwesterly direction with respect to Africa (1.7-1.9±0.9 mm/yr). Focal mechanism solutions calculated for recent earthquakes occurring in this region (Mw>4.5) agree with the geodetic constraints of a sinistral relative motion.

Overall, these observations suggest that the western boundary of Sinai has been, and still is, accommodated sinistral motion relative to Africa. This conclusion implies that the Sinai Microplate is moving faster with respect to Eurasia relative to the motion of Africa with respect to Eurasia. This, in turn, seems to be in conflict with the notion that subduction of the oceanic lithosphere north of the Sinai Microplate (i.e., east of Cyprus) has recently ceased. We speculate that the downgoing slab might still promote the relatively fast northward motion of Sinai and/or a northward drag force induced by large-scale mantle flow related to the Afar plume could also contribute to the motion of the Sinai Microplate.

How to cite: Granot, R., Katz, O., Kanari, M., Hyams, O., and Hamiel, Y.: New constraints on the kinematics of the western Sinai Microplate: geodynamic implications, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9537, https://doi.org/10.5194/egusphere-egu22-9537, 2022.

EGU22-9541 | Presentations | TS4.1

Slow slip events captured by GNSS  along the Central Section of the North Anatolian Fault 

Jorge Jara, Alpay Ozdemir, Ugur Dogan, Romain Jolivet, Ziyadin Çakir, and Semih Ergintav

Recent observations suggest that seismogenic faults release elastic energy not only during sudden earthquakes but also aseismically. Slow slip can be persistent, lasting for years, or episodic. Aseismic slip is thought to be influenced by the presence/migration of fluids, stress interactions through fault geometrical complexities, or fault material heterogeneities. However, slow slip events have mostly been captured by regional GNSS networks in subduction zones, and the finest details of the nucleation, propagation, and arrest of such events have not been observed yet. Therefore, continental creeping faults are ideal targets for tackling such observational gaps and focusing on the sub-daily behavior of such slow slip events.

 

The central segment of the North Anatolian Fault is known to be creeping at least since the 1950s. This region was struck by the Mw 7.3 Bolu/Gerede earthquake in 1944, and since then, no earthquake of magnitude greater than 6 has been recorded. During the 1960s, aseismic slip was discovered as a wall built across the fault in 1957 was being slowly offset. Geodetic studies (InSAR, GNSS, and creepmeters) focused on capturing and analyzing aseismic slip around the village of Ismetpasa. Creepmeter measurements during the 1980s and 2010s, along with InSAR time series analysis, suggest that aseismic slip occurs episodically rather than persistently. However, no permanent GNSS stations were available close enough to the fault to study the details of such slow slip events.

 

Within the scope of a French-Turkish collaboration, we installed 17 GNSS stations (ISMENET) in 2019 to survey the spatio-temporal evolution of aseismic slip rate and characterize the physical properties of the fault zone. A creepmeter array located in the Ismetpasa village reported the occurrence of a significant slow slip event between December 2019 - January 2020. We analyze the GNSS record to search for small aseismic slip episodes and describe their behavior. We use a combination of Multivariate Singular Spectrum Analysis (MSSA) and Geodetic Template Matching (GTM) to extract the signature of aseismic slip and characterize its source. Results are compared to creepmeter measurements, as well as the historical earthquakes, fault geometrical complexities, and kinematic coupling. Our results confirm that aseismic slip in the region is not permanent. Therefore, even though the aseismic slip rate in the long-term seems to be constant, such a rate might result from the contribution of many aseismic slip episodes as the one detected in this work.

How to cite: Jara, J., Ozdemir, A., Dogan, U., Jolivet, R., Çakir, Z., and Ergintav, S.: Slow slip events captured by GNSS  along the Central Section of the North Anatolian Fault, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9541, https://doi.org/10.5194/egusphere-egu22-9541, 2022.

The Apennine Tyrrhenian margin records the evolutionary steps of the back-arc basin developed at the rear of a E-ward migrating fold-and-thrust belt. As well-documented in literature, the counterclockwise rotation of the Apennines is related to the southward increase of the roll back-related subduction of the Adria slab. This led first to the progressive incorporation of thrust sheets within the Apennine prism in the upper plate and later to its subsequent back-arc extension that is contemporaneous with the continuate inarching of the Apennine front towards the Adriatic and Ionian seas. Uncertainties arise on the structural style and timing in the internal Apennines between the orogenic and post-orogenic stages, that are respectively represented by thrust-sheet implacement, and crustal thinning.

We hereby propose a combined 2D seismic and field data review that allows identifying the geodynamic processes preceding the crustal stretching of the Apennine Tyrrhenian margin with new insights from on- and off-shore seismic lines. In particular, the construction of a new geotraverse across the margin, which is stretched over 100 km between the internal Central Apennines belts and the Pontian escarpment, allows to roughly estimate: i) the Late Miocene - Earliest Pliocene shortening with its change of the basal decollement depth through time; in particular, subsurface data highlighted stacked thrust sheets that were involved in an initial in-sequence propagation with top-to-the-ENE, synchronous to late Tortonian foredeep to wedge-top sedimentation. We also distinguish late backthrusts related to the formation of triangle zones that are more deeply rooted moving to the western chain interior. ii) The amount of crustal stretching and subsidence; Back arc-related orogenic collapse is preceded by initial orogen uplift and erosion in the internal sectors. iii) The onset of at least two magmatic cycles; in this frame, the lateral slab tearing and retreat is tracked by E-rejuvenated volcanic activity in the upper plate along the Volsci Volcanic Field and the Palmarola-Vesuvius lineaments. Those volcano-tectonic trends are favoured by a series of transtensive structures that progressively reflect the arc expansion in the rear. In this frame, the NE-dipping crustal detachment(s) may have played into crustal thinning during the Pliocene, driving and occasionally hampering magma emplacement, while high-angle faults have locally driven monogenetic eruptions. Finally, we report on field and seismic evidence of neo-tectonics, supporting ongoing extension occurring on the margin.

How to cite: Vico, G. and Cardello, G. L.: From thrusting to back-arc extension: seismic structure and field evidence of the Apennine Tyrrhenian margin (Central Italy), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9955, https://doi.org/10.5194/egusphere-egu22-9955, 2022.

EGU22-10062 | Presentations | TS4.1

A re-evaluation of the 5th October 1948 M7.3 Ashgabat earthquake (Turkmenistan) 

Neill Marshall, Richard Walker, Qi Ou, and Christoph Gruetzner

The 1948 M 7.3 Ashgabat earthquake, killing over 38,000 people, occurred in the dextral strike-slip Kopeh Dagh fault zone in the Iran-Turkmenistan border region. Previously, it has been debated which fault(s) it occurred on and whether this earthquake was a thrust/reverse, strike-slip, or multi-fault earthquake, as published focal mechanisms suggest it had a reverse mechanism. We relocated the hypocentre using historical seismograms and present a new strike-slip focal mechanism. We used Pleiades satellite stereo imagery to produce Digital Elevation Models of part of the ruptured area. These data reveal clear strike-slip faults where surface ruptures were mapped in 1948. The earthquake did not rupture the Main Kopeh Dagh fault, but instead these subsidiary faults, highlighting the importance of considering lesser faults in seismic hazard models.

How to cite: Marshall, N., Walker, R., Ou, Q., and Gruetzner, C.: A re-evaluation of the 5th October 1948 M7.3 Ashgabat earthquake (Turkmenistan), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10062, https://doi.org/10.5194/egusphere-egu22-10062, 2022.

EGU22-10145 | Presentations | TS4.1

Coseismic and Postseismic Deformation of the January 24, 2020 Sivrice (Elazig) Earthquake Under the Constrain of Geodetic Observations 

İlay Farımaz, Seda Özarpacı, Alpay Özdemir, M. Hilmi Erkoç, Efe Turan Ayruk, Semih Ergintav, Uğur Doğan, and Ziyadin Çakır

January 24, 2020 Sivrice earthquake (Mw 6.8), which is the largest along the East Anatolian Fault (EAF) over the last century, is providing a wealth of information on the mechanics of transform faulting and for monitoring the different phases of the last seismic cycle. In this study, we aim to estimate coseismic and postseismic surface deformation along the Sivrice earthquake rupture and determine the strain accumulations on Pütürge segment by combining InSAR and GNSS measurements. The area was described one of the major seismic gaps along the EAF and we have started to study from Palu to Sivrice segments of the EAF, since 2015. Near field survey GNSS network has been established since 2015 and measured two times in a year, until 2021. Besides, after the earthquake, we surveyed 60% of near field sites to contain the coseismic field within 2-3 days. This dataset analyzed with continuous GNSS stations around the region to control the far field of the deformation field. Additionally, this dataset is densified by InSAR deformation field. For this purpose, the stack of interferograms have been interpreted from descending orbit Sentinel-1 dataset, composed of 6 days interval SAR acquisitions that starts from January 2020 to June 2020 which covers the earthquake time. As a result, significant differences between the pattern of strain accumulation before and after earthquake are documented with both GNSS and InSAR data. Moreover, the signature of the postseismic deformations is presented for 6 months.  

This study was supported by TUBITAK 1001 project no. 114Y250 and 118Y435.

Keywords: Sivrice earthquake, EAF, coseismic, postseismic, InSAR, GNSS

How to cite: Farımaz, İ., Özarpacı, S., Özdemir, A., Erkoç, M. H., Ayruk, E. T., Ergintav, S., Doğan, U., and Çakır, Z.: Coseismic and Postseismic Deformation of the January 24, 2020 Sivrice (Elazig) Earthquake Under the Constrain of Geodetic Observations, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10145, https://doi.org/10.5194/egusphere-egu22-10145, 2022.

EGU22-10193 | Presentations | TS4.1

Determining Strain Accumulation Along NAF with Block Modelling 

Efe Turan Ayruk, Seda Özarpacı, Alpay Özdemir, Volkan Özbey, Semih Ergintav, and Uğur Doğan

The North Anatolian Fault (NAF) is a one of the major dextral strike-slip faults of Turkey which forming the boundary between the Eurasian - Anatolian plates. From 1939 to 1999, significant earthquakes occurred as showing a westward migration. Several studies are being conducted due to this seismic activity along the NAF. However, none of these are sufficiently dense to understand the behaviour of the fault. Here we present our block modelling results obtained from combine that published GNSS velocity datasets to determine strain accumulation along the NAF with TDEFNODE software (McCaffrey,1995). Our study area separates to 3 blocks, starts from east of the Sapanca Lake and includes the Karliova Triple Junction on the east, extends over the Black Sea on the north and 130 kilometers from the fault on the south. Checkerboard method is used to test the resolution of the dataset, then node distribution on the NAF is optimized and Wang’s model is used for inversion solution (Wang,2003). Euler Pole and block strain are estimated with inversion solution for Eurasia/Anatolia plates and the slip deficit variations are estimated for NAF. Under the constrain of the dense GNSS networks, we displayed that some segments of NAF are creeping up to shallow part of the crust and some other segments are locked at deeper region. Herein to better understand latest circumstance of complex slip deficit pattern of the NAF, estimated by our model, we evaluated our results under the complementary present and paleo-seismological datasets.

Keywords: NAF, block modelling, GNSS

How to cite: Ayruk, E. T., Özarpacı, S., Özdemir, A., Özbey, V., Ergintav, S., and Doğan, U.: Determining Strain Accumulation Along NAF with Block Modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10193, https://doi.org/10.5194/egusphere-egu22-10193, 2022.

EGU22-10619 | Presentations | TS4.1

Neogene to recent geodynamic evolution of Northern Tunisia foreland thrust belt. 

Seifeddine Gaidi, Fetheddine Melki, Guillermo Booth-Rea, Wissem Marzougui, Jose Vicente Pérez-Peña, Patricia Ruano, Jorge Pedro Galve, Haifa Chouaieb, Jose Miguel Azañón, and Fouad Zargouni

This work analyses the tectonic evolution of Northern Tunisia from the Late Miocene to Present. Two orthogonal extensional systems with ENE- and SE-directed transport produced the extensional collapse of the Tell and Atlas Foreland Thrust Belts (FTBs) in northern Tunisia during the Late Miocene to Pliocene in a context of NW-SE plate convergence between Africa and Eurasia. These systems produced the extensional denudation of the Tunisian Atlas and Tell foreland thrust belts, which we related to deep mantle tectonic mechanisms, known as a common feature in other FTB´s in the western Mediterranean, i.e. Betics, Rif, Calabria and Apennines. Low-angle normal faults have extended and reworked the Tunisian Tell external foreland thrust belt, exhuming midcrustal lower-greenschist metapelites and marbles with Triassic protholiths, and forming Late Miocene basins. This extension was followed by later Pliocene to Present tectonic inversion, developing the active shortening structures in Northern Tunisia. The main shortening structure is formed by different reverse and strike-slip fault segments, linked forming the 130 km long Alia-Thibar fault zone. Restored Plio-Quaternary deformation observed on reflection seismic lines indicates deformation rates around 0.6-0.8 mm/yr in the studied segments and larger amounts of shortening to the West of Northern Tunisia (16%) than to the East (7%), which suggests that tectonic inversion started earlier to the West and later propagated eastwards, reaching Northeastern Tunisia in the Late Pliocene. Due to the young age of this tectonic inversion, the present relief of Northern Tunisia is characteristic of a young thrust and fold belt, with dominating axial valleys along synforms and an incipient transverse drainage development propagating from West to East.

How to cite: Gaidi, S., Melki, F., Booth-Rea, G., Marzougui, W., Pérez-Peña, J. V., Ruano, P., Galve, J. P., Chouaieb, H., Azañón, J. M., and Zargouni, F.: Neogene to recent geodynamic evolution of Northern Tunisia foreland thrust belt., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10619, https://doi.org/10.5194/egusphere-egu22-10619, 2022.

EGU22-11846 | Presentations | TS4.1

Mantle origins of topography, volcanism and the North Anatolian Fault in Anatolia: constraints from seismic tomography, seismic anisotropy and crustal structure 

Ian Bastow, Thomas Merry, Rita Kounoudis, Christopher Ogden, Rebecca Bell, Saskia Goes, Jennifer Jenkins, Laurence Jones, Beth Grant, and Charles Braham

The eastern Mediterranean hosts, within the span of a few hundred kilometres, extensional, strike-slip, and collision tectonics above a set of fragmenting subducting slabs. Widespread Miocene-Recent volcanism and ~2km uplift has been attributed to mantle processes such as delamination, dripping and/or slab tearing/break-off. We investigate this complex region using a variety of broadband seismological techniques, with new P- and S-wave tomographic images in Kounoudis et al. (2020), seismic anisotropy constrained via an updated dataset of SKS shear-wave splitting observations in Merry et al. (2021), and crustal structure imaged by quality-controlled H-κ stacking of receiver functions in Ogden & Bastow (2021). Overall, seismic anisotropy and crustal structure are more spatially variable than previously recognised, and such variations correspond well with variations in mantle structure shown by the tomography. In general, Moho depth is poorly correlated with elevation, suggesting crustal thickness variations do not fully explain topographic differences, and residual topography calculations indicate the requirement for a mantle contribution to Anatolian Plateau uplift. Evidence for such a contribution exists in central Anatolia, where an imaged horizontal tear in the Cyprus slab spatially corresponds with volcanism, a residual topographic high, and a region of reduced splitting delay times and nulls, all consistent with upwelling of asthenospheric material through the tear. Anisotropic fast directions are consistent with flow through the imaged gap between the Cyprus and Aegean slabs, again correlating roughly with both volcanism and high residual topography. Slow uppermost‐mantle wave speeds below active volcanoes in eastern Anatolia, and ratios of P-to-S wave relative traveltimes, indicate a thin lithosphere and melt contributions. Elsewhere, there is more evidence for slab processes controlling mantle flow, with anisotropic fast directions diverted at the edges of imaged slabs and consistent with flow towards the retreating Hellenic trench in the Aegean. The North Anatolian Fault is revealed to be a deep, plate-scale structure: whilst there are no clear changes in Moho depth across the fault, deep velocity contrasts suggest a 40­-60km decrease in lithospheric thickness from the Precambrian lithosphere north of the fault to a thinned Anatolian lithosphere in the south. Moreover, short-length-scale variations in anisotropy and backazimuthal variations in splitting parameters at the fault indicate fault-related lithospheric deformation, with seismic fast directions either fault-parallel or intermediate between the principle extensional strain rate axis and fault strike, diagnostic of a relatively low-strained transcurrent mantle shear zone. Upper mantle structure thus exerts a strong influence on uplift, volcanism and deformation in Anatolia.

References

Kounoudis, R., I.D. Bastow, C.S. Ogden, S. Goes, J. Jenkins, et al.,  (2020), Seismic Tomographic Imaging of the Eastern Mediterranean Mantle..., G3, 21(7), doi:10.1029/2020GC009009.

Merry, T.A.J., I.D. Bastow, R. Kounoudis, C.S. Ogden, R.E. Bell, & L. Jones (2021), The influence of the North Anatolian Fault and a fragmenting slab architecture on upper mantle seismic anisotropy... ,G3, 22, doi:10.1029/2021GC009896.

Ogden, C.S., & I.D. Bastow (2021), The Crustal Structure of the Anatolian Plate from Receiver Functions..., GJI, doi:10.1093/gji/ggab513.

How to cite: Bastow, I., Merry, T., Kounoudis, R., Ogden, C., Bell, R., Goes, S., Jenkins, J., Jones, L., Grant, B., and Braham, C.: Mantle origins of topography, volcanism and the North Anatolian Fault in Anatolia: constraints from seismic tomography, seismic anisotropy and crustal structure, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11846, https://doi.org/10.5194/egusphere-egu22-11846, 2022.

EGU22-12611 | Presentations | TS4.1

New insights on the relationship between inherited structures of the opening of the Algero-Balearic basin and recent inversion of its southern margin 

Shaza Haidar, Pierre Leffondré, Jacques Déverchère, David Graindorge, Frauke Klingelhoefer, Mohamed Arab, Mourad Medaouri, and Marie-Odile Beslier

The Algero-Balearic Basin (ABB) is an Oligo-Miocene back-arc basin resulting from a polyphase tectonic evolution involving Tethyan subduction retreat and bilateral slab tear propagation. The ABB was fully opened by the Tortonian, while the Gibraltar and Calabria arcs formed by the narrowing of retreating slab fragments. Since then, the Algerian margin has undergone a tectonic inversion, potentially preceding an incipient subduction as shown by the analysis of the on-offshore deformation distribution. In this work, we aim to shed light on the relationships between the large-scale structures inherited from the ABB opening and the recent margin inversion. For this purpose, we rely on two recent analyses, one addressing the ABB opening (Haidar et al., 2021) and the other mapping the inversion-related structures off-Algeria (Leffondré et al., 2021), both being constrained by a set of deep penetration multi-resolution seismic profiles cross-correlated with magnetic, gravimetric and bathymetric data. 

The deep ABB has been subdivided into 4 zones with relatively distinct geodynamic evolutions, as demonstrated by variations in pre-Messinian sedimentary infill thickness and basement depth : (1) the oldest, fan-shaped oceanic basin to the east (off-Jijel), formed during the Langhian-Serravallian after collision of the Kabylian blocks with the stretched African margin; (2) the shallower and younger Hannibal thinned continental domain (HD), intruded by intense post-collisional magmatic activity during the Upper Serravallian - Lower Tortonian; and ever-younger to the west, (3) the central-western (off-Algiers-Tipaza) and (4) westernmost zones, formed from the Tortonian to the Lower Messinian in response to the westward retreat of the Gibraltar slab and the concomitant migration of the Alboran block by propagation of vertical tears along a STEP (Subduction Transform Edge Propagator) type margins.

The tectonic inversion is characterised by long-wavelength of flexure (>100km) of the ABB towards the Algerian margin and/or buckling of shorter wavelengths (≈30km). The central (HD) and central-eastern (off-Jijel) zones are dominated by flexure, whereas buckling is dominant in the central-western zone. Further, the easternmost (off-Annaba) and westernmost zones exhibit a combination of flexure and buckling. Except in the westernmost zone, characterized by low deformation on a single fault, the margin toe consistently displays inversion-related faults systems consisting of 3 to 4 south-dipping and sub-parallel thrust faults.

By comparing the zonation of the deep ABB and the zones with different responses to inversion, we evidence a similar zonation of the margin, with only slight differences likely resulting from data density variations. To the east, the old and wide fan-shaped basin has favored the development of a significant flexural response, whereas the young westernmost zones, narrower and bordered by STEP-faults, evidence a combination of buckling and short-wavelength of flexure. The HD is a complex zone with a shorter wavelength of flexure compared to the eastern zone, probably related to magmatic activities affecting the potentially continental crust. Our results suggest that if initial zonation persists, several parameters may be involved in the control of the inversion mode. These parameters may include the opening-related structural inheritance, the oceanic lithosphere composition, as well as the age and former structures of the margin.

How to cite: Haidar, S., Leffondré, P., Déverchère, J., Graindorge, D., Klingelhoefer, F., Arab, M., Medaouri, M., and Beslier, M.-O.: New insights on the relationship between inherited structures of the opening of the Algero-Balearic basin and recent inversion of its southern margin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12611, https://doi.org/10.5194/egusphere-egu22-12611, 2022.

EGU22-13052 | Presentations | TS4.1

Connecting subduction, extension, and shear localization across the Aegean Sea and Anatolia 

Sylvain Barbot and Jonathan Weiss

The Eastern Mediterranean is the most seismically active region in Europe due to the complex interactions of the Arabian, African, and Eurasian tectonic plates. Deformation is achieved by faulting in the brittle crust, distributed flow in the viscoelastic lower-crust and mantle, and Hellenic subduction, but the long-term partitioning of these mechanisms is still unknown. We exploit an extensive suite of geodetic observations to build a kinematic model connecting strike-slip deformation, extension, subduction, and shear localization across Anatolia and the Aegean Sea by mapping the distribution of slip and strain accumulation on major active geologic structures. We find that tectonic escape is facilitated by a plate-boundary-like, trans-lithospheric shear zone extending from the Gulf of Evia to the Turkish-Iranian Plateau that underlies the surface trace of the North Anatolian Fault. Additional deformation in Anatolia is taken up by a series of smaller-scale conjugate shear zones that reach the upper mantle, the largest of which is located beneath the East Anatolian Fault. Rapid north-south extension in the western part of the system, driven primarily by Hellenic Trench retreat, is accommodated by rotation and broadening of the North Anatolian mantle shear zone from the Sea of Marmara across the north Aegean Sea, and by a system of distributed transform faults and rifts, including the rapidly extending Gulf of Corinth in central Greece and the active grabens of western Turkey. Africa-Eurasia convergence along the Hellenic Arc occurs at a median rate of 49.8 mm/yr in a largely trench-normal direction, except near eastern Crete where variably-oriented slip on the megathrust coincides with mixed-mode and strike-slip deformation in the overlying accretionary wedge near the Ptolemy-Pliny-Strabo trenches. Our kinematic model illustrates the competing roles the North Anatolian mantle shear zone, Hellenic Trench, overlying mantle wedge, and active crustal faults play in accommodating tectonic indentation, slab rollback, and associated Aegean extension. Viscoelastic flow in the lower crust and upper mantle dominate the surface velocity field across much of Anatolia and a clear transition to megathrust-related slab pull occurs in western Turkey, the Aegean Sea, and Greece. Crustal scale faults and the Hellenic wedge contribute only a minor amount to the large-scale, regional pattern of Eastern Mediterranean interseismic surface deformation.

How to cite: Barbot, S. and Weiss, J.: Connecting subduction, extension, and shear localization across the Aegean Sea and Anatolia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13052, https://doi.org/10.5194/egusphere-egu22-13052, 2022.

EGU22-194 | Presentations | TS4.2

The Ar-Hötöl surface rupture along the Khovd fault (Mongolian Altay) 

Battogtokh Davaasambuu, Matthieu Ferry, Ritz Jean-Francois, and Ulziibat Munkhuu

The Ar-Hötöl surface rupture along the Khovd fault (Mongolian Altay)

 

Battogtokh Davaasambuu1,2, Matthieu Ferry1,*, Jean-Francois Ritz1 and Ulziibat Munkhuu2

  • Géosciences Montpellier, University of Montpellier, CNRS, France
  • Institute of Astronomy and Geophysics, Mongolian Academy of Sciences, Mongolia

 

Abstract

The Khovd fault is one of the major active faults of the Altay but has been little studied. Detailed mapping based on satellite imagery shows that the Khovd structure exceeds 550 km in length and displays different types of complex rupture segmentation, fresh and mature surface ruptures and a number of co-seismic and cumulative offsets along its entire length.

We present a 1:200,000 scale map of the Ar-Hötöl surface rupture along the Khovd Fault in the Mongolian Altay, presumed to be the surface expression of a Mw ~ 7.8 earthquake that was felt regionally in 1761 CE. The detailed mapping is based on a multi-scale approach combining a range of airborne and terrestrial imaging and topographic techniques: Sentinel-2, Pleiades, TanDEM-X, UAV, and terrestrial laser scanning. This effort led to the detailed quantification of right-lateral and vertical offsets ranging from ~ 1 m to ~ 4 km over a continuous rupture length of 238 km. The distribution of the smaller offset class documents the surface deformation associated with the last surface-rupturing earthquake. Its analysis yields a robust segmentation model comprising 6 segments 18 to 55 km in length, a maximum co-seismic slip value of 4.5 m ± 0.5 m located near the center of the rupture. Our detailed remote sensing and field observations precise the varying kinematics along strike, bring new evidence of repeated faulting and confirm a moment magnitude of 7.8 ± 0.3.

The aim of the present research work is to reveal the main sources of potential destructive earthquakes by identifying the location of past large earthquakes along the fault and estimate their magnitude and recurrence period. Our results would contribute to improve seismic hazard estimation for population of the Altay Mountains.

 

Keywords: active fault, surface rupture, Altay Range

 

How to cite: Davaasambuu, B., Ferry, M., Jean-Francois, R., and Munkhuu, U.: The Ar-Hötöl surface rupture along the Khovd fault (Mongolian Altay), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-194, https://doi.org/10.5194/egusphere-egu22-194, 2022.

EGU22-514 | Presentations | TS4.2

Seafloor expression of the deep structure during initiation of transtensional fault systems, as seen in the North-South fault system of the Alboran Sea, SE Iberia. 

Ariadna Canari Bordoy, Hector Perea, Sara Martínez - Loriente, Eulàlia Gràcia, David Fernández - Blanco, and Jaume Llopart

How fault segments grow and connect in regions with moderate to high seismic activity is key to assess associated hazards. Earthquakes may affect populated areas and can trigger tsunamis that threaten coastal areas and affect marine infrastructures. Regions accommodating relatively slow tectonic deformation may still enclose active fault systems capable of generating moderate to large magnitude earthquakes, albeit at long recurrence intervals (103 to 104 years). Although the Alboran Sea is currently characterised by slow tectonic deformation and by earthquakes of low to moderate magnitude, large historical and instrumental events have also occurred (i.e., the Almeria 1522 IEMS98 VIII-IX or the Al-Idrissi 2016 Mw 6.4 earthquakes). This Neogene basin located in the westernmost Mediterranean Sea absorbs most of the convergence between the Eurasian and Nubian plates (3 - 5 mm/year) by means of four tectonic-scale fault systems: the Carboneras and Al-Idrissi left-lateral strike-slip faults, the Yusuf right-lateral strike-slip fault and the Alboran Ridge thrust.

Our study characterises the North-South fault system on the northern Alboran Sea to better understand the kinematics of the region on a larger scale. This system is proposed as the northern termination of the Al-Idrissi fault, and it may be presently evolving due to the transtensional stress field that affects the area. The first step to characterise the fault system has been to elaborate a detailed geomorphological map of the area to describe the identified scarps, their distribution, and structural relations. To achieve this, we have used very high-resolution bathymetric data (1x1 m pixel resolution) acquired with an autonomous underwater vehicle. The bathymetry shows several fault scarps striking N-S, resulting in horst and graben systems. The second step has involved the interpretation of high-resolution multichannel airgun and sparker seismic profiles running across the N-S faults. The integration of this dataset allows us to relate the morphological scarps with different normal faults interpreted in the seismic profiles. These faults cut the post-Messinian seismostratigraphic units (last 5.3 Ma) up to the seafloor, which supports that the fault system is currently active. Finally, the high segmentation of the North-South fault system and its small accumulated fault displacements supports it is in its initial stage of evolution.

How to cite: Canari Bordoy, A., Perea, H., Martínez - Loriente, S., Gràcia, E., Fernández - Blanco, D., and Llopart, J.: Seafloor expression of the deep structure during initiation of transtensional fault systems, as seen in the North-South fault system of the Alboran Sea, SE Iberia., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-514, https://doi.org/10.5194/egusphere-egu22-514, 2022.

EGU22-1341 | Presentations | TS4.2

A comparative analysis of approaches to expanding Canada’s Earthquake Scenario Catalogue 

Jeremy Rimando, Tiegan Hobbs, Alexander Peace, and Katsuichiro Goda

Canada’s earthquake scenario catalogue is a nation-wide collection of possible earthquake rupture scenarios that allows us to understand which populations and assets will be impacted by the rupture of particular faults (or their segments). In the past, scenarios were often generated on an ad hoc basis, when they were needed by practitioners. As new information from geologic, geomorphic, geophysical, and geodetic studies become available, it is possible to model additional earthquake rupture scenarios for inclusion in Canada’s earthquake scenario catalogue, which will be crucial to providing relevant seismic hazard and risk estimates to end users such as community planners and emergency managers. This is especially valuable in the seismically active intraplate regions of eastern Canada, where the seismic risk awareness, perception and, consequently, preparedness, is relatively low. In updating this catalogue, we employed different approaches to modelling earthquake hazard and risk scenarios using the Global Earthquake Model Foundation’s (GEM) OpenQuake Engine. We conducted a ‘known events’ approach, which involved modelling representative events for historical earthquakes and potentially active faults. We also implemented a ‘systematic risk-based’ approach, which involved disaggregating the seismic risk at certain locations into the relative contributions from different seismic source zones, and ranking the seismic risk for each census subdivision (approximately aligned with municipalities) across Canada. The goal of the ‘systematic risk-based’ approach was to mitigate the irregular coverage of the existing catalogue. We compare the nature of the two catalogues for one community, taking into account the ways these kinds of catalogues are used in Canada and elsewhere. Finally, we described the overall spatial variations in seismic risk, focusing on regions where seismic zones are close to densely-populated areas, such as the offshore BC region and Cascadia subduction zone in western Canada; and the Western Quebec, Charlevoix, lower St. Lawrence, and southern Great Lakes seismic zones in eastern Canada. 

How to cite: Rimando, J., Hobbs, T., Peace, A., and Goda, K.: A comparative analysis of approaches to expanding Canada’s Earthquake Scenario Catalogue, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1341, https://doi.org/10.5194/egusphere-egu22-1341, 2022.

EGU22-1829 | Presentations | TS4.2

Hidden Tectonics: Finding faults in (seemingly) climate controlled landscapes 

Jorien L.N. van der Wal, Veit Nottebaum, Georg Stauch, Boris Gailleton, Steven Binnie, Justin Tully, Ochirbat Batkhishig, Frank Lehmkuhl, and Klaus Reicherter

Central Asia’s arid landscape provides a key natural laboratory to study the effects of slow deformation in continental interiors. Far-field stresses of the India-Eurasia collision have created major transpressive fault systems across the continent since the Cenozoic. In the 20th century the northward progression of this deformation resulted in four major earthquakes in Mongolia, among which was the 1957 Mw 8.1 Gobi Altai earthquake in southern Mongolia. Palaeoseismic research following this event has allowed for quantification of deformation rates since the Late Pleistocene. Yet, the application of classic palaeoseismological methods disregards the possibility of more dispersed deformation, as was suggested in other continental interiors.

The 1957 earthquake ruptured ~350 km of the Bogd fault in southern Mongolia, along the mountain front of a series of Gobi Altai restraining bends just south of the Valley of (Gobi) Lakes basin. The high restraining bends are bound by small, steep alluvial fans that reflect a ~100 kyr climate cyclicity, whereas the low relief Valley of Gobi Lakes is characterized by endorheic lakes and sparsely dated large, gentle fans. To determine whether deformation during the 1957 earthquake was representative of regional deformation, we expanded the active tectonic record by increasing the spatial and temporal scales of our studies. Along the highest restraining bend, Ikh Bogd Mountain (~4,000 m asl), we confirmed vertical slip rates of <0.3 mm/yr along single fault strands. We also observed cumulative deformation and increased steepness of older alluvial fan levels, which could suggest progressive tilting by reverse faults along the mountain front. If this tilting is merely tectonically induced, uplift rates of Ikh Bogd could reach 0.9-1 mm/yr. Morphometric analyses indicate that faults in the restraining bend’s interior still affect river steepness. This could imply that multiple sub-parallel faults are active simultaneously, accumulating to the higher uplift rate suggested by fan tilting.

The basin north of Ikh Bogd comprises the endorheic Orog Nuur (lake) which is mostly fed by the Tuyn Gol (river) that drains the Hangay Mountains in central Mongolia. Its large alluvial fans are cross-cut by four tectonic lineaments that can each accommodate M~7 earthquakes and that have a cumulative vertical slip rate that is similar to the Bogd fault. This suggests that they are significant components of the regional structure, yet they were previously overlooked because the recurrence intervals of surface-rupturing events are slower than climatic rates. In the Orog Nuur Basin itself, reflection seismics indicate that Jurassic-Cretaceous extension structures were reactivated by Miocene-Present transpression. The effect these structures have on the Basin’s modern geomorphology indicates that they may still be active, although lacustrine and fluvial sediments do not reflect any tectonic activity since MIS 5 (~120 ka).

By expanding spatial and temporal scales of active tectonic studies in southern Mongolia, we show that variability in the interplay between climate, tectonics, and geomorphology can mask the complexity of a tectonic structure. By adapting methods and incorporating the different processes that affect landscapes, such studies contribute to more complete seismic hazard assessments in slowly deforming continental interiors.

How to cite: van der Wal, J. L. N., Nottebaum, V., Stauch, G., Gailleton, B., Binnie, S., Tully, J., Batkhishig, O., Lehmkuhl, F., and Reicherter, K.: Hidden Tectonics: Finding faults in (seemingly) climate controlled landscapes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1829, https://doi.org/10.5194/egusphere-egu22-1829, 2022.

EGU22-1868 | Presentations | TS4.2 | Highlight

Surface-rupturing paleoearthquakes in a context of slow deforming continental interiors: the Lower Tagus Valley fault, Central Portugal 

Mohammad Foroutan, Susana Vilanova, Sandra Heleno, Andrew Murray, Luís Pinto, Ailar Sajedifar, Ana Falcão, Mohadesseh Torkamani, Carolina Canora, Pedro Pina, Gonçalo Vieira, and Joao Fonseca

Estimating the rate and the pattern of active deformation of slow-slip structures in intracontinental regions has always been a challenging task. Central Portugal is one of those intracontinental regions where the convergence of Eurasian and Nubian plates governs its active deformation. The NE-striking Lower Tagus Valley (LTV) is a locus of active deformation and several historical earthquakes. The eastern and western margins of the LTV are fault-controlled zones (Lower Tagus Valley Fault Zone; LTVFZ), characterized by the predominant strike-slip component. The ~80 km long LTVFZ is one of the most significant intraplate structures in mainland Portugal, and its seismic activity may pose a considerable threat in densely populated urban and industrial areas developed along the LTV. However, the spatio-temporal seismic history along the main structures of LTV is still poorly constrained. In this study, we investigate the geomorphologic features along the Eastern LTVFZ using high-resolution digital aerial orthophotos, high-resolution topographic data extracted from airborne Light Detection and Ranging (LiDAR) data sets, drone-derived high-resolution topographic data, and very high-resolution orthophotos acquired by a small unoccupied aerial system. Removing vegetation cover by LiDAR data leads to access to bare earth surface models that are essential to recognize subtle geomorphic features and constrain their offsets. Accordingly, several cumulative left-lateral displacements were measured along a 20-km stretch of the Eastern LTVFZ. The smallest measured offsets range between 2 and 3 meters that may correspond to the coseismic slip during the most recent surface faulting.     

To specify the contribution of the Eastern LTVFZ to the regional seismic hazard, we investigate its seismic history through three paleoseismic trenches excavated across the fault near the city of Almeirim. The stratigraphic units, structural features, and geological relations were first logged in the field and then evaluated using the high-resolution, rectified seamless trench-wall photomosaics. Several vertical to steep fault strands exposed in the trench walls cut through the late Pleistocene and Holocene alluvial deposits, recording the signature of several strong paleoearthquakes. Stratigraphic analysis and optically stimulated luminescence dating suggest that the most recent surface faulting has occurred sometime in the middle-late Holocene. The horizontal displacement of this earthquake was measured at two localities nearby the trench site, both in the field and on the very high-resolution orthophotos, and amounts to 2 to 3 meters of the on-fault sinistral offset. The evidence of an older earthquake has been preserved in the late marine isotope stage (MIS) 3 deposits, and at least two even older earthquakes recorded in a sequence of alluvial deposits that predate MIS 4. Although the Eastern LTVFZ may be characterize by low slip rates and instrumentally a quiescent structure, it remains capable of generating morphogenic large-magnitude earthquakes of Mw 7 to 7.5 with millennial recurrence intervals. Such seismic behavior challenges the reliability of assessing seismic hazard over slow-slipping faults across intraplate settings in the lack of geological information.

How to cite: Foroutan, M., Vilanova, S., Heleno, S., Murray, A., Pinto, L., Sajedifar, A., Falcão, A., Torkamani, M., Canora, C., Pina, P., Vieira, G., and Fonseca, J.: Surface-rupturing paleoearthquakes in a context of slow deforming continental interiors: the Lower Tagus Valley fault, Central Portugal, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1868, https://doi.org/10.5194/egusphere-egu22-1868, 2022.

EGU22-3003 | Presentations | TS4.2

Active deformation across the western Kunlun range, from NW Tibet to the SW Tarim Basin (China), using Sentinel-1 InSAR data 

Marguerite Mathey, Raphaël Grandin, Cécile Lasserre, Martine Simoes, Marie-Pierre Doin, Philippe Durand, and the Flatsim Team

The western Kunlun (WK) region is characterized by weak to moderate seismicity. However the recent Pishan earthquake (Mw 6.4), which ruptured in 2015 a blind thrust of the Pishan anticline at the front of the WK range, points out the potential for larger earthquakes in this region. Previous studies highlighted the existence of a major thrust sheet, connected at depth to the fault segment that likely ruptured in 2015, spanning ~ 150-180 km, between the western Kunlun front of the chain and another active deformation front further north within the Tarim basin (Mazar Tagh ridge). This active thrust sheet has a probable slip-rate of ~ 0.5-2.5 mm/yr as derived from geological and morphotectonic indicators. Would this structure be fully locked during the interseismic period, it could lead to earthquakes of Mw ~ 8 given the rupture width under consideration.

 

The present work aims at studying slip partitioning and interseismic loading in this area. GPS data within the Tarim basin lack constraints due to relatively high uncertainties and to a sparse spatial distribution. We present here an InSAR time-series analysis which provides a high space and time resolution to monitor the main active structures. This analysis is however challenging due to sand dunes and vegetation, which alter the coherence of the signal, and to topographic gradients inducing atmospheric phase delays where tectonic deformation is expected. We thus rely for this study on the ForM@Ter LArge-scale multi-Temporal Sentinel-1 InterferoMetry (FLATSIM) service (Thollard et al., 2021) to process the 5 ascending and 5 descending tracks covering our area. We compare parametric signal decompositions and principal/independent components analysis in order to separate tectonic from non-tectonic signals. We finally derive a regional linear velocity map representative of tectonic motions, masking unwrapping errors, atmospheric residuals, and remaining non-tectonic signals.

 

These first InSAR-based velocity results obtained along the WK-Tarim area allow to discuss the potential locking of the wide thrust sheet, in the context of known moderate ruptures. It also brings new insights into the possible connections between compressive structures and large strike-slip fault systems from the WK front to northwestern Tibet. In the complex junction area of the Western Kunlun, Altyn Tagh and Karakorum faults, several strike-slip and normal faults could be identified as active over the observation period (2015-2021), with slip rates consistent with the ones derived from morphotectonic studies (~ 4-5 mm/yr), and some faults likely showing creep (Longmu-Gozha Co fault system). These results may contribute to better understand the occurrence of normal faulting earthquakes in-between the identified strike-slip segments, such as the 2020 Mw 6.3 Yutian earthquake.

How to cite: Mathey, M., Grandin, R., Lasserre, C., Simoes, M., Doin, M.-P., Durand, P., and Team, T. F.: Active deformation across the western Kunlun range, from NW Tibet to the SW Tarim Basin (China), using Sentinel-1 InSAR data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3003, https://doi.org/10.5194/egusphere-egu22-3003, 2022.

EGU22-3646 | Presentations | TS4.2 | Highlight

Boosting detection of active tectonics with multi-source data and integrated methods: recent outcomes from the Apennines 

Federica Ferrarini, J Ramón Arrowsmith, Rita de Nardis, Francesco Brozzetti, Daniele Cirillo, Kelin X Whipple, and Giusy Lavecchia

   The Apennine mountain belt is a seismically active region showing coupled extensional- and compressional tectonic regimes. The bulk of the seismic energy is released along the normal-fault systems paralleling the topographic divide where earthquakes with 6.0<MW<7.0 have occurred both in historical- and recent times. Moderately-energetic compressive/transpressive earthquakes (4.0<MW<6.0), which occurred in the last 50 years, are associated instead with recent activity along the outer front of the fold-and-thrust belt.

   The relatively-low slip rates (1-3 mm/y), peculiar geological settings, fault systems’ immaturity hamper the assessment of Quaternary fault activity, challenging estimation of the seismic hazard.

   We present the results of multiscale-multidisciplinary approaches carried out in the Sibillini Mts and peri-Adriatic piedmont of Abruzzo and Molise regions, located in the Apennine extensional- and compressional domain, respectively. In detail:

  • we investigated the area beyond the northern tip of the Mt Vettore-Mt Bove Fault (VBF), where a remarkable seismicity rate was observed after the 2016 (Mw 6.5) Norcia earthquake. We interpreted primary topographic attributes to direct geological field surveys. We compared (on-surface) evidence of distributed deformation with results coming from 3D assessment of fault slip tendency with computation of Coulomb failure function across the potential fault surfaces. We pointed out the seismogenic character of the ∼13 km-long Pievebovigliana master normal Fault (PBF), which strikes N155°E, dips SW and is in right-lateral en echelon setting with respect to the VBF. The reconstructed geometry of the immature PBF is compatible with the occurrence of Mw≥6.0 earthquakes;
  • we addressed the hypothesis of late Quaternary activity along the Apennines Outer Front (SAOF), in central-southern Italy, where compressional tectonics is well documented until the Lower-Middle Pleistocene and the front is buried under Plio-Pleistocene foredeep deposits. By integrating topographic- and fluvial network analyses along with morphotectonic investigation of fluvial terraces we found, in the Abruzzo region, variable evidence of rock uplift along segments of the SAOF and inward structures, on its hanging wall. The observed pattern of anomalies is difficult to explain with long-wavelength regional uplift alone and agrees with the regional seismotectonic framework. Despite the low deformation-rate context challenging the interpretation of the topographic and geomorphic signals, the study suggests a reconsideration of late Quaternary active thrusting in central-southern Italy.

   Despite the different tectonic contexts, the study areas belong to, and the diversity in scale and resolution of the input data, the integration of different methods of investigation turned out successful while dealing with active tectonics in low-deforming-rate regions. Our results along the Apennines confirm how multidisciplinarity boosts the chance to decipher clues of active tectonics and unveil potentially seismogenic sources.

This work has received funding from DiSPuTer - University ‘G. d’Annunzio’ of Chieti-Pescara and from the European Union’s Horizon 2020 research and innovation programme, under Grant Agreement #795396.

 

How to cite: Ferrarini, F., Arrowsmith, J. R., de Nardis, R., Brozzetti, F., Cirillo, D., Whipple, K. X., and Lavecchia, G.: Boosting detection of active tectonics with multi-source data and integrated methods: recent outcomes from the Apennines, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3646, https://doi.org/10.5194/egusphere-egu22-3646, 2022.

EGU22-3735 | Presentations | TS4.2

Using numerical modelling to investigate the driving forces of permanent forearc deformation in northern Cascadia 

Nicolas Harrichhausen, Jack P Loveless, Kristin D Morell, Christine Regalla, and Emerson M Lynch

We use boundary element method modelling to investigate whether subduction zone coupling drives permanent forearc deformation in the northern Cascadia subduction zone. Recent work in this region shows that several active crustal faults accommodate permanent strain north of the Olympic Peninsula in Washington State, USA and British Columbia, Canada. These faults are similar in that they strike west-northwest, have oblique right-lateral slip senses, and have low slip rates (<1 mm/yr). Paleoseismic studies show that despite the region’s low permanent strain rates, these faults have produced large (~M 7) earthquakes. Therefore understanding how and why these structures accommodate permanent deformation is crucial to assessing regional seismic hazard. Previous work has hypothesized this type of permanent forearc deformation may be driven by stress resulting from interseismic subduction zone coupling. To test this hypothesis, we used a 3D boundary element method model to determine whether coupling-driven forearc deformation can account for the observed right-lateral fault slip on one of the recently studied structures, the Leech River--Devils Mountain fault. Our model predicts left-lateral slip on this fault if strain results from subduction zone coupling alone, inconsistent with the observed kinematics. Additionally, if we use our model to mimic strain partitioning, where only strain resulting from the strike-slip component of subduction zone coupling is accommodated in the forearc, the predicted fault slip is also inconsistent with observations of fault kinematics. These simplified models represent a first-order test that contradicts the hypothesis that subduction zone coupling is the primary driver of permanent forearc deformation in northern Cascadia.

How to cite: Harrichhausen, N., Loveless, J. P., Morell, K. D., Regalla, C., and Lynch, E. M.: Using numerical modelling to investigate the driving forces of permanent forearc deformation in northern Cascadia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3735, https://doi.org/10.5194/egusphere-egu22-3735, 2022.

EGU22-3768 | Presentations | TS4.2 | Highlight

Quaternary slip rates from multi-site paleoseismic analysis of a complex deformation zone in the Alhama de Murcia Fault (SE Spain): improvements and challenges 

Octavi Gómez-Novell, María Ortuño, Julián García-Mayordomo, Juan M. Insua-Arévalo, Thomas K. Rockwell, Stéphane Baize, José J. Martínez-Díaz, Raimon Pallàs, Marc Ollé, and Eulàlia Masana

Paleoseismology is a fundamental method to characterize the activity of faults in low to moderate strain regions such as SE Spain. Among the different parameters to characterize such activity, the slip rate is one of the most crucial for fault-based probabilistic seismic hazard assessments (PSHA) as it controls the rates of earthquake occurrence and ultimately the hazard levels likely to be exceeded in a given time period.

The Alhama de Murcia Fault (AMF) is the most active structure within the Eastern Betics Shear Zone (EBSZ), a transpressive fault system that accommodates the largest part of the Africa-Eurasia convergence in SE Iberia. The AMF has caused some of the most important earthquakes in the EBSZ since historical times, including the damaging 2011 Mw 5.2 Lorca event. In this setting, paleoseismic studies in the EBSZ have paid special attention to this fault, and particularly to its central segment (Lorca-Totana) as this is one of the most geomorphologically prominent.  Despite this, the segment comprises a wide deformation zone where the fault splays into five subparallel slip-partitioned branches, four of these still unstudied to date. We present a comprehensive paleoseismic study that integrates paleoseismic data from four out of the five branches that compose the segment. Our aim is to improve the representativeness of the geological slip rates by accounting for a nearly complete transect of the fault zone: we excavated eight new trenches across the four branches including seven fault-perpendicular and one parallel trench to measure vertical and lateral displacements, respectively. Fault slip analysis combined with OSL and radiocarbon dating allowed the calculation of slip rates for each branch and for the whole transect, as well as their variability over time.

A total net slip rate of 1.60 +0.16/-0.11 mm/yr for the past 18-15 ka is obtained, which is almost twice the previous estimations from a single fault branch (0.9±0.1 mm/yr). This points out the relevance of accounting for all structures of a fault zone for a more reliable characterization. The slip rate variability analysis depicts cyclic patterns of short slip rate accelerations followed by longer quiescence periods, some of which are interestingly similar to those identified in the neighboring Carrascoy Fault in previous studies. This may, for the first time, suggest potentially synchronous activity among faults in Iberia. The present study is therefore an important step to improve the representativeness of the slip rate estimations in the AMF, and ultimately for subsequent PSHA studies in the area. Despite this, two main challenges still need to be assessed; first, the intermittent deposition of alluvium in the area makes it difficult to have correlative time periods between sites to integrate slip rates. Second, the lack of data in one of the five fault branches and the lack of detailed 3D trenching in most branches suggests that the obtained slip rate values could be a minimum. In this sense, integrating data from new paleoseismic sites and refining the existing data would likely allow to refine the current estimations and potentially fill the present knowledge gaps.

How to cite: Gómez-Novell, O., Ortuño, M., García-Mayordomo, J., Insua-Arévalo, J. M., Rockwell, T. K., Baize, S., Martínez-Díaz, J. J., Pallàs, R., Ollé, M., and Masana, E.: Quaternary slip rates from multi-site paleoseismic analysis of a complex deformation zone in the Alhama de Murcia Fault (SE Spain): improvements and challenges, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3768, https://doi.org/10.5194/egusphere-egu22-3768, 2022.

EGU22-5732 | Presentations | TS4.2

The seismicity of Cyprus 

Thomas Merry, Ian Bastow, David Green, Freddie Ugo, Rebecca Bell, Sylvana Pilidou, and Iordanis Dimitriadis

The island of Cyprus sits at the boundary between the Anatolian and African plates, at a transition between oceanic subduction and incipient continental collision. Seismicity has been recorded here for millenia, with at least 12 town-destroying earthquakes recorded over the last 2,000 years. However, the instrumental coverage on the island has remained poor until relatively recently, and there is no bespoke velocity model or local magnitude scale, meaning that local seismicity is relatively poorly understood. Larger earthquakes, mainly to the south and west of the island, have revealed a mix of strike-slip and reverse faulting mechanisms. More enigmatic is the onshore seismicity, and questions remain over deformation within the Cyprus slab and uplift mechanisms of the Troodos ophiolite. We investigate seismicity in and around the island, in order to better understand these processes and their associated seismic hazard. We combine records of a temporary deployment of five broadband seismometers with the 13 permanent broadband seismometers on the island, as well as two accelerometers, to create a two-year local earthquake catalogue. We locate earthquakes both within the overriding Cyprus crust and the underthrusting African plate, and identify previously unrecognised seismically active regions on the island, especially around the Troodos ophiolite. We use this earthquake catalogue to constrain a new 1-D velocity model and local magnitude scale for the region. We also constrain new focal mechanisms and interpret these in the context of the regional tectonics.

How to cite: Merry, T., Bastow, I., Green, D., Ugo, F., Bell, R., Pilidou, S., and Dimitriadis, I.: The seismicity of Cyprus, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5732, https://doi.org/10.5194/egusphere-egu22-5732, 2022.

EGU22-6018 | Presentations | TS4.2

Seismotectonic evidence for present-day transtensional reactivation of the slowly deforming Bodensee-Hegau Graben in the northern foreland of the Central Alps 

Tobias Diehl, Herfried Madritsch, Michael Schnellmann, Thomas Spillmann, Elmar Brockmann, and Stefan Wiemer

This study presents a seismotectonic analysis of the Miocene-aged Bodensee-Hegau Graben, a major tectonic element in the northern foreland of the European Central Alps. The graben is characterized by comparatively low strain rates and low to moderate seismicity. Our study builds on the seismological analysis of earthquakes recorded by a recently densified seismometer network. The derived high-precision absolute and relative hypocenter relocations allow to identify seismogenic structures in the pre-Mesozoic basement, which we relate to bounding faults on either side of the NW-SE striking graben. A cluster of seismicity on the SW side of the graben is associated with the previously mapped Neuhausen Fault. In contrast, the seismogenic, SW-dipping bounding faults on the opposite side of the graben, between the extinct Hegau volcanic field and the Bodanrück peninsula of Lake Constance, cannot be associated with any known fault. A set of 51 focal mechanisms allows for a high-resolution analysis of kinematics and stress regime of the graben. Our results show that the bounding faults of the graben are optimally oriented to be reactivated in transtensional mode in the present-day stress field. Slip rates across the Neuhausen and Randen faults estimated from geodetic data are likely <0.1 mm/yr. In comparison with historic seismicity over the past 600 years and geomorphic field observations, these rates appear overestimated. Nevertheless, historic seismicity over the past 600 years suggests that fault dimensions and slip rates are certainly sufficient to generate MW 5.0 earthquakes within this slowly deforming transtensive fault zone in the foreland of the Alpine collision zone.

How to cite: Diehl, T., Madritsch, H., Schnellmann, M., Spillmann, T., Brockmann, E., and Wiemer, S.: Seismotectonic evidence for present-day transtensional reactivation of the slowly deforming Bodensee-Hegau Graben in the northern foreland of the Central Alps, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6018, https://doi.org/10.5194/egusphere-egu22-6018, 2022.

EGU22-6469 | Presentations | TS4.2

Quantifying fault activity over different time scales in the Lower Rhine Graben, towards an improved fault database for seismic hazard assessment. 

Marthe Lefevre, Kris Vanneste, Alain Demoulin, and Aurelia Hubert-Ferrari

The Lower Rhine Graben (LRG) is an area of slow intra-plate extension in north-western Europe. Located in a densely populated area, this rift, with moderate but rather continuous seismic activity, poses significant seismic hazard. The LRG NW-trending fault system is 200-km long and accommodates a total extension of ~0.1 +/- 0.03mm/yr. While the major active faults are well known, the activity of this complex system as a whole remains poorly understood. This is partly due to the fact that the tectonic signal issued from such low strain rates deformation is often overprinted by other natural or anthropogenic processes. Thus, previous fault models do not integrate minor structures associated with limited deformation and remain elusive about precise fault geometry and branching. A high-resolution DEM, created from Lidar-based DEMs recently available in the surrounding countries, allows us to retrieve detailed tectonic information and refine the fault traces and scarp geometry. We thus present, for the entire region, a revised and homogeneous fault map, based on morphological observations of fault scarps and offset alluvial terraces, complemented by external information from paleoseismological surveys and geophysical profiles. The high-resolution topography shows a clear difference in fault morphological expression between the eastern and western sides of the graben, with clear scarps and sharp boundaries along the eastern side and smoother cumulative scarps in the west, suggesting contrasting fault behavior across the graben. Based on this detailed mapping, we propose a new active faults model for the whole LRG, reflecting the uncertainties in fault geometry. This is compiled in a database, including several levels of fault mapping (traces, fault sections, faults, main faults), where the fault traces are ranked according to the certainty of their identification and location.

Another limitation for seismic hazard assessment in the area is the relative scarcity of fault-displacement data compared to the large number of structures. In the southern part of the graben, a well-developed terrace allows us to estimate the activity of most faults over the Quaternary, but such an extended marker is missing in the northern part of the LRG, resulting in only few localized data. To complement these offset observations, we use several 3D-geological models. After a selection of the most representative geological layers, we automatically retrieve their offsets at several locations along each fault, to obtain the spatial slip distribution at different timescales.  We observe that along individual faults, the slip profile evolves laterally and in time, showing some fault linkage, while at the scale of the graben borders the total slip does not show significant lateral variations. Moreover, although the surface-expression differs between the two sides of the graben, the total slip rates are fairly equivalent on both sides, suggesting a symmetrical extension, at least for the northern area.

All offset measurements available for different marker horizons are also included in the new LRG fault database, thus providing an integrated tool which allows the user to choose the most relevant timescale and degree of geometrical complexity for advanced seismic hazard assessment.

How to cite: Lefevre, M., Vanneste, K., Demoulin, A., and Hubert-Ferrari, A.: Quantifying fault activity over different time scales in the Lower Rhine Graben, towards an improved fault database for seismic hazard assessment., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6469, https://doi.org/10.5194/egusphere-egu22-6469, 2022.

EGU22-6846 | Presentations | TS4.2

Intra-plate seismicity of the Lake Eyre Basin and Gawler Craton, Australia 

Caroline Eakin, Shubham Agrawal, and John Paul O'Donnell

The Australian continent, being void of plate boundaries, is often perceived as seismically quiescent. However, around 100 magnitude three or larger earthquakes are typically recorded in Australia each year, with a magnitude 6+ occurring every 8-10 years. Such intra-plate activity can pose a significant risk as they are often non-periodic, poorly understood, and sporadically recorded by sparse seismic networks across vast continents. Within Australia the distribution of intra-plate seismicity is non-uniform, but instead tends to concentrate along certain weak zones of increased activity. One such region is the eastern margin of the Gawler Craton in South Australia, one of the oldest building blocks of the continent. Recently several new temporary seismic arrays have been deployed in the region, transforming data coverage across South Australia. So far over 70 new local events have been recorded that would otherwise have gone undetected by the national network. After relocation the pattern of earthquakes becomes more spatially defined and appears to be closely tied to the edge of the Gawler Craton. Supporting evidence suggests that these events may be associated with a trans-crustal scale fault system that adds new constraints on the poorly defined craton boundary.

How to cite: Eakin, C., Agrawal, S., and O'Donnell, J. P.: Intra-plate seismicity of the Lake Eyre Basin and Gawler Craton, Australia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6846, https://doi.org/10.5194/egusphere-egu22-6846, 2022.

EGU22-7856 | Presentations | TS4.2

Rapid detection of complex deformation pattern following strong earthquakes through DInSAR measurements: the October 2016 central Italy case 

Filippo Carboni, Massimiliano Porreca, Emanuela Valerio, Mariarosaria Manzo, Claudio De Luca, Maurizio Ercoli, and Massimiliano Barchi

In the last three decades, remote sensing techniques, such as Differential Synthetic Aperture Radar Interferometry (DInSAR), Lidar differencing, optical imagery, and Global Positioning System (GPS) have been exploited for investigating, with high accuracy, ground displacement phenomena. Large seismic events (Mw > 5.5) can trigger deformations at the surface, such as ruptures related to the activation of main active faults and/or other deformations induced by seismic shaking (e.g., landslides, creeping, sinkhole).

In 2016-2017, a long earthquake sequence struck the Apennines in central Italy, producing impressive surface ruptures attributed to the 24 August Mw 6.0 and 30 October Mw 6.5 main-shocks. These ruptures were investigated and mapped by field geologists soon after the earthquakes.

We present detailed maps of the surface deformation pattern produced by the M. Vettore Fault System during the October 2016 earthquakes. The DInSAR analysis have been retrieved from ALOS-2 SAR data, via the Parallel Small BAseline Subsets (P-SBAS) algorithm. On these maps, we trace a set of cross-sections to analyse the coseismic vertical displacement, essential to identify both surface fault ruptures and off-fault deformations.

At a local scale, we identify a lower number of coseismic ruptures respect to the ones recognised in the field, but they are in very good agreement and even more laterally continuous. At a larger scale, we observe the M. Vettore Fault System hanging-wall being characterized by a long-wavelength upward-convex curvature, which is less evident towards the south and locally interrupted by a steep vertical gradient, testifying the occurrence of an antithetic NE-dipping fault.

A quantitative comparison of DInSAR- and field-derived vertical displacement reveals that our approach is particularly effective to constrain ruptures characterized by spatial vertical displacement up to 50 – 60 cm, which, in the field, show an unclear lateral continuity.

The rapid detection of deformation patterns from DInSAR technique can furnish important constraints on the activated fault segments, their spatial distribution and interaction soon after the seismic events. Thanks to the large availability of satellite SAR acquisitions, the proposed workflow can be potentially applied worldwide. It might be fundamental not only to support field geological mapping activities during an ongoing seismic crisis but also to provide a wider and faster picture of surface ruptures crucial for emergency management by civil protection in densely populated areas.

How to cite: Carboni, F., Porreca, M., Valerio, E., Manzo, M., De Luca, C., Ercoli, M., and Barchi, M.: Rapid detection of complex deformation pattern following strong earthquakes through DInSAR measurements: the October 2016 central Italy case, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7856, https://doi.org/10.5194/egusphere-egu22-7856, 2022.

EGU22-7945 | Presentations | TS4.2 | Highlight

Slip distribution of the 29 December 2020 Mw 6.4 Petrinja earthquake (Croatia) from dense geodetic benchmarks and optical image correlation measurements 

Maxime Henriquet, Marianne Métois, James Hollingsworth, Branko Kordić, Cécile Lasserre, and Lucilla Benedetti

The intracontinental Mw 6.4 Petrinja earthquake (Croatia) of December 29th, 2020, is one of the strongest earthquakes recorded in slowly deforming Eastern Europe. In low strain contexts, sparse seismic monitoring and the rare occurrence of strong earthquakes often prevent the detailed analysis of coseismic rupture. Discontinuous right-lateral coseismic surface rupture and extensive damages reported in the area suggest a relatively shallow seismogenic source for the Petrinja earthquake. Here, we leverage dense near field measurements from optical image correlation and numerous geodetic benchmarks for cadastral and engineering purposes to model the surface and subsurface slip distribution of the Petrinja earthquake. Optical image correlation based on pre-event (7th December 2017) WorldView and post-event (12th and 20th February 2021) Pleiades satellite images is used to refine the trace of the segmented surface rupture and derive coseismic displacements in the very near-field (< 1km from the fault). The ~13 km long imaged fault trace reveals an en échelon geometry in agreement with field observations, and a right-lateral slip reaching up to ~1 m. These results are consistent with the displacement field derived from the dense cadastral GNSS measurements. No additional conjugate fault is visible on the image correlation outcomes. The elastic inversion of these data shows that the coseismic slip was localized on a near-vertical strike-slip fault at shallow depth, < 10 km, and that significant slip reached the surface. It also suggests that the fault bending near Župić interfered with the rupture propagation as the largest slip, > 3 m, is localized on the northern section at depth < 5 km. In conclusion, this study not only provides new constrains on the seismogenic source of the Petrinja earthquake, it also underlines the potential of optical image correlation and cadastral GNSS measurements to retrieve a dense surface displacement field in the epicentral area of moderate intracontinental earthquakes.

 

How to cite: Henriquet, M., Métois, M., Hollingsworth, J., Kordić, B., Lasserre, C., and Benedetti, L.: Slip distribution of the 29 December 2020 Mw 6.4 Petrinja earthquake (Croatia) from dense geodetic benchmarks and optical image correlation measurements, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7945, https://doi.org/10.5194/egusphere-egu22-7945, 2022.

EGU22-8300 | Presentations | TS4.2

Velocity influence on deformation partitioning along evolving restraining bends 

Hanna Elston and Michele Cooke

The evolution of strike-slip restraining bends depends on early fault geometry (e.g., bend angle & stepover distance) and material properties, yet the influence of loading rate on fault system evolution is unknown. Within viscoelastic materials, such as the crust, the relaxation of stresses depends on loading rate. Under faster strain, faults will have shorter recurrence intervals, which reduces the time for stress relaxation during the interseismic period. Because slow strain rates yield greater stress relaxation, the growth of new faults near restraining bends may depend on loading rate. While crustal restraining bends evolve under a range of strain rates, the field expressions of faulting have overprints of early and late deformation, which makes discerning the impact of early strain rate on fault growth difficult. Here, we use scaled physical experiments to directly investigate the impact of strain rate on the evolution of restraining bends. We use wet kaolin as an analog for the crust because it creates sharp faults that remain active even when the loading orientation deviates slightly from the ideal for fault slip. In addition, off-fault stresses within the wet kaolin dissipate over time just as stresses within the crust do via inelastic processes and are tracked with tests on Anton Paar MCR102 rheometer. We directly observe and record the horizontal surface deformation for three experiments with the same initial restraining bend geometry. Computer-controlled stepper motors drive a basal plate at a prescribed velocity to induce faulting within the overlying layer of wet kaolin. The three experimental loading rates of 0.25, 0.5, and 1.0 mm/min scale to crustal loading rates of 2-4, 4-8, and 11-22 mm/yr respectively. We use digital image correlation to calculate incremental displacement and strain field data from overhead photos. Restraining bend experiments with different loading rates produce different deformation histories; slower applied loading produces greater  off-fault deformation and more secondary faults. Furthermore, new oblique-slip faults that grow within the slower loading rate experiments accommodate greater slip than the new faults that grow within the faster loading rate experiments. This suggests that strike-slip fault systems in slow strain rate regions may have slip distributed among several faults whereas slip may localize along a few faults within high strain rate regions. Additionally, the restraining bend geometry becomes more open in the slower loading rate experiments due to greater off-fault deformation. The differences in fault evolution owe to the sensitivity of both the wet kaolin strength and the degree of stress relaxation to strain rate, supported by rheometer tests. The experimental data suggest that loading rate can impact strain partitioning and fault geometry in crustal faults.

How to cite: Elston, H. and Cooke, M.: Velocity influence on deformation partitioning along evolving restraining bends, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8300, https://doi.org/10.5194/egusphere-egu22-8300, 2022.

EGU22-8806 | Presentations | TS4.2 | Highlight

Morphotectonics of the eastern Rhine Graben Boundary Fault (Germany): an active fault within the plate interiors of Central Europe 

Sara Pena-Castellnou, Stephane Baize, Jochen Hürtgen, and Klaus Reicherter

The eastern Rhine Graben Boundary fault zone (RGBF) constitutes the oriental margin of the Upper Rhine Graben (URG) which forms part of the European Cenozoic Rift System. The URG with low to moderate intraplate seismicity is one of the most seismically active areas in the plate interiors of Central Europe. Assessing seismic hazard in intraplate Europe is challenging as modest lithospheric deformation (<1 mm/yr) resulting from far-field stresses is accommodated by slow-slip faults. The instrumental and historical earthquake catalog of the URG (dating back to 800 AD) is too short to include the complete earthquake history and, for instance, document the occurrence of large earthquakes, potentially leading to underestimate capable faults.

Identifying and characterizing active faults is essential towards a comprehensive seismic hazard assessment in the URG. Several research efforts have been made towards this direction, focusing on the western RGBF and the southern end of the eastern RGBF. However, neotectonic studies integrating the whole eastern RGBF are lacking. As a first step, we here present a study of the neotectonic imprint in the morphology of the eastern margin of the URG based on the 12 m resolution TanDEM-X DEM and the 1 m resolution DEM of Baden-Württemberg derived from LIDAR data together with data from regional geological maps. We performed geomorphological mapping of Quaternary deposits, paleoseismic features, and faults. Besides, we calculated several morphometric parameters, including mountain front sinuosity, basin asymmetry, knickpoints, and hypsometric curve analysis to depict long-term deformation. The eastern RGBF consists of several NNE-SSW parallel fault strands marked by topographic steps that constitute the boundary between the Rhine River plain and the eastern uplifted URG shoulder. We have identified along the fault landforms that appear typical of active tectonic landscapes: a) topographical scarps, b) well-defined triangular facets developed on the hillslope associated with the main fault trace, c) displaced alluvial fans, d) left-lateral channel deflections and beheaded channels, and e) hanging valleys; that allows us to prove the kinematics of the fault as transtensional left-lateral strike-slip which is consistent with the regional stress (SH max). The occurrence of these neotectonic features varies along the 300 km long eastern RGBF fault, which, together with the results from the morphometric analysis, allow us to differentiate areas with differential tectonic activity suggesting fault segmentation. These results point out the seismic potential of the eastern RGBF, are critical to find suitable sites for paleoseismological trenching and are key to later propose plausible rupture scenarios for further PSHA studies.

How to cite: Pena-Castellnou, S., Baize, S., Hürtgen, J., and Reicherter, K.: Morphotectonics of the eastern Rhine Graben Boundary Fault (Germany): an active fault within the plate interiors of Central Europe, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8806, https://doi.org/10.5194/egusphere-egu22-8806, 2022.

EGU22-9137 | Presentations | TS4.2

Revised classification criteria for glacially induced faults 

Holger Steffen, Odleiv Olesen, and Raimo Sutinen

Glacially triggered faulting is the release of stresses induced by the advances and retreats of ice sheets in addition to other stresses that accumulated in the lithosphere. The faulting typically occurred along pre-existing faults or weakness zones before, during or after the last ice melting. This type of faulting is mainly recognized in intraplate regions but is also proposed for some plate boundary areas. Past reactivations were probably accompanied by large-magnitude seismic events triggering hundreds of landslides and seismically induced soft-sediment deformation structures (SSDS) in the region surrounding the glacially induced faults (GIFs).

Classification criteria were developed in the 1980s and 1990s to correctly identify a GIF and distinguish it from the vast number of other faults around the globe. Reliable field evidence for reactivated faults in and (even) around many formerly glaciated areas has considerably increased the number of confirmed and probable GIFs in recent years, which were recently unified in an international database (Munier et al., 2020). It has been generally thought that GIFs, especially the so-called postglacial faults in northern Fennoscandia, were developed during a short period of time towards the end of and shortly after the deglaciation, however, new dating results from Fennoscandia documenting several episodes of fault rupture within the past 14,000 years (Ojala et al., 2018; Olesen et al., 2021) and even connected to the begin of glaciation (Sutinen & Middleton, 2021) challenge this idea. The youngest fault scarp was formed less than 600 years ago (Olesen et al., 2021).

The new findings warrant a discussion of the classification criteria. We introduce revised classification criteria for GIFs, modified from the previous criteria and for easier application expressed as a checklist, see also Steffen et al. (2021).

 

References

Munier, R., Adams, J., Brandes, C., et al. (2020). International database of Glacially Induced Faults. PANGAEA, https://doi.org/10.1594/PANGAEA.922705.

Ojala, A. E., Markovaara-Koivisto, M., Middleton, M., Ruskeeniemi, T., Mattila, J., Sutinen, R. (2018). Dating of paleolandslides in western Finnish Lapland. Earth Surface Processes and Landforms 43(11), 2449–2462, https://doi.org/10.1002/esp.4408.

Olesen, O., Olsen, L., Gibbons, S., Ruud, B., Høgaas, F., Johansen, T., Kværna, T. (2021). Postglacial faulting in Norway – Large magnitude earthquakes of the Late Holocene Age. In H. Steffen, O. Olesen, R. Sutinen, eds., Glacially-triggered faulting. Cambridge University Press, pp. 198– 217, https://doi.org/10.1017/9781108779906.015.

Steffen, H., Olesen, O., Sutinen, R. (2021). Glacially-triggered faulting – A historical overview and recent developments. In H. Steffen, O. Olesen, R. Sutinen, eds., Glacially-triggered faulting. Cambridge University Press, pp. 3–19, https://doi.org/10.1017/9781108779906.003.

Sutinen, R., Middleton, M. (2021). Porttipahta end moraine in Finnish Lapland is constrained to Early Weichselian (MIS 5d, Herning stadial). Geomorphology 393, 107942, https://doi.org/10.1016/j.geomorph.2021.107942.

How to cite: Steffen, H., Olesen, O., and Sutinen, R.: Revised classification criteria for glacially induced faults, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9137, https://doi.org/10.5194/egusphere-egu22-9137, 2022.

EGU22-9228 | Presentations | TS4.2

Soft-sediment deformations in post-collisional calcarenites: a multi-scale descriptive approach 

Silvia Tamburelli, Pierre Mueller, Chiara Amadori, Laura Crispini, Matteo Maino, and Niccolò Menegoni

In the time frame after initial deposition but prior to lithification, sediments are frequently prone to physical, chemical, or biological disturbance. The resultant structures – commonly referred to as soft sediment deformation (SSD) - can be explained by a variety of mechanisms, each defined by a distinct set of parameters. Among the factors responsible for upward-oriented, physically-induced disturbance, two main triggering mechanisms are distinguished: (i) Fluidization of sediment, where SSD occurs as a fluid (typically saline water) passes through a layer of solid particles via areas of available pore space, and (ii) Liquefaction of unconsolidated sands, a process that commonly occurs in response to sudden loading on a bed which forces the sediment to transition from a solid to a liquefied state. Liquefaction can moreover be caused by seismic shocks. When subjected to seismic shocks, unconsolidated sand-size sediments tend to decrease in volume, which in turn produces an increase in pore-water pressure and a decrease in shear strength. A contrasting mechanism responsible for SSD is chemical disturbance which is thought to be the result of desiccation, cementation and crystal growth, thermal expansion, and contraction of partially lithified sediment during a continuous spectrum of diagenetic stages.

The origin of SSD remains a disputed topic in clastic sedimentology and a challenging task in outcrop studies. We present the first report of disturbed calcarenites in the “Pietra di Finale”, which crops out along the Ligurian coast, bordering the Ligurian Alps transect of the Western Alps. It represents an Early to Late Miocene mixed carbonate-siliciclastic coastal wedge that unconformably superimposes the Alpine metamorphic units. The "Pietra di Finale" is considered as a low strain region due to the lack of any deformation evidence, including seismic record, suggesting a Miocene tectonic quiescence in the southernmost part of the Alps. The “Pietra di Finale” can be subdivided in two formations: a basal terrigenous sequence resting below calcarenites making up the top of the formation. The calcarenitic formation displays a uniquely well-exposed assemblage of SSD features. These features comprise (i) vertical sediment expulsions recognizable by gross changes in granulometry with respect to that of the hosting sediments, (ii) carbonatic fluid-expulsion veins, (iii) lateral continuity of SSD-prone layers and (iv) sequential vertical and lateral organization of SSDs. The main aim of this study is to unravel the origin of untypically large coarse-clastic injections into the hosting calcarenites, with emphasis put on distinguishing the role of discriminating seismically from diagenetically induced sediment disturbances. Results from a multi-proxy approach: comprising a detailed study of the sedimentological characteristics at the outcrop-scale and photogrammetric investigations of the geometry of the structures and their stratigraphic occurrence; petrographic investigations of both grain and intergranular features (i.e. clasts and cement); as well as compositional and microthermometry analyses of the vein-filling cements, can yield insights into the pivotal role of the fluids as driver of seismicity-induced liquefaction and  uncommon mineralization and intrastratal sediment mobilization.

How to cite: Tamburelli, S., Mueller, P., Amadori, C., Crispini, L., Maino, M., and Menegoni, N.: Soft-sediment deformations in post-collisional calcarenites: a multi-scale descriptive approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9228, https://doi.org/10.5194/egusphere-egu22-9228, 2022.

EGU22-10132 | Presentations | TS4.2 | Highlight

A possible surface rupture of the 1756 Düren earthquake (Lower Rhine Graben) 

Vanessa Steinritz, Jochen Hürtgen, and Klaus Reicherter

Strong and rare or infrequent intraplate quakes in densely populated areas pose a significant risk to humans, infrastructure, and the environment. The Lower Rhine Graben is tectonically one of the most active zones in central Europe, and it is part of the European Cenozoic rift system. The destructive 1756 CE Düren Earthquake (Mw 6.4±0.3; located in western Germany), or the  1992 CE Roermond Earthquake (Mw 5.9; located in eastern Netherlands), both caused by normal faults of the Lower Rhine Graben, inflicted tremendous damage and demonstrate the need of hazard assessments and prevention in this highly industrialized area. Therefore, mapping and detecting of the traces, historical activity and kinematics of faults and related fault systems, is of high importance for hazard assessment of critical infrastructure   (i.e. pipelines, highways, lifelines) and cities in the Dutch, Belgian and German border region.

The 1756 CE Düren earthquake was one of the most destructive ones in the area, and in entire Central Europe, the observed damage (landslides, sackungen) and magnitude suggest a surface rupturing event. The causative fault is still under debate, also epicentral area and hypocentral depth remain enigmatic although different studies investaged several faults in the area, e.g. the normal Rurrand Fault or the Schafberg Fault. The Rurrand Fault does not exhibit seismic surface rupturing events younger than 2.3 ka, whereas the Schafberg Fault is much too short to produce a M > 6 event and trenching failed.

Trenching at the Birkesdorfer Sprung (or Fault), a NW-SE trending normal fault with a minimum length of c. 9 km, revealed a set of SW dipping normal faults associated with colluvial wedges and unconformities. Geophysical ground survey methods (GPR and ERT) as well as GIS-based morphotectonic analyses identified a long fault trace. Radiocarbon (14C) charcoal dating of displaced colluvial deposits revealed very young ages of c. 240 y BP and evidence for a second event older than c. 3.6 ky BP, the latter has been already described. However, this older event can be bracketed here much better in between 9.1 ± 1.5 ky BP and 3.6 ± 0.03 ky BP. Hence, in the Holocene, the recurrence period of surface rupturing earthquakes is lower than thought before and other seismic sources, such as the Birkesdorfer Fault must be considered.

How to cite: Steinritz, V., Hürtgen, J., and Reicherter, K.: A possible surface rupture of the 1756 Düren earthquake (Lower Rhine Graben), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10132, https://doi.org/10.5194/egusphere-egu22-10132, 2022.

EGU22-10362 | Presentations | TS4.2

Palaeoseismological constraints on the Anghiari normal fault (Northern Apennines, Italy): first results. 

alessio testa, Paolo Boncio, Stephane Baize, Francesco Mirabella, Stefano Pucci, Cristina Pauselli, Maurizio Ercoli, Magali Riesner, Bruno Pace, and Lucilla Benedetti

The Italian Apennines is a slowly deforming area, despite not properly being an intraplate region. This is particularly true for the Northern Apennines, where<= 2mm/yr of extension is accommodated by low-slip rate normal faults, often organized in parallel systems partitioning the regional deformation. As a result, large earthquakes on individual faults are separated by long (>~1ka) recurrence intervals. This makes earthquake geology a fundamental tool for characterizing the seismic hazard.

The Anghiari fault is a 11 km-long segmented NE-dipping normal fault bounding the western side of the Upper Tiber Valley (Northern Apennines, Italy), and belonging to the well-known Altotiberina low-angle normal fault system. Here, we provide unprecedented evidence of the Holocene activity of the Anghiari fault through geological, geophysical and palaeoseismological investigations.

The fault is composed of at least two nearly parallel splays. One splay runs at the base of the Pleistocene Anghiari ridge, downfaulting the late Quaternary alluvial deposits of the Tiber Valley against Middle Pleistocene continental deposits. The other splay is located within the Middle Pleistocene units of the Anghiari ridge. We focus on the latter.
Detailed geomorphological analysis, geological mapping and near-surface geophysics, enabled us to select two sites for palaeoseismological trenching. Radiocarbon dating of faulted sediments provides constraints for late Holocene and historical surface faulting events significantly contributing to the estimation of the seismic hazard in the region.

How to cite: testa, A., Boncio, P., Baize, S., Mirabella, F., Pucci, S., Pauselli, C., Ercoli, M., Riesner, M., Pace, B., and Benedetti, L.: Palaeoseismological constraints on the Anghiari normal fault (Northern Apennines, Italy): first results., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10362, https://doi.org/10.5194/egusphere-egu22-10362, 2022.

EGU22-11135 | Presentations | TS4.2 | Highlight

Interactive map of seismic hazard for nuclear facilities, Czech Republic 

Renata Lukešová, Jiří Málek, Jiří Vackář, Jan Valenta, Lucia Fojtíková, Ivan Prachař, and Barbora Lachová

The main aim of this project is create an interactive map of seismic hazard of the territory of the Czech Republic and the system of its upgrading. The map will fulfill the recommendation of the International Atomic Energy Agency for evaluation of seismic hazard at the sites of nuclear facilities. It will serve as the background material during the process of approving of seismic safety of nuclear infrastructure. The interactive map will enable also to improve seismic hazard assessment for non-nuclear buildings, facilities and infrastructure. The system of continual upgrading will enable to include the new scientific results in the field of seismic hazard and experience from new earthquakes.

Czech Republic is situated in an intraplate region with low seismicity. The seismic hazard is relatively low, but not negligible. The seismic hazard is evaluated by probabilistic seismic hazard method, including construction of logic tree and deriving of seismic hazard curves. In areas, where no or just a few weak events are recorded, but significant earthquakes can occur from both geological and seismological point of view, the concept of diffused seismicity is applied.

Historical catalogs in weak-seismic regions cover a much shorter period than the average time between the strong (controlling) earthquakes. This cause a complicate evaluation of focal zone maximal magnitude parameter. Hence, a new method of maximal magnitude determination was developed. It uses Bayesian approach combining a priori information from wider region with historical earthquake catalogue resulting in probability distribution of maximum magnitude.

For the evaluation of the local conditions, the new Vs30 map of Czech Republic is prepared. The map combines method of Wald and Allen (2007), using topographic slope as a proxy for seismic site conditions and amplification, and new Vs30 field measurements on multiple locations in the area of study.

References:

Wald, J.W. and Allen, T.I (2007): Topographic Slope as a Proxy for Seismic Site Conditions and Amplification, doi: 10.1785/0120060267.

How to cite: Lukešová, R., Málek, J., Vackář, J., Valenta, J., Fojtíková, L., Prachař, I., and Lachová, B.: Interactive map of seismic hazard for nuclear facilities, Czech Republic, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11135, https://doi.org/10.5194/egusphere-egu22-11135, 2022.

EGU22-11609 | Presentations | TS4.2

Towards integrating information about strain rates in PSHA models in Europe: comparison between seismic moment rates from ESHM20 model and geodetic estimates 

Bénédicte Donniol, Anne Socquet, Celine Beauval, Jesús Piña-Valdès, Laurentiu Danciu, and Shyam Nandan

Most national and international seismic regulations require quantifying seismic hazard based on probabilistic seismic hazard assessment (PSHA) methods. The probabilities of exceeding ground-motion levels at sites of interest over a future time window are determined by combining a source model and a ground-motion model. This research work aims at understanding how the measurement of strain rates by geodesy can provide constraints on the source model.

Earthquake catalogs, merging instrumental and historical data, are usually used to establish earthquake recurrence models. Although these catalogs extend over several centuries, the observation time windows are often short with respect to the recurrence times of moderate-to-large events and in some regions the recurrence models can be weakly constrained.

Here, we compute different realizations of strain rates maps over Europe using a combined velocity field (Piña Valdes et al., JGR submitted). These strain rates are compared to the source model of the new European seismic hazard model (ESHM20, Danciu et al. 2021). More precisely, the moment rates estimated from the earthquake recurrence models are compared to the geodetically-derived moment rates.

We explore the different uncertainties in both models. For geodesy, we integrate uncertainties on the velocities at each station, and the epistemic uncertainties on the different steps of the computation of the geodetic moment rate : filtering of the velocity field (outliers’ removal and smoothing) (Piña-Valdés et al, JGR submitted), parameters used to drive the strain inversion with VISR software (Shen et al. 2015), constants and formula used for the moment computation. The goal is to quantify the impact of each parameter uncertainty or decision on the moment computation.

The first results show that a correlation exists between the seismically and geodetically derived moment rates. In general, the main uncertainty is on the velocities at each stations, followed by the depth taken into account for the moment computation. In areas characterized by high activity, such as Betics or Apennines for example, the moment rates derived by both methods are comparable. In areas of lower activity, such as at the interior of plates, the error associated with geodetic measurements is of the same order of magnitude as the measured strain, and the relation between catalog-based and strain-based moment is not straightforward.

How to cite: Donniol, B., Socquet, A., Beauval, C., Piña-Valdès, J., Danciu, L., and Nandan, S.: Towards integrating information about strain rates in PSHA models in Europe: comparison between seismic moment rates from ESHM20 model and geodetic estimates, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11609, https://doi.org/10.5194/egusphere-egu22-11609, 2022.

EGU22-12054 | Presentations | TS4.2 | Highlight

3D GNSS Velocity Field sheds light on the Deformation Mechanisms in Europe:  effects of the vertical crustal motion on the distribution of seismicity 

Anne Socquet, Jesus Piña Valdes, Céline Beauval, Marie Pierre Doin, Nicola D'Agostino, and Zhengkang Shen

Crustal deformation and seismicity in Europe are still poorly understood. Seismic activity is classically ascribed to crustal strain rates generated by tectonic deformation. However, crustal deformation is not only due to tectonic loading, but can also be related to isostatic and buoyancy processes that induce additional strains on the crust by flexure. The influence that those processes have on seismic activity, as well their interaction, is still controversial, and the main limitation to study it is because the deformation processes are commonly analyzed separately in small regions. We present here a 3D secular velocity field that covers Eurasia and its plate boundaries including 4508 GNSS stations obtained by combining 10 different datasets. We have developed a method based on spatial filtering to identify outliers and smooth the velocity field, and have computed a strain rate map representative of the main deformation processes that affect Europe. The vertical and horizontal deformation features were compared with earthquake recurrence models obtained from the spatial and temporal distribution of the seismicity in Europe. Our results suggest that is not possible to explain the seismicity of Europe based on the horizontal strain rate maps only. In some areas markers of the crustal flexure such as the vertical velocity field and its derivative, may help to interpret earthquake distribution models derived from geodetic data.

How to cite: Socquet, A., Piña Valdes, J., Beauval, C., Doin, M. P., D'Agostino, N., and Shen, Z.: 3D GNSS Velocity Field sheds light on the Deformation Mechanisms in Europe:  effects of the vertical crustal motion on the distribution of seismicity, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12054, https://doi.org/10.5194/egusphere-egu22-12054, 2022.

EGU22-932 | Presentations | TS4.4

Structural setting, active tectonics and seafloor morphology of the northeastern Calabria accretionary prism (Ionian Sea, Italy) 

Lorenzo Lipparini, Andrea Argnani, Giulia Sgattoni, Claudio Pellegrini, Marzia Rovere, and Irene Molinari

The Calabrian accretionary prism is the result of a complex interaction between subduction-related tectonics and sedimentation, active since the Eocene. The limited seismicity recorded in recent years in the area appears mostly associated to the subduction interface and could reflect either a weak subduction coupling or a slow subduction rate. Nevertheless, recent intense deformation and uplift of the seafloor has been observed within the accretionary prism.

The analysis of multichannel 2D and high-quality 3D seismic data, morphobathymetric data and instrumental seismicity, allows defining and characterizing both the deeper and shallower tectonic deformation affecting the northeastern sector of the Calabrian accretionary prism. 

Besides the uppermost thrust fault of the Calabrian accretionary prism, that outlines the Crotone promontory, the shallow tectonic pattern of the prism is characterized by a belt of broad flat-topped anticlines, and a set of minor narrow structures, mainly NNW-SSE to N-S oriented, that present a variable relationship with the underlying main thrust faults. The uppermost sedimentary strata within the anticlines are affected by numerous small-scale extensional faults, not rooted at depth, likely due to outer-arc extension above uplifted depocenters. In places, the inversion of basin-bounding faults is also visible. More regularly spaced and cylindrical NW-SE anticlines are also observed in the Gulf of Taranto, in the outer sector of the accretionary prism, where a thrust/back-thrust tectonic style is present. The origin of the anticlines varies within the overall set and reflects the long-term tectonic evolution of the accretionary prism, with the oblique docking of the Calabrian accretionary prism onto the Apulian Escarpment as a key feature.

How to cite: Lipparini, L., Argnani, A., Sgattoni, G., Pellegrini, C., Rovere, M., and Molinari, I.: Structural setting, active tectonics and seafloor morphology of the northeastern Calabria accretionary prism (Ionian Sea, Italy), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-932, https://doi.org/10.5194/egusphere-egu22-932, 2022.

EGU22-1588 | Presentations | TS4.4 | Highlight

Tracking past earthquakes along the Japan Trench:  Fresh initial results from the IODP Japan Trench Paleoseismology Project 

Michael Strasser, Ken Ikehara, Jeremy Everest, and Lena Maeda and the IODP Expedition 386 Science Party

Short historical and even shorter instrumental records limit our perspective of earthquake maximum magnitude and recurrence, and thus are inadequate to fully characterize Earth’s complex and multiscale seismic behavior and its consequences. Examining prehistoric events preserved in the geological record is essential to reconstruct the long-term history of earthquakes and to deliver observational data that help to reduce uncertainties in seismic hazard assessment for long return periods. Motivated by the mission to fill the gap in long-term records of giant (Mw 9 class) earthquakes such as the Tohoku-Oki earthquake in 2011, International Ocean Discovery Program (IODP) Expedition 386, Japan Trench Paleoseismology, was designed to test and further develop submarine paleoseismology in the Japan Trench.

Earthquake rupture propagation to the trench and sediment remobilization related to the 2011 Mw 9.0 Tohoku-Oki earthquake, and the respective structures and deposits are preserved in trench basins formed by flexural bending of the subducting Pacific Plate. These basins are ideal study areas for testing event deposits for earthquake triggering as they have poorly connected sediment transport pathways from the shelf and experience high sedimentation rates and low benthos activity (and thus high preservation potential) in the ultra-deep water hadal environment. Results from conventional coring covering the last ~1,500 y reveal good agreement between the sedimentary record and historical documents. Subbottom profile data are consistent with basin-fill successions of episodic muddy turbidite deposition and thus define clear targets for paleoseismologic investigations on longer timescales accessible only by deeper coring.

In 2021, IODP Expedition 386 successfully collected 29 Giant Piston cores at 15 sites (1 to 3 holes each; total core recovery 831 meters), recovering 20 to 40-meter-long, continuous, upper Pleistocene to Holocene stratigraphic successions of 11 individual trench-fill basins along an axis-parallel transect from 36°N – 40.4°N, at water depth between 7445-8023 m below sea level. The cores are currently being examined by multimethod applications to characterize and date event deposits for which the detailed stratigraphic expressions and spatiotemporal distribution will be analyzed for proxy evidence of giant versus smaller earthquakes versus other driving mechanisms. Initial preliminary results presented in this EGU presentation reveal event-stratigraphic successions comprising several 10s of potentially giant-earthquake related event beds, revealing a fascinating record that will unravel the earthquake history of the different along-strike segments, that is 10–100 times longer than currently available information. The data set will enable a statistically robust assessment of the recurrence patterns of giant earthquakes as input for improved probabilistic seismic hazard assessment and advanced understanding of earthquake-induced geohazards globally. 

 

How to cite: Strasser, M., Ikehara, K., Everest, J., and Maeda, L. and the IODP Expedition 386 Science Party: Tracking past earthquakes along the Japan Trench:  Fresh initial results from the IODP Japan Trench Paleoseismology Project, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1588, https://doi.org/10.5194/egusphere-egu22-1588, 2022.

EGU22-2942 | Presentations | TS4.4

The Plio-Quaternary activity of the Yusuf Fault System (Alboran Sea; Westernmost Mediterranean): From 3D deep structure to seafloor geomorphology 

Hector Perea, Sara Martínez-Loriente, Jaume Llopart, Ariadna Canari, Laura Gómez de la Peña, Rafael Bartolomé, and Eulàlia Gràcia

The identification and seismic characterization of the active structures in the Alboran Sea (westernmost Mediterranean) are essential to evaluate better the exposure of the South Iberian Peninsula and Maghreb coasts to different natural hazards. The Alboran Sea accommodates part of the present-day crustal deformation related to the NW-SE convergence (4-5 mm/yr) between the African and Eurasian plates. The area is characterized by low to moderate magnitude instrumental seismicity. However, large earthquakes (I > IX and M > 6.0) have occurred in this region in historical and recent times (i.e., 1522 Almeria, 1790 Oran, 1910 Adra, 1994 and 2004 Al-Hoceima or 2016 Al-Idrissi earthquakes). The dextral strike-slip Yusuf Fault System (YFS) is one of the largest active faults in the Alboran Sea and its seismogenic and tsunamigenic hazard needs to be characterized. The fault system trends WNW-ESE and has a length of ~150 km. Using multi-scale bathymetric (ranging from m to cm) and seismic data and different morphological and seismic analysis tools (i.e., slope or relief image maps), we have imaged and characterized the fault system. The analysis of this dataset reveals that the YFS is a complex structure composed of an array of strike-slip faults. The 3D structural model shows that most of the identified faults reach up and offset the seafloor and the Upper Quaternary sedimentary units. The current morphology of the seafloor is a consequence of the Plio-Quaternary tectonic evolution that have resulted in the formation of a large pull-apart basin, which is deeper than the surrounding areas, a topographic ridge, an elongated depression and morphologic lineaments following its trend. The dataset also images several submarine landslides scars, mainly on the steeper slopes surrounding the pull-apart basin. In addition, the analysis of ultra-high resolution data acquired along the Yusuf lineament with AUV has revealed the presence of a series of en-echelon scarps with heights ranging from few centimeters to less than 10 meter. Seismic profiles across these scarps show that they are related to different fault strands of the YFS that are offsetting the seafloor, possibly because of an earthquake occurred in historical times.

How to cite: Perea, H., Martínez-Loriente, S., Llopart, J., Canari, A., Gómez de la Peña, L., Bartolomé, R., and Gràcia, E.: The Plio-Quaternary activity of the Yusuf Fault System (Alboran Sea; Westernmost Mediterranean): From 3D deep structure to seafloor geomorphology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2942, https://doi.org/10.5194/egusphere-egu22-2942, 2022.

In southwestern Japan, the northwestward subduction of the Philippine Sea plate beneath the Eurasian plate results in large magnitude (>8) earthquakes and tsunamis (e.g. 1944 Tonankai and 1946 Nankaido earthquakes) and slow earthquakes at the Nankai margin. As part of the Nankai Trough Seismogenic Zone Experiment (NanTroSEIZE), Long Term Borehole Monitoring Systems (LTBMSs), a suite of high-sensitivity borehole sensors providing real-time observations of hydrologic processes and crustal deformation, were installed from 2010 at 3 boreholes of the International Ocean Discovery Program (IODP).  

The pore pressure recorded by the LTBMSs, used as a proxy for volumetric strain, shows transient variations associated with slow slip events (Araki et al., 2017). Similar observations have been made at other subduction zones, like the north Hikurangi margin (e.g. Wallace et al., 2016), highlighting the key role of hydromechanical properties in fault mechanics and processes. The LTBMSs also capture the pore pressure oscillations arising from Earth tides forcing, with diurnal (~24 h) and semidiurnal (~12 h) periods. The phase and amplitude of the tidal signal can be decomposed from the observational data using tidal analysis programs, providing an opportunity to monitor changes related to the hydraulic and poroelastic responses to tectonic loading and transient loading arising from SSEs.

In this study, we use BAYTAP-08 (Tamura and Agnew, 2008), a modified version of the Bayesian Tidal Analysis Program - Grouping Model program of Tamura et al. (1991), to extract the tidal response from the pore pressure recorded at different depth intervals, at three sites: above the updip limit of the locked seismogenic zone at Site C0002 (first-time LTBMS deployment in 2010), at the megasplay fault zone and its footwall at Site C0010 (since 2016) and at the frontal thrust of the accretionary prism at Site C0006 (since 2018).

Tidal amplitudes and phases of semi-diurnal and diurnal tide components were carefully checked for any possible temporal variations, that may be related to subseafloor strain accumulation or coseismic release. We focused on the M2 and O1 canonical components.

Using a 1D poroelastic model, the analytic solution for tidal amplitude and phase was derived and compared with observations. The average amplitude ratio (relative to the seafloor) is 0.62-0.66, which is lower than the theoretical loading efficiency value. The phase lag difference is <1° for all depth intervals, as predicted by the 1D poroelastic theory for the range of permeability values (10-15 to 10-19 m²) determined from core samples (e.g. Reuschlé, 2011; Rowe et al., 2011; Tanikawa et al., 2012, 2014; Chen, 2015; Dutilleul, 2021) or drilling data (e.g. Pwavodi and Doan, 2021). This may be caused by the borehole casing or the LTBMS assembly itself. More careful inspection is on the way.

The removal of the tidal signal computed with BAYTAP-08 provides a clearer residual (i.e. non-tidal) pore pressure signal, which seems to have a long-term variation. It may either be the instrumental drift, but may be related to potential subseafloor strain modulations related to plate convergence and seismic activities.

How to cite: Dutilleul, J. and Kinoshita, M.: Tidal analysis of the NanTroSEIZE Long Term Borehole Monitoring System (LTBMS) pore pressure records at the Nankai margin, SW Japan., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4332, https://doi.org/10.5194/egusphere-egu22-4332, 2022.

EGU22-4835 | Presentations | TS4.4

Submarine landslides triggered by the 1663 earthquake (M>7) in the St. Lawrence Estuary, Quebec, Canada 

Méril Mérindol, Guillaume Saint-Onge, Nabil Sultan, Patrick Lajeunesse, and Sébastien Garziglia

In eastern Canada, the Charlevoix-Kamouraska/Bas-Saint-Laurent (CKBSL) seismic zone presents a seismic hazard almost as high as the active Pacific zone. The major event of February 5, 1663, with a magnitude estimated at > 7 highlights this important seismic hazard. The numerous submarine landslides mapped in the St. Lawrence Estuary in the CKBSL seismic zone suggest that earthquakes have acted as a trigger for submarine slope failures. In this context, the SLIDE-2020 expedition on board the RV Coriolis II in the St. Lawrence Estuary aimed to map, image and sample more than 12 zones of submarine instabilities and their associated deposits. The analysis of sediment cores sampled in the distal sedimentary deposits from these landslides reveals the presence of rapidly deposited layers (turbidites and debrites) directly linked to the submarine landslides. Dating of these landslides with 210Pb and 14C techniques led to the identification of four periods of synchronous emplacement corresponding to the strongest historical earthquakes: 1663 AD, 1860/1870 AD, 1925 AD and 1988 AD. This synchronicity over a distance reaching 220 km of several landslides supports a relationship between their triggering in the St. Lawrence Estuary and regional seismicity. The fact that as many as 9 submarine landslides appear to have been triggered by the 1663 AD earthquake indicates that this event is the strongest recorded in the last two millennia.

Keywords: 1663 earthquake, Canada, Geohazards, Geophysics, Holocene, Quebec, Paleoseismicity, Sedimentology, Submarine landslides.

How to cite: Mérindol, M., Saint-Onge, G., Sultan, N., Lajeunesse, P., and Garziglia, S.: Submarine landslides triggered by the 1663 earthquake (M>7) in the St. Lawrence Estuary, Quebec, Canada, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4835, https://doi.org/10.5194/egusphere-egu22-4835, 2022.

For many countries, the methodology for offshore geohazards mitigation lags far behind the well-established onshore methodology. Particularly complicated is the mapping of active faults. One possibility is to follow the onshore practice, i.e., identifying a sub-seabed Holocene horizon and determining whether it displaces this horizon for each fault. In practice, such an analysis requires numerous coring and often ends without an answer.   

Here we suggest a new approach aimed for master planning. Based on high-quality seismic data, we measure for each fault the amount of its recent (in our specific case 350 ky) displacement and the size of its plane. According to these two independently measured quantities, we classify the faults into three hazard levels, highlighting the “green” and “red” zone for planning.

Our case study is the Israeli continental slope, where numerous salt-related, thin-skinned, normal faults dissect the seabed, forming tens of meters high scarp, which are crossed by gas pipelines. A particular red zone is the upper slope south of the Dor disturbance, where a series of big listric faults rupture the seabed in an area where the sedimentation rate is four times faster than the displacement rate. We suggest that this indicates seismic rupture rather than creep.

How to cite: Laor, M. and Gvirtzman, Z.: Classifying offshore faults for hazard assessment: A new approach based on fault size and vertical displacement, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7112, https://doi.org/10.5194/egusphere-egu22-7112, 2022.

EGU22-11083 | Presentations | TS4.4

Identification and 3D modeling of active faults in the Dubrovnik (Croatia) offshore area – preliminary results 

Marin Sečanj, Bruno Tomljenović, Josip Stipčević, Helena Latečki, and Iva Dasović

The wider region around the city of Dubrovnik, encompassing coastal and offshore area of southern Croatia, is characterized by the relatively high seismicity rate with intermittent occurrence of strong events indicating the ongoing tectonic activity. Historical, instrumental and paleoseismological records show that this area was hit by at least dozen strong earthquakes in the last 500 years. Among these the most significant is the Great Dubrovnik earthquake from 1667 which devastated the region. This and other strong events of this area are related to several individual to composite seismogenic sources that generally extends in NW-SE direction from Albania to the central part of External Dinarides fold-thrust-belt in Croatia, still however, not yet sufficiently known in great details. Here, we aim to present preliminary results of identification and 3-D modeling of distribution and geometry of active faults in the offshore Dubrovnik area, based on analyses of reflection seismic profiles associated with deep borehole and surface geology data provided by the Croatian Hydrocarbon Agency.

Identification and classification of recently active faults in this area were performed by matching at least one of the following criteria: (1) offsets of the Pliocene - Quaternary deposits along faults that could be correlated between neighboring seismic lines, (2) deformation of Pliocene - Quaternary deposits above fault tips and (3) correlation of fault geometry and kinematics with distribution of the earthquake hypocenters and available fault plane solutions. In addition, a long-term neotectonic activity of identified faults has been studied by deformation and truncation of Miocene and Pliocene stratigraphic horizons that are frequently found affected by faults closely related with a long-term salt tectonics activity.

Location and geometry of the identified recently active faults are in good correlation with distribution of instrumentally recorded earthquake locations, where certain events are clustered within narrow zones of delineated fault planes. These preliminary results will be used for 3D geological and structural modelling of active earthquake generating fault systems between the city of Dubrovnik and the town of Ston, cross-section balancing and slip-rate calculation along active faults. In turn, these would provide input data for seismic shaking simulation and future seismic hazard assessment in this area.

How to cite: Sečanj, M., Tomljenović, B., Stipčević, J., Latečki, H., and Dasović, I.: Identification and 3D modeling of active faults in the Dubrovnik (Croatia) offshore area – preliminary results, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11083, https://doi.org/10.5194/egusphere-egu22-11083, 2022.

EGU22-11506 | Presentations | TS4.4

Submarine active tectonics in the south and northwest Iberian margins 

Adrià Ramos, Luis Somoza, Teresa Medialdea, Pedro Terrinha, and Juan-Tomás Vázquez

The Iberian Peninsula is surrounded to the north by the convergence margin between Eurasia and the former Iberian plates (North and Northwest Iberian margin), and to the south by a transform plate boundary between Eurasia and Nubia (Gulf of Cádiz) to a shear-compressive indentation of Nubia northwards in the Alborán Sea. These margins are affected by historic and present-day seismicity, which are linked to active tectonic structures deforming the seafloor of the margins. The main objective is to better understand their development in the framework of the present plate organization and thus evaluate the seismic hazard around Iberia. Therefore, we carried out an extensive geophysical characterization of submarine faults, focusing on those that show seabed morphological expressions, by mapping them with high-resolution swath bathymetry data, high-resolution parametric sub-bottom profiles and multichannel 2D seismic profiles. Their activity and distribution are in good agreement with the geodetic and seismological observations.

Our results show that the present-day active tectonics and its related deformation, including seismicity and tsunami-affected coastal areas, are mainly located in the south Iberian margin, around the boundary between the Eurasian and Nubia tectonic plates. The submarine active faults are represented in this margin by a large strike-slip fault system and fold-thrust systems, in response to the NW-SE convergence between the aforementioned tectonic plates. The different orientation and distribution of submarine faults, and the fault type from focal mechanism of seismic events, led us to identify simple and pure shear zones from the Alborán Sea to the east, to the Gibraltar Arc and Gulf of Cadiz to the west. This suggests a strain partitioning model along the plate boundary in response to the present-day shear stress orientation.

Deformation is also documented in the NW Iberian margin. Thrust fault systems with high seismic activity were identified and mapped along Iberian ocean-continent transition around the Galician and Portuguese margins, reflecting the re-activation of former Cenozoic faults. Deformation in this margin is also derived from the westward motion of the Iberian oceanic domain and the clockwise rotation of the Iberian continental domain with respect to the Eurasian plate.

How to cite: Ramos, A., Somoza, L., Medialdea, T., Terrinha, P., and Vázquez, J.-T.: Submarine active tectonics in the south and northwest Iberian margins, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11506, https://doi.org/10.5194/egusphere-egu22-11506, 2022.

EGU22-12537 | Presentations | TS4.4

Structural reconstruction and Quaternary evolution of the buried thrust in the central Adriatic Sea (Italy). 

Francesco Emanuele Maesano, Giovanni Toscani, Yuri Panara, and Roberto Basili

Whenever sedimentation exceeds the tectonic rate, the detection and investigation of active faults become challenging, especially when the investigated area is offshore. The coastal area of the central Adriatic is characterized by the presence of Plio-Pleistocene thrusts, which strongly controlled the evolution of the Apennines foredeep. Apart from the significant exception of the Conero promontory, these thrusts are all blind and have no significant signature in the bathymetry. Nonetheless, the coastal and offshore central Adriatic has experienced some moderate-magnitude seismic sequences related to the frontal thrusts on either side, belonging to the Apennines and the Dinarides chains.

In the last years, multiple studies conducted along the Apennine orogeny assessed the Plio-Pleistocene slip rates using different approaches and methodologies. Fault plane dimensions and attitude are key parameters for seismotectonic information fed into seismic and tsunami hazard analyses. In this work, we present the interpretation of two regional seismic reflection profiles across the central Adriatic, calibrated with the available well-logs, which show the evolution of the thrust system in space and time and their influence on the development of the Apennines foredeep and help to put some constraints to understand the most recent tectonic history of the region.

How to cite: Maesano, F. E., Toscani, G., Panara, Y., and Basili, R.: Structural reconstruction and Quaternary evolution of the buried thrust in the central Adriatic Sea (Italy)., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12537, https://doi.org/10.5194/egusphere-egu22-12537, 2022.

EGU22-12572 | Presentations | TS4.4

A releasing-bend at the northern termination of the Alfeo-Etna shear zone (Western Ionian Sea, Italy): seismotectonic implications and relation with Mt. Etna volcanism 

Carmelo Monaco, Giovanni Barreca, Valentina Bruno, Giorgio De Guidi, Carmelo Ferlito, Salvatore Gambino, Felix Gross, Mario Mattia, and Luciano Scarfì

Offshore data in the western Ionian Sea indicate that the NW-SE trending dextral shear zone of the Alfeo-Etna fault system turns to N-S direction near the Ionian coastline, where the Timpe fault system occurs. This latter deform the lower eastern slope of Mt. Etna, showing NNW-SSE to NNE-SSW orientation and resulting from E-W trending regional extension. They are seismically active having given rise to shallow and low-moderate magnitude earthquakes in the last 150 years. Morpho-structural data show that NW-SE trending right-lateral strike-slip faults connect the Timpe fault system with the upper slope of the volcano, where the eruptive activity mainly occurs along N-S to SW-NE trending fissures. As a whole, morpho-structural, geodetic and seismological data, seismic profiles and bathymetric maps suggest that similar geometric and kinematic features characterize the shear zone both on the eastern flank of the volcano and in the Ionian offshore. The Alfeo-Etna fault system probably represents a major kinematic boundary in the western Ionian Sea associated with the relative motion of Africa and Eurasia since it accommodates, by dextral transtensional kinematics, diverging motions in adjacent western Ionian compartments. Along this major tectonic alignment, crustal structures such as releasing bends, pull-apart basins and extensional horsetails occur both offshore and on-land, where they probably represent the pathway for magma uprising from depth.

How to cite: Monaco, C., Barreca, G., Bruno, V., De Guidi, G., Ferlito, C., Gambino, S., Gross, F., Mattia, M., and Scarfì, L.: A releasing-bend at the northern termination of the Alfeo-Etna shear zone (Western Ionian Sea, Italy): seismotectonic implications and relation with Mt. Etna volcanism, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12572, https://doi.org/10.5194/egusphere-egu22-12572, 2022.

EGU22-879 | Presentations | TS4.5

Imaging evolution of Cascadia slow-slip event using high-rate GPS 

Yuji Itoh, Yosuke Aoki, and Junichi Fukuda

The short-term slow slip event (SSE), a class of slow earthquakes which has duration of a few to tens of days, is typically detected and modeled from daily static Global Positioning System (GPS) data. However, the daily GPS data cannot image the sub-daily SSE processes, so underlying mechanisms of SSEs have been still elusive. By processing the raw GPS observables in the kinematic analysis approach, we can obtain surface deformation field at the subdaily interval, which has great potential to overcome the time resolution issue present in the daily static GPS data. Although the kinematic GPS coordinates are known much noisier (~ cm) than the daily static coordinates (~ a few mm), recent applications to postseismic deformation studies achieved identifying sub-cm deformation. Motivated by them, we for the first time applied the kinematic GPS coordinates to model the short-term SSE.

We chose one Cascadia SSE in March – April 2017, which has been already reported from daily GNSS data, and performed the kinematic GPS analysis at a 30-second interval for observations during the event occurrence. Although the obtained raw coordinate series were quite noisy, we were able to discern the transient motion of a few mm during the event after carefully removing non-tectonic position fluctuation such as multipath effects, common mode errors and outliers.

Then, we inverted the cleaned data at a 30-minute interval using a Kalman-filter based method to infer spatiotemporal evolution of slip. The obtained spatiotemporal slip distribution exhibits a multi-stage evolution consisting of an isotropic growth of SSE and subsequent along-strike migration and termination. The transition of the slip growth mode occurs when the slip area fills the rheologically permitted down-dip width for the SSE occurrence. As conceptualized by Gomberg et al. (2016, GRL), this is analogous to the rupture growth of regular great earthquakes, so it implies the presence of common mechanical factors behind the two distinct slip phenomena. The inferred moment rate has two peaks, which are consistent with the daily tremor counts in this region.

We carried out another slip inversion using the daily static GPS data recorded during the same period and the same inversion method to investigate the performance and limitation of our kinematic GPS data. A moment rate inferred from the daily data has also two peaks, so our 30-minute inversion result has the comparable time resolution to that derived from the widely-used daily data. This is an astonishing result given the long-believed low signal-to-noise ratio of the kinematic GPS. Our results strongly highlight the importance of better understanding of the non-tectonic noise in the kinematic GPS analysis, which will further improve the temporal resolution of SSE.

How to cite: Itoh, Y., Aoki, Y., and Fukuda, J.: Imaging evolution of Cascadia slow-slip event using high-rate GPS, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-879, https://doi.org/10.5194/egusphere-egu22-879, 2022.

EGU22-943 | Presentations | TS4.5

Relative contribution of afterslip, non-linear viscous, and poroelastic processes to the early postseismic deformation field of the 2010 Maule earthquake 

Carlos Peña, Sabrina Metzger, Oliver Heidbach, Jonathan Bedford, Bodo Bookhagen, Marcos Moreno, Onno Oncken, and Fabrice Cotton

Large earthquakes impose differential stresses in the crust and upper mantle that are transiently relaxed during the postseismic phase mostly due to afterslip on the fault interface, viscoelastic relaxation in the lower crust and upper mantle, and poroelastic rebound in the upper crust. During the last years, the wealth of geophysical and geodetic observations, as well as great effort in forward and inverse modelling have allowed a better comprehension of the role of these mechanisms during the postseismic period. However, it is still an open question to what extent postseismic processes contribute to the surface deformation signal, especially during the early postseismic period. In this study, we use GNSS and InSAR observations collected in the first 48 days following the 2010 Maule earthquake in Chile along with a model approach that integrates afterslip, poroelasticity, and temperature-controlled power-law (non-linear viscosity) rheology. The afterslip distribution is obtained from a geodetic data inversion after removing the poro-viscoelastic component by forward modelling to the geodetic data. We find that our model approach explains the geodetic cumulative signal 14% better than a pure elastic model inverting for afterslip. This improvement is mainly produced by the better fit to the geodetic signal at the volcanic and back-arc regions due to the inclusion of non-linear viscoelastic processes, which can explain > 60% of the observed surface displacements in these regions. We also show that poroelastic processes play a significant role locally, specifically near the region where the coseismic slip was largest. Here, poroelastic processes explain most of the cumulative observed GNSS uplift signal and produce surface landward patterns that affect the horizontal GNSS component by up to 15% in the opposite direction. If poroelastic processes are ignored, our results reveal that the resulting afterslip amplitude is both amplified and suppressed by up to 40% in regions of ~50 x 50 km2. Our findings have implications for the calculation of the postseismic slip budget, and therefore the seismic hazard assessment of future earthquakes.

How to cite: Peña, C., Metzger, S., Heidbach, O., Bedford, J., Bookhagen, B., Moreno, M., Oncken, O., and Cotton, F.: Relative contribution of afterslip, non-linear viscous, and poroelastic processes to the early postseismic deformation field of the 2010 Maule earthquake, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-943, https://doi.org/10.5194/egusphere-egu22-943, 2022.

Tectonic pseudotachylytes are produced by rapid sliding and melting, and then solidified fast in faults during earthquakes, which are considered as fossil earthquake. Pseudotachylytes record the physical-chemical processes related to earthquake in fault zone, which are essential materials for understanding the history of fault activity.  Here we focus on the pseudotachylytes and cataclastic rocks in the East Yibug Caka fault, SN-trending normal fault in the Qiangtang terrane, in the hinterland of the Tibetan Plateau. Combined optical microscope, scanning electron microscope, powder X-ray diffraction (XRD) with in situ X-ray fluorescence (XRF) analyses, their microstructures, mineral composition and elemental distribution were analyzed in detail. Field investigation shows that the dark gray to brown in color pseudotachylytes, associated with cataclastic rocks, are occurred as fault veins and injection veins with thickness ranging from a few mm to 1 cm. Microstructural observations show that multiple lines of evidence, such as embayed quartz fragments, honeycomb-like vesciles and locally developed microcrystallines and cluster aggregates, indicate that the pseudotachylytes were the products of frictional melting during the seismic slip. In addition, pseudotachylytes present as clasts in cataclastic rocks and fault breccias, and younger cataclastic rocks contain breccia of earlier cataclastic rocks, these characteristcs indicate that large seismic events occurred repeatedly in this fault zone. Considering the initial active time of the normal faults in this area is 13.5 Ma, the formation depth of the pseudotachylytes and associated cataclastic rocks is 10 km, the exhumation rate of the these fault rocks from deep depth is at least ~0.74 mm/yr. Pseudotachylytes along normal faults are seldom reported, this is the first time that we find melt-origined pseudotachylytes in the SN-trending normal faults in the Qiangtang terrane, and where present they have important implications for learning regional seismic activity and fault evolution process.

How to cite: Wang, H., Li, H., Sun, Z., and He, X.: Discovery of the pseudotachylytes in the Qiangtang Rift, Tibet, and their petrological characteristics and tectonic significance, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1052, https://doi.org/10.5194/egusphere-egu22-1052, 2022.

EGU22-2393 | Presentations | TS4.5

Weak, Seismogenic Faults in the Lower Crust 

Sam Wimpenny

Earthquake-generating faults are typically confined to the upper 10-15 km of the crust, with the middle and lower crust deforming aseismically. Along the margins of Earth’s highest mountain ranges, however, seismicity can extend throughout the whole crust, from the surface to depths of 30-50 km in rocks at temperatures of 400-600 degrees. For earthquakes to take place at such high temperatures, the lower crust is thought to have an extremely dry (anhydrous) mineralogy, such that elastic strain is not relaxed by creep.

In this study, I will discuss the mechanical properties of earthquake-generating faults in the lower crust around the Andes mountains. I will use force-balance calculations to demonstrate that faults within the lower crust can be frictionally very weak, with an average effective static coefficient of friction <0.2. The mechanisms invoked to generate similar frictionally-weak, earthquake-generating faults in the upper crust appeal to the presence of highly-pressurised water, or water-driven alteration of the fault core to form phyllosilicate minerals. However, the dry mineralogy thought to necessitate elastic strain accumulation in the lower crust should preclude abundant free water within these faults by acting as a `sponge’, soaking up free water in hydration reactions. The geological controls on the frictional properties of earthquake-generating, lower-crustal faults remain a conundrum.

How to cite: Wimpenny, S.: Weak, Seismogenic Faults in the Lower Crust, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2393, https://doi.org/10.5194/egusphere-egu22-2393, 2022.

EGU22-2415 | Presentations | TS4.5

Field, microstructural and phase characterization of mirror-like fault surfaces in bituminous dolostones (central Apennines, Italy) 

Miriana Chinello, Elena Bersan, Michele Fondriest, Telemaco Tesei, Sveva Corrado, and Giulio Di Toro

Mirror-like surfaces (MSs) are easily recognizable in the field since they reflect natural visible light, thanks to their low surface roughness (nm-scale). These ultra-polished surfaces are often found in seismogenic fault zones cutting limestones and dolostones (e.g., Siman-Tov et al., 2013; Fondriest et al., 2013; Ohl et al., 2020). Both natural and experimentally-produced fault-related MSs were described in spatial association with ultrafine matrix (grain size <10µm), nanograins (<100nm in size), amorphous carbon, decomposition products of calcite/dolomite (i.e., portlandite, periclase) and larger in size but “truncated” clasts (Verberne et al., 2019). However, the mechanism of formation of MSs is still a matter of debate. Indeed, experimental evidence shows that MSs can develop both under seismic (slip rate ≈1 m/s; Fondriest et al., 2013; Siman-Tov et al., 2013; Pozzi et al., 2018; Ohl et al., 2020), and aseismic (slip rate ≈0.1-10 µm/s; Verberne et al., 2013; Tesei et al., 2017) deformation conditions, involving various physical-chemical processes operating over a broad range of P-T conditions, strain, and strain rates.

To better constrain the formation mechanism of MSs and their role in the seismic cycle, field, and high-resolution microstructural investigations, combined with thermal maturity analyses, were conducted on MSs cutting Triassic bituminous dolostones from the Italian Central Apennines. This region is one of the most seismically active areas in the Mediterranean (e.g., L’Aquila 2009, Mw 6.3 earthquake), with mainshocks and aftershocks propagating along extensional faults, cutting km-thick sequences of carbonates. The studied faults are hosted in the footwall of the younger-on-older Monte Camicia thrust, related to the Pliocene to Holocene in age Apenninic compressional to extensional tectonics and exhumed from < 4 km depth. The MSs samples were collected from faults with evidence of increasing cumulated slip (from few mm to few meters) and different attitudes (variable resolved stresses) to evaluate i) whether the thermal maturity of organic matter on fault surfaces preserved a trace of frictional heating and ii) to estimate the role of variable mechanical work in their formation.

The microstructures of the MSs and the associated slip zones display a polyphasic deformation history; smeared bitumen along the slip surfaces is spatially associated with (i) discrete ultracataclastic slip zones containing fragments of older bitumen-rich slip zones and calcite-rich vein-precipitated matrix and, (ii) lower strain cataclastic layers with evidence of pressure-solution in the dolostone clasts and viscous shear in the bitumen. Such different deformation styles of bitumen-rich materials might be an evidence of high strain rate coseismic embrittlement and long-term aseismic creep during the seismic cycle.

Micro-Raman analyses on the MSs and their wall rocks have been aimed at quantifying the thermal maturity of the organic matter on slip surfaces that can reveal thermal pulses associated to frictional heating during seismic slip. This multidisciplinary study, though finalized to a deep understanding of their formation mechanism, may lead to recognize microstructural or mineralogical/geochemical features specifically associated to earthquake ruptures in natural faults with a potential impact on seismic hazard studies.

How to cite: Chinello, M., Bersan, E., Fondriest, M., Tesei, T., Corrado, S., and Di Toro, G.: Field, microstructural and phase characterization of mirror-like fault surfaces in bituminous dolostones (central Apennines, Italy), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2415, https://doi.org/10.5194/egusphere-egu22-2415, 2022.

EGU22-2559 | Presentations | TS4.5

Searching for partial ruptures of repeating earthquakes in Parkfield, California 

Alice Turner and Jessica Hawthorne

Repeating earthquakes are thought to represent the repeated rupture of loaded patches surrounded by regions that are slipping aseismically; they provide a natural laboratory to study interactions between seismic and aseismic processes. These events occur less often than one would expect if these earthquakes accommodate all of the long-term slip. Recent crack models using rate-and-state friction (Cattania and Segall, 2019; Chen and Lapusta, 2009 ) suggest a possible explanation: for small events, a larger amount of the slip budget on the patch being taken up by aseismic slip. For larger events where most of the slip budget is seismic, the patch experiences partial ruptures, also leading to the deviation from expected scaling. We aim to test the predictions of this model of repeating ruptures by searching for the proposed partial ruptures. We choose to search using the Northern California earthquakes catalogue, which contains many well-located repeating earthquake sequences. Preliminary results suggest that partial ruptures in the Parkfield region are not common. If preliminary results pass additional tests, it may suggest that partial ruptures do not make up a significant proportion of the slip budget of larger repeating earthquakes in this region. 

How to cite: Turner, A. and Hawthorne, J.: Searching for partial ruptures of repeating earthquakes in Parkfield, California, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2559, https://doi.org/10.5194/egusphere-egu22-2559, 2022.

EGU22-2791 | Presentations | TS4.5

The role of fluids in earthquake cycles: insights from seismo-hydro-mechanical models 

Betti Hegyi, Luca Dal Zilio, Whitney Behr, and Taras Gerya

Understanding the role of fluids in earthquake mechanisms and designing a computational framework which couples solid rock deformation and fluid flow is a major challenge in geosciences. We present results from a newly developed Hydro-Mechanical Earthquake Cycle (H-MEC) numerical code, which can resolve inertia- and fluid-driven seismic events, as well as long-term deformation in and off-fault. The two-dimensional (2-D) code uses a finite difference method with rate dependent strength, while an adaptive time-stepping allows the correct resolution of both long- and short-time scales, ranging from years during slow tectonic loading to milliseconds during the propagation of dynamic ruptures. We investigate the evolution of a simple strike-slip fault with fluid flow in a poro-visco-elasto-plastic compressible media. We analyze which parameters could have a first-order control on the seismic and aseismic slip behavior. In particular, we explore  the effects of fault permeability, shear modulus and the rate-strengthening yield strength. Our results suggest that the mentioned parameters influence the recurrence time of seismic cycles. Furthermore, permeability controls the long-term slip behavior and has a significant impact on the self-pressurization of pore-fluid pressure inside the fault zone, both during earthquake nucleation and propagation. Notably, for a range of different fault permeability a temporal transition from seismic events to aseismic slip can be observed, due to a gradual increase of pore-pressure over multiple earthquake cycles. This new numerical framework can help us better understand earthquake mechanisms and earthquake cycles, the role of fluids along fault-structures, and their effect on long term geodynamic processes. 

How to cite: Hegyi, B., Dal Zilio, L., Behr, W., and Gerya, T.: The role of fluids in earthquake cycles: insights from seismo-hydro-mechanical models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2791, https://doi.org/10.5194/egusphere-egu22-2791, 2022.

EGU22-2795 | Presentations | TS4.5

The role of poroelasticity and dilatancy in governing the transition from aseismic to seismic slip during fluid injection 

Elías Rafn Heimisson, Shengduo Liu, Nadia Lapusta, and John Rudnicki

Most faults at seismogenic depths can be described as fractures or discontinuities in a fluid-saturated porous medium and thus, the theory of poroelasticity offers a practical mechanical description of the natural fault environment. However, poroelasticity is rarely considered in simulations of fault slip. Poroelasticity incorporates the two-way coupling of solid and fluid phases where pore-pressure change,  e.g., due to slip, strains the rock matrix and volumetric strain causes changes in pore pressure. During earthquake nucleation, inelastic dilatancy may also induce pore pressure changes. A complex interplay of pore pressure in the bulk and shear zone emerges when we consider the multiple processes coupled to slip on a fault governed by rate-and-state friction. Here, we present an efficient spectral boundary integral code that allows for 2D quasi-dynamic rate-and-state simulations of slow and fast slip with fully coupled and simultaneous state-dependent dilatancy, fluid injection, and two-way coupled diffusive poroelastic bulk response. The method allows for anisotropic shear-zone permeability, while the bulk is considered to be isotropic and homogenous. We can thus simulate three diffusion time scales at once: along the shear zone, across the shear zone, and due to wavelength-dependent bulk diffusion. We apply the code to understand nucleation and repeated fault ruptures with a realistic pore-pressure injection history from a field experiment. We compare different cases with and without dilatancy, larger or smaller differences in drained and undrained poroelastic properties, and varying bulk diffusivity. By systematically increasing the dilatancy coefficient, we observe a transition from highly unstable seismic slip to a migrating slow slip front to quasi-static slip localized to highly pressurized areas. More surprisingly, we find that differences in drained and undrained poroelastic properties and bulk diffusivity strongly influence fault slip stability. A larger difference between drained and undrained Poisson’s ratio or higher bulk diffusivity results in more stable slip during injection, fewer ruptures, and delayed nucleation. These effects appear to be of comparable importance to dilatancy. We conclude that the poroelastic properties of the bulk, which are typically ignored, play a critical role in the stability and determining if slip is seismic or aseismic.

How to cite: Heimisson, E. R., Liu, S., Lapusta, N., and Rudnicki, J.: The role of poroelasticity and dilatancy in governing the transition from aseismic to seismic slip during fluid injection, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2795, https://doi.org/10.5194/egusphere-egu22-2795, 2022.

Dilatancy associated with fault slip produces a transient pore pressure drop which increases frictional strength. This effect has been argued to be at least partially at the origin of slow slip events in subduction zones. Recent experimental results have demonstrated that dilatancy hardening has the potential to stabilise rupture in rocks, but laboratory results need to be upscaled to account for large scale variations in slip along faults. Here, we analyze the dilatant hardening in a steadily propagating rupture model that includes frictional weakening, slip-dependent fault dilation and fluid flow. A fracture mechanics approach is used to show that dilatancy hardening tends to increase the stress intensity factor required to propagate the rupture tip. With increasing rupture speed, an undrained (strengthened) region develops near the tip and extends beyond the frictionally weakened zone. Away from the undrained region, pore fluid diffusion gradually recharges the fault and strength returns to the drained, weakened value. For sufficiently large rupture dimensions, the dilation-induced strength increase near the tip is equivalent to an increase in toughness that is proportional to the square root of the rupture speed. In general, dilation has the effect of increasing the stress required for rupture growth by decreasing the stress drop along the crack. The competing effect of thermal pressurization has the potential to compensate for the dilatant strengthening effect, at the expense of an increased heating rate, which might lead to premature frictional melting. Using reasonable laboratory-derived parameters, we show that the dilatancy-toughening effect leads to rupture dynamics that is quantitatively consistent with the dynamics of observed slow slip events in subduction zones.

How to cite: Brantut, N.: Dilatancy Toughening of Shear Cracks and Implications for Slow Rupture Propagation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2865, https://doi.org/10.5194/egusphere-egu22-2865, 2022.

EGU22-2996 | Presentations | TS4.5

Forecasting earthquake rupture characteristics with deep learning: a proof of concept using analog laboratory foamquakes 

Giacomo Mastella, Fabio Corbi, Jonathan Bedford, Francesca Funiciello, and Matthias Rosenau

In recent years, machine learning has been used to predict earthquake-like failures in various laboratory experiments. The predictions of these approaches have been framed with both regression and classification. Labquakes prediction in direct shear experiments has been achieved by predicting the time to failure of the sample (regression). Similarly, for laboratory analog subduction models, the time to failure has been successfully predicted. In the classification approach, demonstrated on analog models, a time window of “imminence” is predefined and the model determines if failure occurs within this time window or not. These previous approaches suffer from the problem of thresholding: in time-to-failure regression, there is the need to define a velocity or displacement that signals an event has occurred, in imminence classification the choice is the time window that we consider an event to be imminent. Here we remove this thresholding problem by taking a spatiotemporal regression framing that forecasts future surface velocity fields from past ones. In such a framing, the whole seismic cycle is forecast (i.e., interseismic, coseismic, and postseismic). We test this approach on Foamquake.

Foamquake is a novel 3D elastoplastic seismotectonic analog model mimicking the key features of the subduction megathrust seismic cycle in a scaled manner. Foamquake features a wedge-shaped elastic upper plate made of foam rubber. The analog megathrust includes a velocity weakening, rectangular patch embedded in a velocity neutral matrix. Plate convergence is imposed kinematically with a motor-driven belt (analog of the subducting plate) underthrusting the wedge. Foamquake experiences quasi-periodic cycles of stress accumulation and sudden drops through spontaneous nucleation of frictional instabilities. These labquakes are characterized by coseismic displacement of a few tens of meters when scaled to nature and source parameters (seismic moment-duration and moment-rupture area) scaling as real subduction interplate earthquakes. The 3D nature of Foamquake allows running models with two asperities along strike of the subduction zone divided by a barrier. This configuration generates sequences of full and partial ruptures, superimposed cycles, and nested rupture cascades: complex patterns similar to those inferred at natural megathrusts, representing the perfect testbed for developing new prediction strategies.

In particular, we step toward forecasting seismic cycle full surface velocity fields using deep-learning-based approaches from the Computer Vision field. This framing allows simultaneously to forecast the onset of a labquake and illuminate its space-time evolution at different prediction horizons. A variety of deep-learning algorithms have been tested and compared with Random Forest models (which we consider as a baseline machine learning model). We show that Convolutional Recurrent Neural Networks, with spatiotemporal sequences of surface velocities as input, perform the best in forecasting. Preliminary results suggest that the onset and the spatio-temporal propagation of individual lab-quakes can be predicted with relatively high accuracy at prediction horizons that are in the same order of labquake durations. Surface velocities at further horizons than labquake durations appear unpredictable. This study introduces an innovative framing of the earthquake forecasting problem which can open new perspectives for application to natural observations.

 

How to cite: Mastella, G., Corbi, F., Bedford, J., Funiciello, F., and Rosenau, M.: Forecasting earthquake rupture characteristics with deep learning: a proof of concept using analog laboratory foamquakes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2996, https://doi.org/10.5194/egusphere-egu22-2996, 2022.

EGU22-3189 | Presentations | TS4.5 | Highlight

Seismic and aseismic fault slip during the inter-seismic period: observations from the Marmara region of the North Anatolian Fault 

Patricia Martínez-Garzón, Dirk Becker, Virginie Durand, Grzegorz Kwiatek, Marco Bohnhoff, and Murat Nurlu

During the inter-seismic period, faults accumulate tectonic strain which is then released through slip transients of different duration from seismic to aseismic. Imaging creeping fault patches and constraining their depth extent could allow identifying fault segments with larger strain accumulation. The Marmara segment of the North Anatolian Fault (NAFZ) currently represents a seismic gap with a high probability for an M>7 earthquake in direct proximity to Istanbul. In the eastern Sea of Marmara region of the NAFZ, the GONAF borehole observatory is fully operating since 2015, providing the means to monitor earthquake nucleation and crustal deformation over the entire frequency band. In this study, we investigate the spatio-temporal distribution of seismic and aseismic deformation in the Marmara region and the implications for the nucleation of a large earthquake compiling information derived from extended identification of earthquake repeaters and analysis of continuous strainmeter and geodetic recordings. At the eastern portion of the Marmara segment, a fully locked fault segment was identified from absence of microseismicity and from GPS data (Bohnhoff et al., 2013; Ergintav et al., 2014). Towards the western part, shallow fault creep was reported based on sea-floor geodesy (Yamamoto et al., 2018) and the occurrence of repeating earthquakes (Schmittbuhl et al., 2016; Bohnhoff et al., 2017) in specific areas. We generated a new 15-year homogenous seismicity catalog for the Marmara region (2006-2021) unifying the data from the main Turkish seismic agencies AFAD and KOERI and including the GONAF borehole network. A total of 13.876 events were of sufficient quality to obtain non-linear hypocenter locations. We utilized this catalog to search for earthquake repeaters along the entire Main Marmara fault segment as well as the southern Marmara and Armutlu fault segments. Centering at the Western High segment of the Main Marmara fault, a spatial transition eastward and westward from partially creeping to fully locked is observed based on the amount and magnitude of earthquake repeaters and the estimated creeping rate. No other sequence of repeaters is found in any other part of the Marmara region. Analysis of strainmeter continuous recordings revealed two slow slip events connected with the occurrence of two M4+ earthquakes in the region in 2016 and 2018 and lasting for at least 30 days. Coulomb forward modelling combined with seismicity analysis suggests that the fault source of these slip transients could be the shallower portion of a local normal fault structure in the Armutlu Peninsula favorably oriented with respect to the local stress field orientation. All together, these results suggest that aseismic slip is occurring in some segments and different depth extent within the Marmara section of the NAFZ and that aseismic slip has a role in earthquake triggering and nucleation in the region. Still, further studies combining seismological and geodetic data are needed to determine the exact amount of slip-partitioning, particularly with depth.

How to cite: Martínez-Garzón, P., Becker, D., Durand, V., Kwiatek, G., Bohnhoff, M., and Nurlu, M.: Seismic and aseismic fault slip during the inter-seismic period: observations from the Marmara region of the North Anatolian Fault, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3189, https://doi.org/10.5194/egusphere-egu22-3189, 2022.

EGU22-3209 | Presentations | TS4.5

Linking surface strain signals with frictional heterogeneity of the interface in a laboratory-scale subduction megathrust 

Ehsan Kosari, Matthias Rosenau, Jonathan Bedford, Zhiguo Deng, Sabrina Metzger, Bernd Schurr, and Onno Oncken

Geodetic, seismological, gravimetric, and geomorphic proxies have widely been used to understand the behavior of the shallow portion of subduction megathrusts and answer questions related to seismic asperities: Where are they located, and how large are they? How close are they to failure, and how strong are they coupled? Our current knowledge of the kinematics and dynamics of megathrust earthquakes is limited due to their offshore location, and that our observations only cover a fraction of one megathrust earthquake cycle. 

The frictional-elastoplastic interaction between the interface and its overriding wedge causes variable surface strain signals such that the wedge strain pattern may reveal the mechanical state of the interface. We here contribute to this discussion using observations and interpretations of controlled analog megathrust experiments highlighting the variability of deformation signals in subduction zones. To examine the interaction, we investigate seismotectonic scale models representing a seismically heterogenous interface and capture the model’s surface displacements by employing a “laboratory-geodetic” method with high spatio-temporal resolution. Our experiments generate physically self‐consistent, analog megathrust earthquake ruptures over multiple seismic cycles at laboratory scale to study the interplay between short-term elastic and long-term permanent deformation. 

Our results demonstrate that frictional-elastoplastic interaction partitions the upper plate into a trench-parallel and -perpendicular strain domain, experiencing opposite strain (contraction vs. extension) during the co- and interseismic phase of the seismic cycle. Moreover, the pattern differs in the off- and onshore segments of the upper plate. This implies that the seismic potential of the shallow (offshore) portion of the megathrust may be underrepresented if only onshore observations are included in the estimate. However, our models suggest that, in the case of strong frictional contrast (velocity weakening vs. strengthening) on the interface, the short-term, onshore strain pattern (dominated by elastic deformation) may suffice to map the frictional heterogeneity of the shallow interface along strike. Finally, the frictional heterogeneity of the shallow interface is well reflected by the permanent surface strain observed offshore and partially in the strain observed at the coastal region. The observed along-trench segmentation predicted by our models is reasonably compatible with short-term, elastic geodetic observations and permanent geomorphic features in nature.

How to cite: Kosari, E., Rosenau, M., Bedford, J., Deng, Z., Metzger, S., Schurr, B., and Oncken, O.: Linking surface strain signals with frictional heterogeneity of the interface in a laboratory-scale subduction megathrust, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3209, https://doi.org/10.5194/egusphere-egu22-3209, 2022.

It has often been suggested that the frictional instability on small fault patches can lead to slow but accelerated creep and growth, which may explain the nucleation of earthquake rupture. Because of the small size of the asperity at depth, the nucleation process is difficult to verify by observations and its possible role for earthquake generation is still debated.

While most earthquake nucleation models are of complex geometry and assume that the asperity itself is static while its stress is increasing, we suggest a concept where the cohesion zone of a fault patch grows steadily and develops a self-induced high stress behind the crack tip. We show that a slip-weakening and velocity strengthening constitutive relation can generate the high stress cohesion zone. The aseismic growth of the asperity is accelerated, and the point to nucleate into a catastrophic rupture depends on the ambient stress on the fault and the stress drop in the centre of creeping segment. Interestingly the model predicts that earthquakes on faults with subcritical and small ambient stress will start with more energetic ruptures, as their Griffith energy is larger. This is unexpected and may question the common assumption that largest earthquake are triggered if the fault is critically stressed and the last earthquake occurred a long time before the average recurrence period.

Our fracture mechanical, theoretical asperity model is unconventional and questions established ideas on earthquake generation. We discuss the possible consequences and the postulated, testable predictions of the model to motivate laboratory and field experiments.

How to cite: Dahm, T. and Hainzl, S.: Earthquake nucleation – viewpoint of dynamically growing asperities controlled by the fracture cohesion-zone and frictional shear, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3541, https://doi.org/10.5194/egusphere-egu22-3541, 2022.

EGU22-3617 | Presentations | TS4.5

Evidence of frictional melting observed in the fault rock drill cuttings from Pohang enhanced geothermal system (EGS) site 

Sejin Jung, Ji-Hoon Kang, Youngwoo Kil, and Haemyeong Jung

The 2017 Mw 5.5 Pohang earthquake in South Korea has been reported as one of the largest triggered earthquakes at an enhanced geothermal system (EGS) site. A fault that was ruptured in Pohang was not identified by geological investigations or geophysical surveys before the Mw 5.5 Pohang earthquake. “Mud balls” showing a fault gouge structure were reported in the Pohang EGS site only at the depth range of 3,790 – 3,816 m. In this study, we present new observation on the fault rocks retrieved from the Pohang EGS site as drill cuttings. The drill cuttings from 3,256 – 3,911 m interval contained mud balls similar to those observed at the depth of 3,790 – 3,816 m. Mud balls contained fine grains and showed foliated clay matrix with well-rounded clasts of quartz or feldspar, which are a typical fault gouge structure. In addition, mud balls retrieved from the depth of 3,256 and 3,260 m contained black fragments. SEM and TEM observation revealed that these black fragments consist of glassy matrix with sub-micrometer size clasts. Abundant vesicles were observed inside the black fragments, and some of the black fragments preserved foliation defined by compositional layering. TEM observation confirmed that the glassy matrix in the black fragments is amorphous material with a chemical composition similar to illite-smectite. These observations indicate that black fragments are resulted from the frictional melting during the coseismic slip.

How to cite: Jung, S., Kang, J.-H., Kil, Y., and Jung, H.: Evidence of frictional melting observed in the fault rock drill cuttings from Pohang enhanced geothermal system (EGS) site, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3617, https://doi.org/10.5194/egusphere-egu22-3617, 2022.

EGU22-4107 | Presentations | TS4.5

Characterizing the rupture extent of creep events along the Central San Andreas Fault. 

Daniel Gittins and Jessica Hawthorne

The San Andreas Fault has been observed to creep at the surface along the creeping section between San Juan Bautista and Cholame. Slip along this creeping section accumulates at a slow background rate that is punctuated by creep events: few-mm bursts of slip that occur every few weeks to months. Despite observations of these events dating back to the 1960s, we still do not know the rupture extent of these events or the forces that drive them, as previous estimations are confined to short observation periods or one location. So in this study, we systematically characterize creep events in terms of their along-strike rupture extent and determine the depth at which these events occur.

We detect and analyze creep event rupture extent using 18 USGS creepmeters and PBO strainmeters along the San Andreas fault. Using a cross-correlation approach, we systematically detect 2120 creep events in the creepmeter record spanning 1985 - 2020. Comparing the start times of these events, we identify 306 potential multi-creepmeter events and determine their potential along-strike rupture extent. Through both visual inspection and statistical analysis, we identify five creep event types, including single-creepmeter events, small (<2 km) events, medium-sized (3-6 km) events, large (>10 km) events and events that rupture multiple fault strands. We also repeated this analysis after removing events that may be driven by rainfall, and we find that only the correlation of the very largest creep events diminishes. This suggests that these kilometer-long events are not small rainfall-associated perturbations; they are likely to be driven by complex or heterogeneous frictional weakening at depth.

We are exploring more of the properties of creep events to understand better the driving physics, primarily depth, duration, slip and slip evolution. By determining these properties, we may be able to better discriminate between the driving models of creep events and provide a window into the dynamics of larger-scale slip on the San Andreas Fault.

How to cite: Gittins, D. and Hawthorne, J.: Characterizing the rupture extent of creep events along the Central San Andreas Fault., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4107, https://doi.org/10.5194/egusphere-egu22-4107, 2022.

EGU22-4533 | Presentations | TS4.5

Creep on seismogenic faults: Insights from analogue earthquake experiments 

Matthias Rosenau, Fabio Corbi, Nadaya Cubas, Francesca Funiciello, Ehsan Kosari, Bertrand Maillot, Giacomo Mastella, Onno Oncken, Michael Rudolf, Pauline Souloumiac, and Sarah Visage

Tectonic faults display a range of slip behaviours including continuous and episodic slip covering rates of more than 10 orders of magnitude. To gain insight into the slip behaviour of brittle faults, we performed laboratory stick-slip experiments at low pressure using dry “sticky” rice as rock analogue material. Rice has been shown to be a valuable material obeying the rate and state friction laws qualitatively and quantitatively and mimicking the full spectrum of seismogenic fault behaviour (“ricemic cycles”) depending on boundary conditions. The deformation mechanism is granular flow and as such transient hardening and weakening phenomena such as strain localization or stick-slip are accompanied by dilation and compaction, respectively. Such a rheology might be similar in rocks at various scales (grain scale to regional tectonic scale).

We here report on ring shear test experiments on a range of rice varieties, including full-grain and crushed sorts. We imposed boundary conditions (i.e., normal load, shear velocity) scaled down from nature under which our fault analogue shows a variety of slip behaviours ranging from slow and quasi-continuous creep to episodic slow slip to dynamic rupture. The experiments demonstrate that significant interseismic creep (up to far-field loading rate) and earthquakes may not be mutually exclusive phenomena for a given location along a fault. Moreover, creep signals vary systematically with the fault’s seismic potential. Accordingly, the transience of interseismic creep scales with fault strength and seismic coupling as well as with the maturity of the seismic cycle. Loading rate independence of creep signals suggests that the long-term stationary mechanical properties of faults (e.g. seismic coupling) can be inferred from short-term observations (e.g. aftershock sequences). Moreover, we observe the number and size of small episodic slip events to systematically increase towards the end of the seismic cycle providing an observable proxy of the relative shear stress state on seismogenic faults. 

Importantly, very weak faults (with low effective normal loads) in a late stage of their seismic cycle might creep at rates very close to far-field loading for extended periods of the interseismic stage (~decades before failure). Given that we typically observe only a fraction of seismic cycles with high resolution (with geodetic methods) in nature, this might lead to the false belief of the fault being aseismic and not hosting large earthquakes. We thus demonstrate that seismic and aseismic behaviour might not necessarily be mutually exclusive.

How to cite: Rosenau, M., Corbi, F., Cubas, N., Funiciello, F., Kosari, E., Maillot, B., Mastella, G., Oncken, O., Rudolf, M., Souloumiac, P., and Visage, S.: Creep on seismogenic faults: Insights from analogue earthquake experiments, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4533, https://doi.org/10.5194/egusphere-egu22-4533, 2022.

EGU22-5062 | Presentations | TS4.5

Frictional melting during seismic rupture? A new Raman Spectroscopy approach to detect short-lived heat pulses 

Benjamin Moris-Muttoni, Hugues Raimbourg, Romain Augier, Aurélien Canizarès, Patrick Simon, and Yan Chen

Whether seismic rupture propagates over large distances to generate earthquakes or on the contrary slows down quickly, is heavily dependent on the slip processes operating within the fault core. One possible scenario is that during seismic slip, the frictional work induces a local and transient release of heat up to reach the melting of the rock. This melt-lubrication of the fault plane results in resistance drop and promotes further propagation of the fault. Nonetheless, assessing the occurrence of flash melting has turned problematic, especially in the metasediments that constitute a large fraction of seismically active collision or subduction zones.

In this work, we explore the effects of short-lived intense heating on the crystallinity of the carbonaceous particles present in the fault core. For this purpose, we carried out flash-heating experiments on pellets of natural sediments. Using a pair of lasers, the sample temperature was raised to 1400°C for durations ranging from 0.5 to 60 seconds, resulting in partial to total melting. The carbonaceous particles were then analyzed by Raman Spectroscopy. The spectroscopic signal of particles intensely heated for a short period of time present an atypical shape, with a large D3 band centered around 1500cm-1. The D3/Gsl. ratio in Flash-heating experiments show an evolution from 0.2 for the starting material up to 0.7 after a couple of seconds of Flash-heating. Following this experimental work, we analyzed with Raman spectroscopy several independent examples of short-lived intense heating of carbon-bearing rocks: static heating, stick-slip, high-velocity-friction experiments, In all these cases, we observed the presence of a prominent D3 band and a D3/Gsl. ratio larger than reference material. Based on these observations, we established a new parameter, the D3/Gsl. ratio, as sensitive to short-lived intense heating.

Finally, we applied this new Raman parameter in association with micro-structural observations to discriminate the formation process of five Black Fault Rocks (BFR) from the Shimanto and the Kodiak Accretionary Complex. Microstructures are in several cases ambiguous as to the occurrence of melting in the BFR. However, the D3/Gsl. ratio shows a large increase in the Kure and the Mugi BFR while the values are close to 0.2 in the host-rock. In contrast, Nobeoka, Okitsu and Kodiak BFR show similar values in comparing the BFR veins and the host-rocks. Accordingly, the Mugi and Kure BFR are associated with a molten origin when the three others BFR are the result of mechanical wear solely, without evidence for large temperature increase.

In summary, the D3/Gsl. ratio is a parameter that can be easily retrieved in most fault rocks cutting across sediments and that efficiently tracks the occurrence of short-lived intense heating. The use of this parameter appears as a promising approach to decipher the dynamics of faulting and to discriminate faults with intense frictional work from faults where temperature increase was much more limited, either because of slow creep or inhibiting processes (e.g. fluid vaporization during slip).

How to cite: Moris-Muttoni, B., Raimbourg, H., Augier, R., Canizarès, A., Simon, P., and Chen, Y.: Frictional melting during seismic rupture? A new Raman Spectroscopy approach to detect short-lived heat pulses, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5062, https://doi.org/10.5194/egusphere-egu22-5062, 2022.

EGU22-5254 | Presentations | TS4.5

Interactions of asperities controlling on fault stability: An experimental approach 

Weiwei Shu, Olivier Lengliné, and Jean Schmittbuhl

The transition between seismic slip and aseismic creep of faults in the Earth crust suggests a strong time-dependent mechanism for the underlying physics and corresponding mechanical response of fault slip. Asperities establish the real contact on the slipping interface of a fault and serve as stress concentrators that control the initiation of earthquakes. Investigating the interactions between individual asperities and how the global stability of a fault is controlled by the collective effects of their local behaviors are essential for understanding the intrinsic relationships between earthquake swarms and faulting. Here we design a novel direct-shear experimental setup, which allows a thick PMMA (poly-methyl-methacrylate) plate to slide slowly on a customized surface, on which asperities are modeled by spherical PMMA beads and embedded in a softer polymer base, for analogizing tectonic faults. We perform various experiments by applying multiple normal loads and loading rates, with a high-resolution camera employed to capture the detailed activities of asperities. We demonstrate the global stability of a fault could be described by the synthesized behaviors of local asperities. We also prove, for the same asperity, it can experience different slip modes at different time periods. We generate a catalog of fault slip events defined by the slipping velocity of each asperity derived from the image correlation technology, and then we determine slip episodes based on time and space successively. Furthermore, we investigate the distributions of various parameters of the determined slip episodes, including the number of slipping asperities, as well as the duration, mean slip displacement, and moment of slip episodes. We explore the spatiotemporal variations of b-value within one analog seismic cycle and under different normal loads and loading rates. We link the findings at local scales with the bulk mechanical response of the whole fault. Our results bring new insights into the physics and mechanics of seismic and aseismic faulting.

How to cite: Shu, W., Lengliné, O., and Schmittbuhl, J.: Interactions of asperities controlling on fault stability: An experimental approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5254, https://doi.org/10.5194/egusphere-egu22-5254, 2022.

EGU22-6478 | Presentations | TS4.5

Critical roughness controls sliding instability of laboratory earthquakes 

Doron Morad, Amir Sagy, Yuval Tal, and Yossef H. Hatzor

The frictional strength of discontinuities in the upper earth crust controls the stability and dynamics of slip in diverse catastrophic phenomena such as earthquakes and landslides. Natural rock surfaces are rough at various scales with significant variability that affects their frictional behavior. Seismological and geophysical observations of large thrust faults suggest that fault geometry affects earthquake characteristics, yet the exact effects are currently being debated. In this study we show, using laboratory direct shear experiments, that a specific surface geometry enhances sliding instability and that the transition from stable to unstable sliding is non-linearly controlled by the magnitude of the initial roughness. In order to isolate the effect of roughness, we generate six levels of surface roughness in split prisms of Diabase rocks, with four orders of RMS magnitude difference between the smoothest and the roughest samples. The experiments are performed under an imposed constant normal stress of 5 MPa and load point (shear piston) velocity of 0.01 mm/s. The sliding target is typically set to 10 - 13 mm as monitored from two horizontal LVDT’s that are attached to the shear box very close to the tested interface. We show that the amplitude of the stick-slip events diminishes towards the two roughness extremes. The roughest sample (RMS = 1300 µm) exhibits a gradual increase of shear stress to a peak value of ~13 MPa, followed by brittle fracture expressed by a large stress drop of 3 MPa and then by transition to a relatively stable sliding. For the midrange roughness (RMS = 7 µm), stick-slip oscillations are obtained with different levels of stress drops and sliding dynamics characteristics. The smooth sample (RMS = 0.85 µm) slide in a relatively stable manner while the smoothest surface (RMS = 0.7) exhibits local peak friction of 0.18, followed by stable sliding with moderate slip hardening. We further demonstrate, both experimentally and numerically, that stick-slip oscillations commonly referred to as laboratory earthquakes, are constrained to a very limited range of surfaces roughness within which a specific level, defined here as the critical roughness, triggers the highest amplitude of oscillations. We therefore suggest that the roughness amplitude strongly affects the frictional stability and slip dynamics of natural faults.

How to cite: Morad, D., Sagy, A., Tal, Y., and H. Hatzor, Y.: Critical roughness controls sliding instability of laboratory earthquakes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6478, https://doi.org/10.5194/egusphere-egu22-6478, 2022.

EGU22-6560 | Presentations | TS4.5

Seismic potential of the Anninghe Fault zone, southeastern Tibetan Plateau: Constrains from friction experiments on natural granite gouge 

Huiru Lei, André R. Niemeijer, Yongsheng Zhou, and Christopher J. Spiers

The eastern boundary of the Sichuan-Yunnan tectonic block and Tibetan Plateau is marked by a highly active fault zone featuring four left-lateral strike-slip faults, the Xianshuihe, Anninghe, Zemuhe, and Xiaojiang faults. These collectively show the highest seismicity in southwestern China. Since 1977, a portion of the Anninghe faults (AHF) has experienced seismic quiescence for ML≥4.0 earthquakes. The spatial extent of this quiescent portion has gradually dwindled with time resulting in the formation of the current 130-km-long “Anninghe seismic gap”. To evaluate the seismic potential and model seismogenesis on this part of the AHF, data are needed on the frictional properties of relevant fault zone materials under mid-crustal hydrothermal conditions.

In this study, we report both saw-cut and rotary shear friction experiments performed on sieved granite gouge collected from the AHF and believed to represent the fault rock composition at seismogenic depth. Experiments were conducted on 1 mm thick gouge layers at 100-600℃, effective normal stress of 100-200MPa, pore water pressures of 30MPa and 100 MPa, and sliding velocities of 0.01-100μm/s . The saw-cut tests reached shear displacements up to 4 mm versus 30 mm in the ring shear experiments. Friction coefficient lays in the range 0.6-0.8 in most samples, except that it drops to 0.4 at higher temperatures and low velocity. In the saw-cut experiments performed at 30MPa pore water pressure, velocity-strengthening behaviour occurred below 200℃ (Regime 1), whereas velocity-weakening occurred at 200-600℃ (Regime 2). By contrast, dry saw-cut experiments showed velocity-strengthening at all temperatures investigated (25-600℃). In the rotary shear experiments performed at 100MPa pore water pressure, three temperature-dependent regimes of behaviour were identified, showing potentially unstable, velocity-weakening behaviour at 100-400℃ (Regime 2) and velocity-strengthening at lower and higher temperatures (Regimes 1 and 3). These regimes moved towards higher temperatures with an increase in sliding velocity. Combining all the data, the importance of Regime 2, i.e. the temperature range characterized by velocity-weakening, potentially seismogenic behaviour, decreased with increasing pore water pressure, shear displacement and effective normal stress. Combined with our microstructural observation and previous studies, we explain our results qualitatively in terms of a microphysical model in which changes in friction coefficient and (a-b) are caused by competition between dilatant granular flow and grain-scale creep processes.

Since the geothermal gradient around AHF is approximately 30 ℃/km, direct application of our results suggests velocity-weakening (Regime 2) on the AHF at depths of 2.5-12.5 km, and velocity-strengthening at shallower and deeper levels. By comparison, the depth range of the AHF seismic gap (locking region) is 0 to 15 km, additionally, the relocated small earthquake distribution in southwestern China shows that the depth of hypocenters are mostly less than 15km, which is consistent with our experimental results. However, our experiments show that the velocity-weakening regime for AHF gouge is controlled by many factors besides temperature, such as effective normal stress, pore fluid pressure, shear displacement and velocity. Further progress towards understanding the seismic gap, and allowing rupture nucleation modelling, for example, therefore requires a more quantitative microphysical modelling approach in future.

How to cite: Lei, H., Niemeijer, A. R., Zhou, Y., and Spiers, C. J.: Seismic potential of the Anninghe Fault zone, southeastern Tibetan Plateau: Constrains from friction experiments on natural granite gouge, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6560, https://doi.org/10.5194/egusphere-egu22-6560, 2022.

EGU22-6776 | Presentations | TS4.5

Changes in AE similarity track fault kinematics during laboratory earthquakes 

Samson Marty, Raphael A. Affinito, Clay Wood, Chris Marone, Parisa Shokouhi, and Jacques Rivière

It is now recognized that acoustic emissions (AEs) generated during stick-slip frictional sliding (i.e., lab earthquakes) can be considered as microearthquakes. Over the past decades, many laboratory AE studies have addressed issues related to the physics of earthquakes such as fault nucleation and growth in brittle rocks, frequency magnitude statistics of earthquakes, laboratory earthquake precursors and, more recently, laboratory earthquake prediction based on machine learning techniques. Here, we conduct double direct shear experiments on samples of Westerly granite under applied normal loads of 5-15 MPa and with shearing rates of 1-100 μm/s. We use template matching and other cross correlation techniques to study the evolution of AE similarity during the laboratory seismic cycle. The aim of this study is to connect changes in AE similarity to fault stress-loading and kinematics. AE similarity is derived from the correlation matrices of AE catalogs and is found to vary primarily with fault slip velocity. AE similarity is, on average, constant at slow speed (fault slip velocity <= 10 mm/s) and drops as fault slip velocity increases. Our observations show that AE similarity follows a power law of fault slip velocity. Based on previous experimental and theoretical works, we suggest that AE similarity reflects the evolution of fault contact area. One interpretation of our results is that a simple metric such as AE similarity carries relevant information about fault kinematics and fault structural properties that may be used for forecasting and prediction of failure.

How to cite: Marty, S., A. Affinito, R., Wood, C., Marone, C., Shokouhi, P., and Rivière, J.: Changes in AE similarity track fault kinematics during laboratory earthquakes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6776, https://doi.org/10.5194/egusphere-egu22-6776, 2022.

EGU22-8011 | Presentations | TS4.5

Temperature affects the frictional stability of experimental clay-bearing fault gouges 

Isabel Ashman and Daniel Faulkner

Field observations have shown that mature fault zones are rich in clay minerals (e.g. MTL in Japan, Punchbowl Fault in USA, and Alpine Fault Zone in New Zealand). Most mature fault zones are also seismogenic, which is at odds with the velocity strengthening behaviour observed for clay-bearing material in rock deformation experiments. The measurements of rate and state friction in clay-bearing material show that most clay-bearing material would favour aseismic creep when the experiments are conducted at room temperature. To address this disparity between experimental and field observations, a set of controlled friction experiments were devised to investigate the effect of varying temperature conditions on the frictional properties of clay-bearing fault gouges.
The velocity-step friction experiments were conducted in a triaxial deformation apparatus at an effective normal stress of 90MPa and ambient temperatures that increased from room temperature (23°C) to 180°C in increments of 40°C. In order to measure the rate and state frictional properties of the fault gouges, the imposed slip velocity was stepped between 0.3-3 μm/s. The simulated quartz-clay fault gouges had controlled clay (kaolinite) contents in increments of 25wt% from 0-100wt%. Preliminary results show that by increasing the ambient temperature during fault slip, the rate and state friction parameter [a–b] consistently decreases significantly in clay-bearing fault gouges, often from a velocity strengthening [a–b] value to a weakening [a–b] value. This is consistent with the previous, limited studies of clay-bearing material at elevated temperatures. In the clay-poor gouges, the velocity weakening [a–b] parameter is accompanied by dynamic stick-slip behaviour, whereas in clay-rich gouges the velocity weakening [a–b] parameter shows initially unstable slip that is dampened and arrests to aseismic slip. The elevated temperatures in fault zones at depths up to ~6km, as investigated in this study, can therefore lead to unstable fault slip in clay-rich material that is velocity strengthening at room temperature. It is proposed that elevated temperatures are an important component of seismogenic slip occurring in clay-rich material, as is observed in natural faults.

How to cite: Ashman, I. and Faulkner, D.: Temperature affects the frictional stability of experimental clay-bearing fault gouges, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8011, https://doi.org/10.5194/egusphere-egu22-8011, 2022.

EGU22-8340 | Presentations | TS4.5

Fault friction during simulated seismic slip pulses 

Christopher Harbord, Nicolas Brantut, Elena Spagnuolo, and Giulio Di Toro

Theoretical studies predict that during earthquake rupture faults slide at non-constant slip velocity, however it is not clear which source time functions are compatible with the high velocity rheology of earthquake faults. Here we present results from high velocity friction experiments with non-constant velocity history, employing a well-known seismic source solution compatible with earthquake source kinematics. The evolution of friction in experiments shows a strong dependence on the applied slip history, and parameters relevant to the energetics of faulting scale with the impulsiveness of the applied slip function. When comparing constitutive models of strength against our experimental results we demonstrate that the evolution of fault strength is directly controlled by the temperature evolution on and off the fault. Flash heating predicts weakening behaviour at short timescales, but at larger timescales strength is better predicted by a viscous creep rheology. We use a steady-state slip pulse to test the compatibility of our strength measurements at imposed slip rate history with the stress predicted from elastodynamic equilibrium. Whilst some compatibility is observed, the strength evolution indicates that slip acceleration and deceleration might be more rapid than that imposed in our experiments. 

How to cite: Harbord, C., Brantut, N., Spagnuolo, E., and Di Toro, G.: Fault friction during simulated seismic slip pulses, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8340, https://doi.org/10.5194/egusphere-egu22-8340, 2022.

EGU22-9868 | Presentations | TS4.5

Experimental strike-slip earthquakes (“ricequakes”) 

Sarah Visage, Pauline Souloumiac, Bertrand Maillot, Nadaya Cubas, and Yann Klinger

During large strike-slip earthquakes, the surface displacement can be measured from correlation of satellite images acquired before and after the event. These measurements allow quantifying the total surface displacement and knowing how it distributes between on and off-fault deformation, which is important for seismic hazard assessment. These measurements are highly variable, partly due to the sparsity of natural examples. This research focuses on analogue modelling to study parameters affecting the surface displacement in a controlled environment. However, current analogue models do not address the issue of surface deformation associated with strike-slip earthquakes. Instead, models using granular materials, such as sand or clay, rather focus on the surface deformation associated with continuous deformation without earthquakes, while models using rigid materials, such as foam or gelatin, focus on the localization and frequency of seismic events without looking at surface deformation.

To analyze the long-term deformation of seismogenic strike-slip faults from analogue experiments, we used a box composed of two juxtaposed PVC plates simulating a vertical and linear basement fault. A strike-slip fault emerges from this discontinuity. The box is filled with rice and rubber pellets in order to produce both aseismic displacements and earthquakes along the evolving strike-slip fault. Dry rice is a stick-slip granular material already used in subduction experiments. We used a twice broken rice with peak, dynamic, and reactivation friction values of respectively 0.78, 0.67 and 0.68 at a constant shear velocity. Those values decrease when the shear velocity is increased (the parameter “a-b” = -0.012 in the rate friction law of the rice). Since rice is too rigid to produce a measurable elastic strain release, we added a basal layer of fine rubber pellets between the basal PVC plates and the rice layer in order to store elastic strain. Applying a constant displacement velocity and taking photos every 25 micrometers of displacement, we follow the surface displacements through image correlation.

We observe that the average displacement along a profile parallel to the fault (taken at a distance of the basal fault corresponding to half the rice layer thickness) only matches the applied displacement when averaged over the whole experiments. Indeed, during most of the experiment, the observed incremental displacement is lower than the applied one, but from time to time it catches up during discreet events that produce large displacements of up to four times the applied incremental displacement. We interpret these events as seismic events. Hence, the evolution of cumulative displacement with time exhibits some phases of creep, more or less at the same rate as the input rate, during the inter-seismic period, and phases of sudden displacements corresponding to sudden release of elastic strain, i.e., earthquakes. However, we never observe a complete blocking phase (sticking phase). These first results show that it is possible to build an experimental strike-slip fault system in a granular medium with a low normal stress, i.e. a free surface, that produces extended periods of partial stress loading during creep phases, alternating with period of sudden stress release during displacement phases. 

How to cite: Visage, S., Souloumiac, P., Maillot, B., Cubas, N., and Klinger, Y.: Experimental strike-slip earthquakes (“ricequakes”), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9868, https://doi.org/10.5194/egusphere-egu22-9868, 2022.

EGU22-9997 | Presentations | TS4.5

Effects of asperities and roughness on frictional slip of laboratory faults 

simon Guerin-Marthe, Georg Dresen, Gzegorz Kwiatek, Lei Wang, Audrey Bonnelye, and Patricia Martinez-Garzon

Natural faults are heterogeneous features, with complex geometries and material properties. Understanding how the geometrical complexities of a fault affects the dynamics and preparatory phase of earthquakes is of crucial importance for seismic hazard assessment. In laboratory samples, frictional sliding along prefabricated faults may produce so called stick-slips comparable to dynamic ruptures observed during earthquakes. While the effect of roughness has been shown to influence significantly the frictional behavior of laboratory faults, there are only a few studies investigating more complex types of fault heterogeneities. In this study, we conduct friction experiments on granite with inclined sawcut faults, under a constant confining pressure of 35MPa. Samples are loaded using an axial displacement rate of 0.5 µm/s.  At  similar boundary conditions we compare the slip behavior of (1) a smooth fault, (2) a smooth fault with a single asperity, a 7 mm diameter vertical pin traversing the contact interface, and (3) a rough fault prepared by sandblasting the surface with silicon carbide. A key result of this study is that slip behavior depends on fault roughness and is influenced in a non-trivial way by asperities. The smooth fault displays unstable stick-slip as opposed to the rough fault showing predominantly creep. The smooth fault with the pin exhibits a slip behavior in-between, with very regular stress oscillations that seem to be attenuated by the presence of the pin (asperity). Only after failure of the pin, we observe the stress drop during instabilities to increase regularly with cumulative slip. We also show that in the case of a fault with a single asperity, the slip velocity is less than an order of magnitude lower compared to a similar smooth fault without this asperity.

How to cite: Guerin-Marthe, S., Dresen, G., Kwiatek, G., Wang, L., Bonnelye, A., and Martinez-Garzon, P.: Effects of asperities and roughness on frictional slip of laboratory faults, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9997, https://doi.org/10.5194/egusphere-egu22-9997, 2022.

EGU22-10438 | Presentations | TS4.5 | Highlight

Preseismic slip and foreshocks on rough faults embedded in a damage zone 

Camilla Cattania and Paul Segall

Faults exhibit geometrical heterogeneity at all scales, which induces spatial variations in normal stress and hence strength. Additionally, fault zones comprise multiple fractures which can host seismicity and further modify the stress state on the mainshock fault. Here we study how geometrical complexity affects the precursory phase of large earthquakes. We model seismic cycles on fractal faults with uniform velocity-weakening rate-state friction, loaded by a uniform far-field stressing rate. We also include the effect of surrounding damage, represented by a collection of smaller faults with a power-law decay of density with distance from the main fault.
We find that heterogeneity in normal stress σ induced by roughness controls slip behavior: regions with low σ begin to slip aseismically early in the cycle, loading high σ regions (asperities) which eventually fail seismically generating foreshocks. The precursory phase is characterized by a positive feedback between aseismic slip and foreshocks, with stress changes from each process accelerating the other. In simulations including subparallel secondary faults in the damage zone, this process does not take place on the main fault but instead on smaller, off-fault structures. In both cases, mainshocks nucleate on strong asperities at the edge of the preslip area, which is significantly larger and spatially distinct from mainshock nucleation. These features are consistent with a number of observations at different scales, including laboratory experiments, sub-glacial slip events, and foreshock sequences of megathrust earthquakes.

How to cite: Cattania, C. and Segall, P.: Preseismic slip and foreshocks on rough faults embedded in a damage zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10438, https://doi.org/10.5194/egusphere-egu22-10438, 2022.

EGU22-10536 | Presentations | TS4.5

Nucleation and arrest of aseismic fault slip, during and after fluid pressurization 

Antoine Jacquey and Robert Viesca

Fluid pressurization of preexisting faults due to subsurface energy and storage applications can lead to the onset of aseismic slip and microseismicity, and possibly to major induced seismic events.

Fluid injection decreases the fault shear strength and slip occurs when the in situ shear stress on the fault exceeds its shear strength. The nature of slip (aseismic or seismic) depends on the rate at which it occurs and thus on the stability of the deformation. Understanding the mechanics controlling the onset and arrest of aseismic slip and the transition to seismic slip is therefore key to design mitigation strategies for the safe utilization of the subsurface.

In this contribution, we investigate using theoretical and numerical techniques how aseismic slip on a fault plane nucleates, evolves and stops in response to fluid pressurization and its relaxation. We analyze the impacts of the stress regime and the duration of the pressurization event on the aseismic slip propagation and the time to arrest of fault slip after stopping injection. We demonstrate conditions under which there is spatio-temporal self-similarity of (i) aseismic slip profiles during pressurization and (ii) aseismic slip rate profiles after pressurization. We show that post-injection progression and arrest of slip are proportional to the duration of injection. The results presented here provide insights into the mechanics controlling the arrest of aseismic slip after fluid pressurization as a first milestone towards induced seismicity mitigation strategies.

How to cite: Jacquey, A. and Viesca, R.: Nucleation and arrest of aseismic fault slip, during and after fluid pressurization, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10536, https://doi.org/10.5194/egusphere-egu22-10536, 2022.

EGU22-10746 | Presentations | TS4.5

The Effect of Undrained Fluid Boundary Conditions on Fault Stability 

Raphael Affinito, Clay Wood, Samson Marty, and Chris Marone

Pore fluids are ubiquitous throughout the lithosphere and are a major part of the stress distribution along faults. Elevated pore fluid pressure reduces the effective normal stress, allowing slip and potentially changing the mode of faulting.  Mature brittle faults are characterized by deca- to hecto-meter damage zones composed of gouge and complex shear localization fabrics that can host zones of low, anisotropic permeability. Such zones can include undrained pore fluid conditions that may result in a spectrum of slip behaviors including slow slip events. Despite the obvious importance of pore fluids for fault mechanics, their role in dictating fault stability is poorly constrained. Early results for rate-strengthening accretionary wedge materials suggest pore fluid has a stabilizing effect, as the friction parameter (a - b) increases in response to increased pore fluid pressure (Pf ). Here, we describe early stages of a laboratory investigation of the role of fluid pressure on friction rate and memory effects. We present experimental results from rate-weakening synthetic gouge samples at a range of pore fluid pressure conditions. Experiments use a servo-controlled biaxial load frame enclosing a pressure vessel to apply a true triaxial stress-state with pore fluid pressures. Samples are assembled in a double-direct shear configuration with two uniform 3-millimeter-thick gouge layers. Sample forcing blocks include shear wave piezoelectric transducers for ultrasonic monitoring of shear wave amplitude and velocity. We conducted stable sliding experiments at both drained and undrained conditions to explore role of pore fluids on the RSF parameters. Undrained stick-slip experiments were also done at a range of pore fluid pressures to investigate the role of fluid pressure on the nature of fault slip. We explore differences between the drained and undrained conditions with particular attention on changes from rate-weakening to rate-strengthing friction behavior due to localized overpressure. Additionally, we evaluate interplay between the modes of fault slip, due to poroelastic processes which will result in changes in the transmitted shear wave amplitude and velocity. In subduction environments pore fluid pressure can approach lithostatic pressures leading to localized overpressure. Therefore, it is important to understand the contributions of fluids and effective stress state on frictional stability and the mode of fault slip, whether it be aseismic creep, slow slip, or earthquake rupture.

How to cite: Affinito, R., Wood, C., Marty, S., and Marone, C.: The Effect of Undrained Fluid Boundary Conditions on Fault Stability, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10746, https://doi.org/10.5194/egusphere-egu22-10746, 2022.

EGU22-12893 | Presentations | TS4.5

To what extent do slip rates contribute to the seismic activity of faults? 

Nasrin Tavakolizadeh, Hamzeh Mohammadigheymasi, Luís Matias, Graça Silveira, Rui Fernandes, and Nima Dolatabadi

Crustal deformation comprises a combination of seismic energy release occurring by earthquakes and aseismic unloading through creeping or frictional sliding. Efficient segregation of the seismic component attributed to faults is critical in evaluating Seismic Activity Rate (SAR) or Magnitude Frequency Distribution (MFD) of earthquakes in fault-based hazard assessment. The MFDs are routinely calculated by utilizing fault geometry and slip rate, evaluated from geodetic (or geological) data. The slip rates as an integrated representation of elastic and anelastic loadings overestimate the MFDs since earthquakes release only the elastic strain. To work around this problem, the seismic/geodetic moment-rate ratio defined as Seismic Coupling Coefficient (SCC) is incorporated in this study to account for the seismic portion of the total moment rate to calculate MFDs. The parameter has been studied for different tectonic regions worldwide, including the USA, Canada, Iran, Greece, and Italy. We modify the Moment Budget (MB) algorithm introduced by Pace et al. (2016) to weight the total moment rate corresponding to the maximum magnitude (Mmax) generated by the modeled faults by incorporating the SCC. An updated mean recurrence time (Tmean) for the Mmax and its corresponding uncertainty is computed when SCC is incorporated in the calculation. Then, the seismic moment, the SCC weighted Tmean, and its uncertainty are utilized to compute MFDs by balancing the modeled seismic moment rates (by Doubly Truncated Gutenberg-Richter (DTGR) or Characteristic Gaussian (CHG)) and the SCC weighted moment rates. This process is implemented by the Activity Rates (AR) tool of FiSH codes. Fault data of 89 fault segments in Zagros, Iran, are introduced into the algorithm to compute the SCC incorporated MFDs. The acquired fault-based hazard maps are in harmony with the history of seismicity and tectonics of the region, while the total moment rates exaggerate the calculated hazard. Future work involves implementing the processing algorithm on hazard assessment in the Gulf of Guinea. This research contributes to the FCT-funded SHAZAM (Ref. PTDC/CTA-GEO/31475/2017), IDL (Ref. FCT/UIDB/50019/2020), and SIGHT (Ref. PTDC/CTA-GEF/30264/2017) projects. It also uses computational resources provided by C4G (Collaboratory for Geosciences) (Ref. PINFRA/22151/2016).

How to cite: Tavakolizadeh, N., Mohammadigheymasi, H., Matias, L., Silveira, G., Fernandes, R., and Dolatabadi, N.: To what extent do slip rates contribute to the seismic activity of faults?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12893, https://doi.org/10.5194/egusphere-egu22-12893, 2022.

EGU22-13189 | Presentations | TS4.5

Are initial phases of seismic swarms driven by a cascade of events or precursory slow slip? 

Yu Jiang and Pablo González

Resolving fine temporal stressing rate changes can provide crucial information on the driving mechanisms leading to observed seismicity rate change and surface deformation signals and favours the distinguish of various earthquake nucleation hypotheses, e.g., the preslip model and the cascade model. The initial phase of seismic swarms might be an interesting candidate, because (1) the long-duration seismicity during seismic swarms provide us with better chances to reveal any stress change evolution, and (2) significant seismic slip is expected to occur caused by the most energetic event, which could bias our analysis of slow slip existence, while the initial phase contains much less seismic slip.

In this research, we revisit the 2011 Hawthorne seismic swarm (Nevada, USA) with well-recorded seismicity and abundant geodetic data, and test whether the derived observables can distinguish between two distinct slip nucleation hypotheses (cascade and preslip models). Firstly, to support the cascade model, we calculate the Coulomb stress change from the geodetic-estimated fault slip models, which allows us to analyse the spatio-temporal distribution of seismicity. Secondly, to test the preslip model, a modified rate-and-state model is proposed to connect the seismicity rate to the shear stressing rate, which is derived from a new slip history function - a logistic function. We apply this new method to the 2011 Hawthorne seismic swarm, and estimate the shear stressing rate history. The results show that: (1) A slow slip event is required to explain the observed deformation and seismicity in the initial phase of the swarm. Although the seismicity can be triggered by preceding nearby earthquakes, the cascade model alone cannot explain the observed surface deformation signals. (2) Slow slip is accelerating during the initial phase, and this pattern is consistent with the acceleration of slip during the nucleation of ruptures observed in laboratory experiments and numerical simulations. (3) The most energetic event (M4.6) could have been triggered by a slow slip event, nearby preceding seismicity, or both of them. 

The study of the initial phase during the 2011 Hawthorne seismic swarm allows us to explore the driving mechanism leading to the spatio-temporal evolution of seismicity. We conclude that the slow slip is required to interpret the surface deformation and recorded seismicity, and the triggering of the observed earthquakes in a cascade model cannot be ruled out. This study contributes to providing a new method to model the shear stressing history, which helps to illuminate the physics of the nucleation of earthquakes and the role of slow fault slip in the future.

How to cite: Jiang, Y. and González, P.: Are initial phases of seismic swarms driven by a cascade of events or precursory slow slip?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13189, https://doi.org/10.5194/egusphere-egu22-13189, 2022.

EGU22-2188 | Presentations | SM2.1

Locating Nearby Explosions in Fürstenfeldbruck, Germany, Combining 8 Rotational Sensors 

Gizem Izgi, Eva P.S. Eibl, Frank Krüger, and Felix Bernauer

The seismic wavefield can only be completely described by the combination of translation, rotation and strain. Direct measurement of rotational motions in combination with the translational motions allow observing the complete seismic ground motion. Portable blueSeis-3A (iXblue) sensors allow to measure 3 components of rotational motions. We co-located Nanometrics Horizon seismometers with blueSeis-3A sensors and measured the full wavefield.

An active source experiment was performed in Fürstenfeldbruck, Germany in November 2019, in order to further investigate the performance of multiple rotational instruments in combination with seismometers. Within the scope of the experiment 5 explosions took place. For the first two explosions, all 8 rotational sensors were located inside of a bunker while for the rest of explosions, 4 sensors each were located at 2 different sites of the field. One group was co-located with translational seismometers. This is the first time the recordings of 8 rotational sensors are combined for event analysis and location. We calculate and intersect the back azimuths and derive phase velocities of the five explosions.

We discuss the reliability of the data recorded by the rotational sensors for further investigations in other environments.

How to cite: Izgi, G., Eibl, E. P. S., Krüger, F., and Bernauer, F.: Locating Nearby Explosions in Fürstenfeldbruck, Germany, Combining 8 Rotational Sensors, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2188, https://doi.org/10.5194/egusphere-egu22-2188, 2022.

EGU22-2455 | Presentations | SM2.1

Understanding surface-wave modal content for high-resolution imaging with ocean-bottom distributed acoustic sensing 

Zack Spica, Loïc Viens, Mathieu Perton, Kiwamu Nishida, Takeshi Akuhara, Masanao Shinohara, and Tomoaki Yamada

Ocean Bottom Distributed Acoustic Sensing (OBDAS) is emerging as a new measurement method providing dense, high-fidelity, and broadband seismic observations from fiber-optic cables. Here, we use ~40 km of a telecommunication cable located offshore the Sanriku region, Japan, and apply ambient seismic field interferometry to obtain an extended 2-D high-resolution shear-wave velocity model. In some regions of the array, we observe and invert more than 20 higher modes and show that the accuracy of the retrieval of some modes strongly depends on the processing steps applied to the data. In addition, numerical simulations suggest that the number of modes that can be retrieved is proportional to the local velocity gradient under the cable. Regions with shallow low-velocity layers tend to contain more modes than those located in steep bathymetry areas, where sediments accumulate less. Finally, we can resolve sharp horizontal velocity contrasts under the cable suggesting the presence of faults and other sedimentary features. Our results provide new constraints on the shallow submarine structure in the area and further demonstrate the potential of OBDAS for offshore geophysical prospecting.

How to cite: Spica, Z., Viens, L., Perton, M., Nishida, K., Akuhara, T., Shinohara, M., and Yamada, T.: Understanding surface-wave modal content for high-resolution imaging with ocean-bottom distributed acoustic sensing, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2455, https://doi.org/10.5194/egusphere-egu22-2455, 2022.

EGU22-2563 | Presentations | SM2.1

On the Multi-component Information of DAS for Near-Surface Seismic: A Pilot Field Experiment in the Groningen Area 

Musab Al Hasani, Guy Drijkoningen, and Kees Wapenaar

In a surface-seismic setting, Distributed Acoustic Sensing (DAS) is still not a widely adopted method for near-surface characterisation, especially for reflection seismic imaging, despite the dense spatial sampling it provides over long distances. This is mainly due to the decreased broadside sensitivity that DAS suffers from when buried horizontally in the ground (that is when the upgoing wavefield (e.g. reflected wavefield) is perpendicular to the optical fibre). This is unlike borehole settings (e.g. zero-offset Vertical Seismic Profiling), where DAS has been widely adopted for many monitoring applications. Advancements in the field, like shaping the fibre to a helix, commonly known as helically wound fibre, allow better sensitivity for the reflections.

The promise of spatially dense seismic data over long distances is an attractive prospect for retrieving the local variations of near-surface properties. This is particularly valuable for areas impacted by induced seismicity, as is the case in the Groningen Province in the north of The Netherlands,  where near-surface properties, mostly composed of clays and peats, play an essential role on the amount of damage on the very near-surface and the structures built on it. Installing fibre-optic cables for passive and active measurements is valuable in this situation. We installed multiple cables containing different fibre configurations of straight and helically wound fibres, buried in a 2-m deep trench. The combination of the different fibre configurations allows us to obtain multi-component information. We observe differences in the amplitude and phase information, suggesting that these differences can be used for separating the different components of the wave motion. We also see that using enhanced backscatter fibres, reflection images can be obtained for the helically wound fibre as well as the straight fibre, despite the decreased broadside sensitivity for the latter.

How to cite: Al Hasani, M., Drijkoningen, G., and Wapenaar, K.: On the Multi-component Information of DAS for Near-Surface Seismic: A Pilot Field Experiment in the Groningen Area, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2563, https://doi.org/10.5194/egusphere-egu22-2563, 2022.

EGU22-3404 | Presentations | SM2.1 | Highlight

Fibre-optic observation of volcanic tremor through floating ice sheet resonance 

Andreas Fichtner, Sara Klaasen, Sölvi Thrastarson, Yesim Cubuk-Sabuncu, Patrick Paitz, and Kristin Jonsdottir

We report on the indirect observation of low-frequency tremor at Grimsvötn, Iceland, via resonance of an ice sheet, floating atop a volcanically heated subglacial lake.

Entirely covered by Europe’s largest glacier, Vatnajökull, Grimsvötn is among Iceland’s largest and most active volcanoes. In addition to flood hazards, ash clouds pose a threat to settlements and air traffic, as direct interactions between magma and meltwater cause Grímsvötn to erupt explosively. To study the seismicity and structure of Grimsvötn in detail, we deployed a 12.5 km long fibre-optic cable around and inside the caldera, which we used for Distributed Acoustic Sensing (DAS) measurements in May 2021.

The experiment revealed a previously unknown level of seismicity, with nearly 2’000 earthquake detections in less than one month. Furthermore, the cable segment within the caldera recorded continuous and nearly monochromatic oscillations at 0.23 Hz. This corresponds to the expected fundamental-mode resonance frequency of flexural waves within the floating ice sheet, which effectively acts as a damped harmonic oscillator with Q around 15.

In spite of the ice sheet being affected by ambient noise at slightly lower frequencies, the resonance amplitude does not generally correlate with the level of ambient noise throughout southern Iceland. It follows that an additional and spatially localised forcing term is required to explain the observations. A linear inversion reveals that the forcing acts continuously, with periods of higher or lower activity alternating over time scales of a few days.

A plausible explanation for the additional resonance forcing is volcanic tremor, most likely related to geothermal activity, that shows surface expressions in the form of cauldrons and fumaroles along the caldera rim. Being largely below the instrument noise at channels outside the caldera, the ice sheet resonance acts as a magnifying glass that increases tremor amplitudes to an observable level, thereby providing a new and unconventional form of seismic volcano monitoring.

How to cite: Fichtner, A., Klaasen, S., Thrastarson, S., Cubuk-Sabuncu, Y., Paitz, P., and Jonsdottir, K.: Fibre-optic observation of volcanic tremor through floating ice sheet resonance, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3404, https://doi.org/10.5194/egusphere-egu22-3404, 2022.

EGU22-3728 | Presentations | SM2.1

Detecting earthen dam defects using seismic interferometry monitoring on Distributed Acoustic Sensing data 

Aurelien Mordret, Anna Stork, Sam Johansson, Anais Lavoue, Sophie Beaupretre, Romeo Courbis, Ari David, and Richard Lynch

Earthen dams and embankments are prone to internal erosion, their most significant source of failure. Standard monitoring techniques often measure erosion effects when they appear at the surface, reducing the potential response time to address the problem before failure. Through their integrative sensitivity along their propagation, seismic signals are well suited to assess mechanical changes in the bulk of a dam. Moreover, seismic velocities are strongly sensitive to porosity, pore pressure, and water saturation, physical properties that vary the most for internal erosion. Here, we used fiber optics and a Distributed Acoustic Sensing (DAS) array installed on an experimental dam with built-in defects to record the ambient seismic wavefield for one month while the dam reservoir is gradually filled up. The position and nature of the dam defects are unknown to us, to allow an actual blind-detection experiment. We computed cross-correlations between equidistant channels along the dam every 15 minutes and monitored the relative seismic velocity changes at each location for the whole month. The results show a strong correlation of the velocity changes with the water level in the reservoir at all locations along the dam. We also observe systematic deviations from the average velocity change trend. We interpret these anomalies as the effects of the built-in defects placed at different positions in the bulk of the dam. The careful analysis of the residual velocity changes allows us to hypothesize on the position and nature of the defects. 

How to cite: Mordret, A., Stork, A., Johansson, S., Lavoue, A., Beaupretre, S., Courbis, R., David, A., and Lynch, R.: Detecting earthen dam defects using seismic interferometry monitoring on Distributed Acoustic Sensing data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3728, https://doi.org/10.5194/egusphere-egu22-3728, 2022.

EGU22-3729 | Presentations | SM2.1

The Potential of DAS on Underwater Suspended Cables for Oceanic Current Monitoring and Failure Assessment of Fiber Optic Cables 

Daniel Mata, Jean-Paul Ampuero, Diego Mercerat, Diane Rivet, and Anthony Sladen

Distributed Acoustic Sensing (DAS) enables the use of existing underwater telecommunication cables as multi-sensor arrays. The great majority of underwater telecommunication cables are deployed from the water surface and the coupling between the cable and the seafloor is not fully controlled. This implies that there exists many poorly coupled cable segments less useful for seismological research. In particular, underwater cables include segments that are suspended in the water column across seafloor valleys or other bathymetry irregularities. However, it might be possible to use DAS along the suspended sections of underwater telecommunication cables for other purposes. A first one investigated here is the ability to monitor deep-ocean currents. It is common to observe that some particular sections of a cable oscillate with great amplitudes. These oscillations are commonly interpreted as due to vortex shedding induced by the currents. We investigate this hypothesis by estimating the oceanic current speeds from vortex frequencies measured in two underwater fiber optic cables located at Methoni, Greece, and another in Toulon, France. Our results in Greece are in agreement with in-situ historical measurements of seafloor currents while our estimations in Toulon are compatible with synchronous measurements of a nearby current meter. These different measurements therefore point to the possibility to exploit DAS measurements as a tool to monitor the activity of seafloor currents. A second possible application of DAS is to estimate how the cable is coupled to the seafloor, even in the absence of the strong oscillations associated to vortex shedding. For that, we have analyzed the spectral signature of the different cables. Some sections feature fundamental frequencies as expected from a theoretical model of in-plane vibration of hanging cables. By analyzing how the fundamental frequencies change along the cable, we are potentially inferring the contact points of the cable with the seafloor, which will promote fatigue of the cable and potential failure. This mapping of the coupling characteristics of the cable with the seafloor could also be useful to better interpret other DAS signals.

How to cite: Mata, D., Ampuero, J.-P., Mercerat, D., Rivet, D., and Sladen, A.: The Potential of DAS on Underwater Suspended Cables for Oceanic Current Monitoring and Failure Assessment of Fiber Optic Cables, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3729, https://doi.org/10.5194/egusphere-egu22-3729, 2022.

EGU22-4014 | Presentations | SM2.1

Near-field observations of snow-avalanches propagating over a fiber-optic array 

Patrick Paitz, Pascal Edme, Andreas Fichtner, Nadja Lindner, Betty Sovilla, and Fabian Walter

We present and evaluate array processing techniques and algorithms for the characterization of snow avalanche signals recorded with Distributed Acoustic Sensing (DAS).

Avalanche observations rely on comprehensive measurements of sudden and rapid snow mass movement that is hard to predict. Conventional avalanche sensors are limited to observations on or above the surface. Recently, seismic sensors have increased in their popularity for avalanche monitoring and characterization due to their avalanche detection and characterization capabilities. To date, however, seismic instrumentation in avalanche terrain is sparse, thereby limiting the spatial resolution significantly.

As an addition to conventional seismic instrumentation, we propose DAS to measure avalanche-induced ground motion. DAS is a technology using backscattered light along a fiber-optic cable to measure strain (-rate) along the fiber with unprecedented spatial and temporal resolution - in our example with 2 m spatial sampling and a sampling rate of 1kHz.

We analyze DAS data recorded during winter 2020/2021 at the Valleé de la Sionne avalanche test site in the Swiss Alps, utilizing an existing 700 m long fiber-optic cable. Our observations include avalanches propagating on top of the buried cable, delivering near-field observations of avalanche-ground interactions. After analyzing the properties of near-field avalanche DAS recordings, we discuss and evaluate algorithms for (1) automatic avalanche detection, (2) avalanche surge propagation speed evaluation and (3) subsurface property estimation.

Our analysis highlights the complexity of near-field DAS data, as well as the suitability of DAS-based monitoring of avalanches and other hazardous granular flows. Moreover, the clear detectability of avalanche signals using existing fiber-optic infrastructure of telecommunication networks opens the opportunity for unrivalled warning capabilities in Alpine environments.

How to cite: Paitz, P., Edme, P., Fichtner, A., Lindner, N., Sovilla, B., and Walter, F.: Near-field observations of snow-avalanches propagating over a fiber-optic array, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4014, https://doi.org/10.5194/egusphere-egu22-4014, 2022.

EGU22-4478 | Presentations | SM2.1

Non-linear ground response triggered by volcanic explosions at Etna Volcano, Italy 

Philippe Jousset, Lucile Costes, Gilda Currenti, Benjamin Schwarz, Rosalba Napoli, Sergio Diaz, and Charlotte Krawczyk

Volcanic explosions produce energy that propagates both in the subsurface as seismic waves and in the atmosphere as acoustic waves. We analyse thousands of explosions which occurred at different craters at Etna volcano (Italy) in 2018 and 2019. We recorded signals from infrasound sensors, geophones (GPH), broadband seismometers (BB) and Distributed Acoustic Sensing (DAS) with fibre optic cable. The instruments were deployed at Piano delle Concazze at about 2 to 2.5 km from the active craters, within (or onto) a ~300,000 m2 scoria layer deposited by recent volcanic eruptions. The DAS interrogator was setup inside the Pizzi Deneri Volcanic Observatory (~2800 m elevation). Infrasonic explosion records span over a large range of pressure amplitudes with the largest one reaching 130 Pa (peak to peak), with an energy of ca. 2.5x1011 J. In the DAS and the BB records, we find a 4-s long seismic “low frequency” signal (1-2 Hz) corresponding to the seismic waves, followed by a 2-s long “high-frequency” signal (16-21 Hz), induced by the infrasound pressure pulse. The infrasound sensors contain a 1-2 Hz infrasound pulse, but surprisingly no high frequency signal. At locations where the scoria layer is very thin or even non-existent, this high frequency signal is absent from both DAS strain-rate records and BB/GPH velocity seismograms. These observations suggest that the scoria layer is excited by the infrasound pressure pulse, leading to the resonance of lose material above more competent substratum. We relate the high frequency resonance to the layer thickness. Multichannel Analysis of Surface Wave from jumps performed along the fibre optic cable provide the structure of the subsurface, and confirm thicknesses derived from the explosion analysis. As not all captured explosions led to the observation of these high frequency resonance, we systematically analyze the amplitudes of the incident pressure wave versus the recorded strain and find a non-linear relationship between the two. This non-linear behaviour is likely to be found at other explosive volcanoes. Furthermore, our observations suggest it might also be triggered by other atmospheric pressure sources, like thunderstorms. This analysis can lead to a better understanding of acoustic-to-seismic ground coupling and near-surface rock response from natural, but also anthropogenic sources, such as fireworks and gas explosions.

How to cite: Jousset, P., Costes, L., Currenti, G., Schwarz, B., Napoli, R., Diaz, S., and Krawczyk, C.: Non-linear ground response triggered by volcanic explosions at Etna Volcano, Italy, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4478, https://doi.org/10.5194/egusphere-egu22-4478, 2022.

EGU22-4583 | Presentations | SM2.1

Dynamic weakening in carbonate-built seismic faults: insights from laboratory experiments with fast and ultra-localized temperature measurements 

Stefano Aretusini, Arantzazu Nuñez Cascajero, Chiara Cornelio, Xabier Barrero Echevarria, Elena Spagnuolo, Alberto Tapetado, Carmen Vazquez, Massimo Cocco, and Giulio Di Toro

During earthquakes, seismic slip along faults is localized in < 1 cm-thick principal slipping zones. In such thin slipping zones, frictional heating induces a temperature increase which activates deformation processes and chemical reactions resulting in dramatic decrease of the fault strength (i.e., enhanced dynamic weakening) and, in a negative feedback loop, in the decrease of the frictional heating itself.

In the laboratory, temperature measurements in slipping zones are extremely challenging, especially at the fast slip rates and large slip displacements typical of natural earthquakes. Recently, we measured the temperature evolution in the slipping zone of simulated earthquakes at high acquisition rates (∼ kHz) and spatial resolutions (<< 1 mm2). To this end, we used optical fibres, which convey IR radiation from the hot rubbing surfaces to a two color pyrometer, equipped with photodetectors which convert the radiation into electric signals. The measured signals were calibrated into temperature and then synchronized with the mechanical data (e.g., slip rate, friction coefficient, shear stress) to relate the dynamic fault strength to the temperature evolution and eventually constrain the deformation processes and associated chemical reactions activated during seismic slip.

Here, we reproduce earthquake slip via rotary shear experiments performed on solid cylinders (= bare rock surfaces) and on gouge layers both made of 99.9% calcite. The applied effective normal stress is 20 MPa. Bare rock surfaces are slid for 20 m with a trapezoidal velocity function with a target slip rate of 6 m/s. Instead, the gouge layers are sheared imposing a trapezoidal (1 m/s target slip rate for 1 m displacement) and Yoffe (3.5 m/s peak slip rate, and 1.5 m displacement) velocity function. The temperature measured within the slipping zone, which in some experiments increases up to 1000 °C after few milliseconds from slip initiation, allow us to investigate the deformation mechanisms responsible for fault dynamic weakening over temporal (milliseconds) and spatial (contact areas << 1 mm2) scales which are impossible to detect with traditional techniques (i.e., thermocouples or thermal cameras).

Importantly, thanks to FE numerical simulations, these in-situ temperature measurements allow us to quantify the partitioning of the dissipated energy and power between frictional heating (temperature increase) and wear processes (e.g., grain comminution), to probe the effectiveness of other energy sinks (e.g., endothermic reactions, phase changes) that would buffer the temperature increase, and to determine the role of strain localization in controlling the temperature increase. The generalization of our experimental data and observations will contribute to shed light on the mechanics of carbonate-hosted earthquakes, a main hazard in the Mediterranean and other areas worldwide.

How to cite: Aretusini, S., Nuñez Cascajero, A., Cornelio, C., Barrero Echevarria, X., Spagnuolo, E., Tapetado, A., Vazquez, C., Cocco, M., and Di Toro, G.: Dynamic weakening in carbonate-built seismic faults: insights from laboratory experiments with fast and ultra-localized temperature measurements, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4583, https://doi.org/10.5194/egusphere-egu22-4583, 2022.

EGU22-4963 | Presentations | SM2.1

A real-time classification method for pipeline monitoring combining Distributed Acoustic Sensing and Distributed Temperature and Strain Sensing 

Camille Huynh, Camille Jestin, Clément Hibert, Jean-Philippe Malet, Vincent Lanticq, and Pierre Clément

Distributed Fiber Optic Systems (DFOSs) refer to an ensemble of innovative technology that turns an optical fiber into a vast network of hundreds to thousands equally spaced sensors. According to the nature of the sensor, one can be sensitive to acoustic vibration (Distributed Acoustic Sensing, DAS) or to strain and temperature variation (Distributed Temperature and Strain Sensing, DTSS). DAS systems are well suited to detect short-term events in contrast to DTSS systems, which are intended to prevent long-term events. A combination of these two systems appears to be a good way to prevent against most possible events that can appear along an infrastructure. Furthermore, DFOS systems allow the interrogation of long profiles with very dense spatial and temporal sampling. Handling such amounts of data then appears as a challenge when trying to identify a threat along the structure. Machine learning solutions then proves their relevance for robust, fast and efficient acoustical event classification.

The goal of our study is to develop a method to handle, in real time, acquired data from these two DFOSs, classify them according to the nature of their origin and trigger an alarm if required. We mainly focus on major threats that jeopardize the integrity of pipelines. Our database contains leaks, landslides, and third-party intrusion (footsteps, excavations, drillings, etc.) simulated and measured at FEBUS Optics test bench in South-West France. Water and air leaks were simulated using electrovalves of several diameters (1mm, 3mm and 5mm), and landslides with a plate whose inclination was controlled by 4 cylinders. These data were acquired under controlled conditions in a small-scale model of pipeline (around 20m long) along different fiber optic cables installed along the structure.

Our method relies on several tools. A Machine Learning algorithm called Random Forest is used to pre-classify the DAS signal. Our implementation of this algorithm works in flow for a real time event identification. For DTSS signal, a simple threshold is used to detect if a strain or temperature variation occurs. Both results are then gathered and analyzed using a decisional table to return a classification result. According to the potential threat represented by its identified class, the event is considered as dangerous or not. Using this method, we obtain good results with a good classification rate (threat/non-threat) of 93%, compared to 87% if the DAS is used without the DTSS. We have noticed that the combination of both devices enables a better classification, especially for landslides hard to detect with the DAS. This combination enables to dramatically reduce the part of undetected threats from 16% to 4%.

How to cite: Huynh, C., Jestin, C., Hibert, C., Malet, J.-P., Lanticq, V., and Clément, P.: A real-time classification method for pipeline monitoring combining Distributed Acoustic Sensing and Distributed Temperature and Strain Sensing, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4963, https://doi.org/10.5194/egusphere-egu22-4963, 2022.

EGU22-5327 | Presentations | SM2.1

HDAS (High-Fidelity Distributed Acoustic Sensing) as a monitoring tool during 2021 Cumbre Vieja eruption 

José Barrancos, Luca D'Auria, Germán Padilla, Javier Preciado-Garbayo, and Nemesio M. Pérez

La Palma is the second youngest and westernmost among Canary Island. Cumbre Vieja volcano formed in the last stage of the geological evolution of the island and had suffered eight volcanic eruptions over the previous 500 years. In 2017, two remarkable seismic swarms interrupted a seismic silence from the last eruption (Teneguía, 1971). Since then, nine additional seismic swarms have occurred at Cumbre Vieja volcano. On September 11th, 2021, seismic activity began to increase, and the depths of the earthquakes showed an upward migration. Finally, on September 19th, the eruption started after just a week of precursors.

During recent years, the seismic activity has been recorded by Red Sísmica Canaria (C7), composed of 6 seismic broadband stations, which was reinforced during the eruption by five additional broadband stations, three accelerometers and a seismic array consisting of 10 broadband stations.

Furthermore, as a result of a collaboration between INVOLCAN, ITER, CANALINK and Aragón Photonics Labs, it was possible to install, on October 19th, an HDAS (High-fidelity Distributed Acoustic Sensor). The HDAS was installed about 10 km from the eruptive vent and was connected to a submarine fibre optic cable directed toward Tenerife Island. Since then, the HDAS has been recording seismic with a temporal sampling rate of 100 Hz and a spatial sampling rate of 10m for a total length of 50 km using Raman Amplification. For more than two months, in addition to the intense volcanic tremor, the HDAS recorded thousands of earthquakes as well as regional and teleseismic events. On December 13th, 2021, after an intense paroxysmal phase with an eruptive column that reached 8 km in height, the volcanic tremor quickly decreased, and the eruption suddenly stopped. Only a weak volcano-tectonic seismicity and small amplitude long-period events were recorded in the next month.

This valuable dataset will provide a milestone for the development of techniques aimed at using DAS as a real-time volcano monitoring tool and studying the internal structure of active volcanoes.

How to cite: Barrancos, J., D'Auria, L., Padilla, G., Preciado-Garbayo, J., and Pérez, N. M.: HDAS (High-Fidelity Distributed Acoustic Sensing) as a monitoring tool during 2021 Cumbre Vieja eruption, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5327, https://doi.org/10.5194/egusphere-egu22-5327, 2022.

EGU22-5551 | Presentations | SM2.1

A showcase pilot of seismic campaign using Distributed Acoustic Sensing solutions 

Camille Jestin, Christophe Maisons, Aurélien Chérubini, Laure Duboeuf, and Jean-Claude Puech

Distributed Acoustic Sensing (DAS) is a rapidly evolving technology that can turn a fibre optic cable into thousands of acoustic sensors. In this study, we propose to present a seismic survey conducted as a business showcase relying on a collaborative work supported by five partners: FEBUS Optics, RealTimeSeismic (RTS), Gallego Technic Geophysics (GTG), Petro LS and Well-SENSE. The project was carried out at a deep solution mining site developed for salt production, operated by KEMONE, and located nearby Montpellier (South of France).

The seismic campaign was based on two different cable deployments.

On the first hand, a Vertical Seismic Profile survey was conducted on borehole seismic measurements using two different fibre optic cables deployed in a 1800m deep vertical well. The first set of tests was performed along a Petro LS wireline cable including optical fibres. This deployment corresponds to a conventional wireline operation. The second set of data has been acquired along a FibreLine Intervention system (FLI) developed by WellSENSE. The deployment of the FLI system relies on the unspooling a bare optical fibre using a probe along a wellbore. This solution is single-use and sacrificial and can be left in the well at the end of the survey.

On another hand, a short 400m-surface 2D profile has been achieved along both a fibre optic cable and a set of STRYDE nodes deployed by GTG.

Fibre optic cables have been connected to FEBUS DAS interrogator to collect distributed acoustic measurements.  The seismic tests, performed in collaboration with GTG, have been achieved with basic “weight drops” (1T falling from 4m) for the checkshot surveys and with an "IVI Mark 4" 44,000-pound seismic vibrator for VSP shots at offset from wellhead reaching 865m. Acquired data have been analysed by RTS.

This work will describe the survey, present the results, and discuss the learnings in two ways:  the optimisation of acquisition setups and processing parameters to obtain the best exploitable results and seismic surveys perspectives and challenges using DAS technology.

How to cite: Jestin, C., Maisons, C., Chérubini, A., Duboeuf, L., and Puech, J.-C.: A showcase pilot of seismic campaign using Distributed Acoustic Sensing solutions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5551, https://doi.org/10.5194/egusphere-egu22-5551, 2022.

EGU22-5743 | Presentations | SM2.1

Making sense of urban DAS data with clustering of coherence-based array features 

Julius Grimm and Piero Poli

Seismic noise monitoring in urban areas can yield valuable information about near-surface structures and noise sources like traffic activity. Distributed Acoustic Sensing (DAS) is ideal for this task due to its dense spatial resolution and the abundance of existing fiber-optic cables below cities.
A 15 km long dark fiber below the city of Grenoble was transformed into a dense seismic antenna by connecting it to a Febus A1-R interrogator unit. The DAS system acquired data continuosly for 11 days with a sampling frequency of 250 Hz and a channel spacing of 19.2 m, resulting in a total of 782 channels. The cable runs through the entirety of the city, crossing below streets, tram tracks and a river. Various noise sources are visible on the raw strain-rate data. A local earthquake (1.3 MLv) was also recorded during the acquisition period.
To characterize the wavefield, the data is divided into smaller sub-windows and coherence matrices at different frequency bands are computed for each sub-window. Clustering is then performed directly on the covariance matrices, with the goal of identifying repeating sub-structures in the covariance matrices (e.g. localized repeating noise sources). Finding underlying patterns in the complex dataset helps us to better understand the spatio-temporal distribution of the occurring signals.

How to cite: Grimm, J. and Poli, P.: Making sense of urban DAS data with clustering of coherence-based array features, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5743, https://doi.org/10.5194/egusphere-egu22-5743, 2022.

EGU22-5952 | Presentations | SM2.1

Strombolian seismic activity characterisation using fibre-optic cable and distributed acoustic sensing 

Jean-Philippe Metaxian, Francesco Biagioli, Maurizio Ripepe, Eléonore Stutzmann, Pascal Bernard, Roberto Longo, Marie-Paule Bouin, and Corentin Caudron

Stromboli is an open-conduit volcano characterized by mild intermittent explosive activity that produces jets of gas and incandescent blocks. Explosions occur at a typical rate of 3-10 events per hour, VLP signals have dominant periods between 2 and 30 seconds. Seismic activity is also characterized by less energy short-period volcanic tremor related to the continuous out-bursting of small gas bubbles in the upper part of the magmatic column. The high rate of activity as well as the broadband frequency contents of emitted signals make Stromboli volcano an ideal site for testing new techniques of fibre-optic sensing.

In September 2020, approximately 1 km of fiber-optic cable was deployed on the Northeast flank of Stromboli volcano, together with several seismometers, to record the seismic signals radiated by the persistent Strombolian activity via both DAS and inertial-seismometers, and to compare their records.

The cable was buried manually about 30 cm deep over a relatively linear path at first and in a triangle-shaped array with 30-meters-long sides in the highest part of the deployment. The strain rate was recorded using a DAS interrogator Febus A1-R with a sampling frequency of 2000 Hz, a spatial interval of 2.4 m and a gauge length of 5m. Data were re-sampled at 200 Hz. A network of 22 nodes SmartSolo IGU-16HR 3C geophones (5 Hz) has been distributed over the fibre path. A Guralp digitizer equipped with a CMG CMG-40T 30 sec seismometer and an infrasound sensor were placed in the upper part of the path. The geolocation of the cable was obtained by performing kinematic GPS measurements with 2 Leica GR25 receivers. All equipment recorded simultaneously several hundreds of explosion quakes between September 20 and 23.

Data analysis provided the following main results:

  • DAS interrogator clearly recorded the numerous explosion-quakes which occurred during the experiment, as well as lower amplitude tremor and LP events.
  • DAS spectrum exhibits a lower resolution at long periods with a cut-off frequency of approximately 3 Hz.
  • VLP seismic events generated by Strombolian activity are identified only at a few DAS channels belonging to a specific portion of the path, which seems affected by local amplification. At these channels, they display waveforms similar to those sensed by the Güralp CMG-40T.
  • Comparison of DAS strain waveform to particle velocity recorded by co-located seismometers shows a perfect match in phase and a good agreement in amplitude.
  • Beamforming methods have been applied to nodes data located on the upper triangle and to strain rate data, both in the 3-5 Hz frequency band. Slightly different back-azimuths were obtained, values estimated via DAS point more to the southwest with respect to the crater area. Apparent velocities obtained with DAS recordings have lower values compared to those obtained with nodes.

How to cite: Metaxian, J.-P., Biagioli, F., Ripepe, M., Stutzmann, E., Bernard, P., Longo, R., Bouin, M.-P., and Caudron, C.: Strombolian seismic activity characterisation using fibre-optic cable and distributed acoustic sensing, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5952, https://doi.org/10.5194/egusphere-egu22-5952, 2022.

EGU22-6580 | Presentations | SM2.1

Quantifying microseismic noise generation from coastal reflection of gravity waves using DAS 

Gauthier Guerin, Diane Rivet, Martijn van den Ende, Eléonore Stutzmann, Anthony Sladen, and Jean-Paul Ampuero

Secondary microseisms are the most energetic noise in continuous seismometer recordings, and they are generated by interactions between ocean waves. Coastal reflections of ocean waves leading to coastal microseismic sources are hard to estimate in various global numerical wave models, and independent quantification of these coastal sources through direct measurements can therefore greatly improve these models. Here, we exploit a 40 km long submarine optical fiber cable located offshore Toulon, France using Distributed Acoustic Sensing (DAS). We record both the amplitude and frequency of ocean gravity waves, as well as secondary microseisms caused by the interaction of gravity waves incident and reflected from the coast. By leveraging the spatially distributed nature of DAS measurements, additional fundamental information are recovered such as the velocity and azimuth of the waves. On average, 30\% of the gravity waves are reflected at the shore and lead to the generation of local secondary microseisms that manifest as Scholte waves. These local sources can give way to other sources depending on the characteristics of the swell, such as its azimuth or its strength. These sources represent the most energetic contribution to the secondary microseism recorded along the optical fiber, as well as on an onshore broadband station. Furthermore, we estimate the coastal reflection coefficient R$^2$ to be constant at around 0.07 for our 5-day time series. The use of DAS in an underwater environment provides a wealth of information on coastal reflection sources, reflection of gravity waves and new constraints for numerical models of microseismic noise.

How to cite: Guerin, G., Rivet, D., van den Ende, M., Stutzmann, E., Sladen, A., and Ampuero, J.-P.: Quantifying microseismic noise generation from coastal reflection of gravity waves using DAS, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6580, https://doi.org/10.5194/egusphere-egu22-6580, 2022.

EGU22-6976 | Presentations | SM2.1

Comparison between Distributed Acoustic Sensing (DAS) and strain meter measurements at the Black Forest Observatory 

Jérôme Azzola, Nasim Karamzadeh Toularoud, Emmanuel Gaucher, Thomas Forbriger, Rudolf Widmer-Schnidrig, Felix Bögelspacher, Michael Frietsch, and Andeas Rietbrock

We present an original DAS measurement station, equipped with the Febus A1-R interrogator, which has been deployed at the Black Forest Observatory (Schiltach, Germany). The objective of this deployment is twofold. The first is to test the deployed fibre optic cables and to better characterise the recorded signals. The second is to define standards for the processing of these DAS measurements, with a view to using the equipment for passive seismic monitoring in the INSIDE project (supported by the German Federal Ministry for Economic Affairs and Energy, BMWi).

Testing sensors involving new acquisition technologies, such as instruments based on Distributed Fiber Optic Sensing (DFOS), is part of the observatory's goals, in order to assess, to maintain and to improve signal quality. Interestingly, reference geophysical instruments are also deployed on a permanent basis in this low seismic-noise environment. Our analyses thus benefit from the records of the observatory's measuring instruments, in particular a set of three strain meters recording along various azimuths. This configuration enables a unique comparison between strain meter and DAS measurements. In addition, an STS-2 seismometer (part of German Regional Seismic Network, GRSN) allows for additional comparisons.

These instruments provide a basis for a comparative analysis between the DAS records and the measurements of well-calibrated sensing devices (STS-2 sensor, strain meter array). Such a comparison is indeed essential to physically understand the measurements provided by the Febus A1-R interrogator and to characterise the coupling between the ground and the fiber, in various deployment configurations.

We present the experiment where we investigate several Fiber Optic Cable layouts, with currently our most successful setup involving loading a dedicated fiber with sandbags. We discuss different processing approaches, resulting in a considerable improvement of the fit between DAS and strain array acquisitions. The presented comparative analysis is based on the recordings of different earthquakes, including regional and teleseismic events.

How to cite: Azzola, J., Toularoud, N. K., Gaucher, E., Forbriger, T., Widmer-Schnidrig, R., Bögelspacher, F., Frietsch, M., and Rietbrock, A.: Comparison between Distributed Acoustic Sensing (DAS) and strain meter measurements at the Black Forest Observatory, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6976, https://doi.org/10.5194/egusphere-egu22-6976, 2022.

EGU22-6984 | Presentations | SM2.1

Array signal processing on distributed acoustic sensing data: directivity effects in slowness space 

Sven Peter Näsholm, Kamran Iranpour, Andreas Wuestefeld, Ben Dando, Alan Baird, and Volker Oye

Distributed Acoustic Sensing (DAS) involves the transmission of laser pulses along a fiber-optic cable. These pulses are backscattered at fiber inhomogeneities and again detected by the same interrogator unit that emits the pulses. Elastic deformation along the fiber causes phase shifts in the backscattered laser pulses which are converted to spatially averaged strain measurements, typically at regular fiber intervals.

DAS systems provide the potential to employ array processing algorithms. However, there are certain differences between DAS and conventional sensors. The current paper is focused on taking these differences into account. While seismic sensors typically record the directional particle displacement, velocity, or acceleration, the DAS axial strain is inherently proportional to the spatial gradient of the axial cable displacement. DAS is therefore insensitive to broadside displacement, e.g., broadside P-waves. In classical delay-and-sum beamforming, the array response function is the far-field response on a horizontal slowness (or wavenumber) grid. However, for geometrically non-linear DAS layouts, the angle between wavefront and cable varies, requiring the analysis of a steered response that varies with the direction of arrival. This contrasts with the traditional array response function which is given in terms of slowness difference between arrival and steering.

This paper provides a framework for DAS steered response estimation accounting also for cable directivity and gauge-length averaging – hereby demonstrating the applicability of DAS in array seismology and to assess DAS design aspects. It bridges a gap between DAS and array theory frameworks and communities, facilitating increased employment of DAS as a seismic array.

How to cite: Näsholm, S. P., Iranpour, K., Wuestefeld, A., Dando, B., Baird, A., and Oye, V.: Array signal processing on distributed acoustic sensing data: directivity effects in slowness space, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6984, https://doi.org/10.5194/egusphere-egu22-6984, 2022.

EGU22-7153 | Presentations | SM2.1

MEGLIO: an experiment to record seismic waves on a commercial fiber optic cable through interferometry measures with an ultra stable laser. 

Andre Herrero, Davide Calonico, Francesco Piccolo, Francesco Carpentieri, Aladino Govoni, Lucia Margheriti, Maurizio Vassallo, Rita di Giovambattista, Salvatore Stramondo, Cecilia Clivati, Roberto Concas, Simone Donadello, Fabio Simone Priuli, Filippo Orio, and Andrea Romualdi

The experiment MEGLIO follows the seminal work of Marra et al. (2018) where the authors demonstrate the possibility to observe seismic waves on fiber optic cables over large distances. The measure was based on an interferometric technique using an ultra stable laser. In theory, this active measurement technique is compatible with a commercial operation on a fiber, i.e. the fiber does not need to be dark. In 2019, Open Fiber, the largest optic fiber infrastructure provider in Italy, has decided to test this new technology on its own commercial network on land.

A team of experts in the different fields has been gathered to achieve this goal : besides Open Fiber, Metallurgica Bresciana; INRiM, which initially developed the technique, for their expertise on laser and sensors; Bain & Company for the analysis and the processing of the data; INGV for the expertise in the seismology field and for the validation of the observations.

The first year has been dedicated to developing the sensors. In the meantime, a buried optic cable has been chosen in function of its length and the seismicity nearby. The best candidate was the fiber connecting the towns of Ascoli Piceno (Marche, Italy) and Teramo (Abruzzo, Italy) for a length of around 30 km. Although  this technique allows using cable lengths larger than 5.000 km, for this first test we have decided to keep the length short. Actually the cable is mainly buried underneath a road with medium traffic, passes across different bridges and viaducts, starts in the middle of a town and loops in the middle of another town. Thus we expected a strong anthropic noise on the data.

The measurement on the field started in mid June 2020 and the system was operational in early July. We also installed a seismic station at one end of the cable. During these first six months, we have compared the observations on the fiber with the Italian national seismic catalog and the worldwide catalog for the major events. We consider the first results a success. We have detected so far nearly all the seismic activity with magnitude larger than 2.5 for epicentral distance lesser than 50 km. Moreover, we have recorded large events in Mediterranean region and teleseisms. Finally we have recorded new and interesting noise signals. Collecting additional events will be helpful for a better characterization of the technique, its performances and for a statistical analysis.

How to cite: Herrero, A., Calonico, D., Piccolo, F., Carpentieri, F., Govoni, A., Margheriti, L., Vassallo, M., di Giovambattista, R., Stramondo, S., Clivati, C., Concas, R., Donadello, S., Priuli, F. S., Orio, F., and Romualdi, A.: MEGLIO: an experiment to record seismic waves on a commercial fiber optic cable through interferometry measures with an ultra stable laser., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7153, https://doi.org/10.5194/egusphere-egu22-7153, 2022.

EGU22-7182 | Presentations | SM2.1 | Highlight

Monitoring a submarine strike-slip fault, using a fiber optic strain cable 

Marc-Andre Gutscher, Jean-Yves Royer, David Graindorge, Shane Murphy, Frauke Klingelhoefer, Arnaud Gaillot, Chastity Aiken, Antonio Cattaneo, Giovanni Barreca, Lionel Quetel, Giorgio Riccobene, Salvatore Aurnia, Lucia Margheriti, Milena Moretti, Sebastian Krastel, Florian Petersen, Morelia Urlaub, Heidrun Kopp, Gilda Currenti, and Philippe Jousset

The goal of the ERC (European Research Council) funded project - FOCUS is to apply laser reflectometry on submarine fiber optic cables to detect deformation at the seafloor in real time using BOTDR (Brillouin Optical Time Domain Reflectometry). This technique is commonly used monitoring large-scale engineering infrastructures (e.g. - bridges, dams, pipelines, etc.) and can measure very small strains (<< 1 mm/m) at very large distances (10 - 200 km), but until now has never been used to study tectonic faults and deformation on the seafloor.

Here, we report that BOTDR measurements detected movement at the seafloor consistent with ≥1 cm dextral strike-slip on the North Alfeo fault, 25 km offshore Catania, Sicily over the past 10 months. In Oct. 2020 a dedicated 6-km long fiber-optic strain cable was connected to the INFN-LNS (Catania physics institute) cabled seafloor observatory at 2060 m depth and deployed across this submarine fault, thus providing continuous monitoring of seafloor deformation at a spatial resolution of 2 m. The laser observations indicate significant elongation (20 - 40 microstrain) at two fault crossings, with most of the movement occurring between 19 and 21 Nov. 2020. A network of 8 seafloor geodetic stations for direct path measurements was also deployed in Oct. 2020, on both sides of the fault to provide an independent measure of relative seafloor movements. These positioning data are being downloaded during ongoing oceanographic expeditions to the working area (Aug. 2021 R/V Tethys; Jan. 2022 R/V PourquoiPas) using an acoustic modem to communicate with the stations on the seafloor. An additional experiment was performed in Sept. 2021 using an ROV on the Fugro vessel Handin Tide, by weighing down unburied portions of the submarine cable with pellet bags and sandbags (~25kg each) spaced every 5m. The response was observed simultaneously by DAS (Distributed Acoustic Sensing) recordings using two DAS interrogators (a Febus and a Silixa). The strain caused by the bag deployments was observed using BOTDR and typically produced a 50 - 100 microstrain signal across the 120 meter-long segments which were weighed down. In Jan. 2022 during the FocusX2 marine expedition, 21 ocean bottom seismometers were deployed for 12-14 months, which together with 15 temporary land-stations as well as the existing network of permanent stations (both operated by INGV) will allow us to perform a regional land-sea passive seismological monitoring experiment.

How to cite: Gutscher, M.-A., Royer, J.-Y., Graindorge, D., Murphy, S., Klingelhoefer, F., Gaillot, A., Aiken, C., Cattaneo, A., Barreca, G., Quetel, L., Riccobene, G., Aurnia, S., Margheriti, L., Moretti, M., Krastel, S., Petersen, F., Urlaub, M., Kopp, H., Currenti, G., and Jousset, P.: Monitoring a submarine strike-slip fault, using a fiber optic strain cable, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7182, https://doi.org/10.5194/egusphere-egu22-7182, 2022.

EGU22-7203 | Presentations | SM2.1

Multiphase observations of a meteoroid in Iceland recorded over 40 km of telecommunications cables and a large-N network 

Ismael Vera Rodriguez, Torsten Dahm, Marius P. Isken, Toni Kraft, Oliver D. Lamb, Sin-Mei Wu, Sebastian Heimann, Pilar Sanchez-Pastor, Christopher Wollin, Alan F. Baird, Andreas Wüstefeld, Sigríður Kristjánsdóttir, Kristín Jónsdóttir, Eva P. S. Eibl, Bettina P. Goertz-Allmann, Philippe Jousset, Volker Oye, and Anne Obermann

On July 2, 2021, around 22:44 CET, a meteoroid was observed crossing the sky near Lake Thingvallavatn east of Reykjavik in Iceland. During this event, a large-N seismic network consisting of 500, 3-component geophones was monitoring local seismicity associated with the Hengill geothermal field southwest of the lake.  In addition to the large-N network, two fiber optic telecommunication cables, covering a total length of more than 40 km, were connected to distributed acoustic sensing (DAS) interrogation units. The systems were deployed under the frame of the DEEPEN collaboration project between the Eidgenössische Technische Hochschule Zürich (ETHZ), the German Research Centre for Geosciences (GFZ), NORSAR, and Iceland Geo-survey (ISOR). Both the large-N and the DAS recordings display multiple trains of infrasound arrivals from the meteoroid that coupled to the surface of the earth at the locations of the sensors. In particular, three strong phases and multiple other weaker arrivals can be identified in the DAS data.

Fitting each of the strong phases assuming point sources (i.e., fragmentations) generates travel time residuals on the order of several seconds, resulting in an unsatisfactory explanation of the observations. On the other hand, inverting the arrival times for three independent hypersonic-trajectories generating Mach cone waves reduces travel time residuals to well under 0.5 s for each arrival. However, whereas the 1st arrival is well constrained by more than 900 travel times from the large-N, DAS and additional seismic stations distributed over the Reykjanes peninsula, the 2nd and 3rd arrivals are mainly constrained by DAS observations near Lake Thingvallavatn. The less well-constrained, latter trajectories show a weak agreement with the trajectory of the first arrival. Currently, neither the multi-Mach-cone model nor the multi-fragmentation model explain all our observations satisfactorily. Thus, traditional models for interpreting meteoroid observations appear unsuitable to explain the combination of phase arrivals in the large-N network and DAS data consistently.

How to cite: Vera Rodriguez, I., Dahm, T., Isken, M. P., Kraft, T., Lamb, O. D., Wu, S.-M., Heimann, S., Sanchez-Pastor, P., Wollin, C., Baird, A. F., Wüstefeld, A., Kristjánsdóttir, S., Jónsdóttir, K., Eibl, E. P. S., Goertz-Allmann, B. P., Jousset, P., Oye, V., and Obermann, A.: Multiphase observations of a meteoroid in Iceland recorded over 40 km of telecommunications cables and a large-N network, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7203, https://doi.org/10.5194/egusphere-egu22-7203, 2022.

EGU22-7311 | Presentations | SM2.1

Calibration and repositioning of an optical fibre cable from acoustic noise obtained by DAS technology 

Lucas Papotto, Benoit DeCacqueray, and Diane Rivet

DAS (Distributed Acoustic Sensing) turns fibre optic cables used for telecommunications into multi-sensor antenna arrays. This technology makes it possible to detect an acoustic signal from a natural source such as cetacean or micro-earthquakes, or a man-made source by measuring the deformation of the cable. At sea, the coupling between the optical fibre and the ground on which it rests, as well as the calibration of the cable, is a critical point when the configuration of the cable is unknown. Is the fibre buried or suspended? What is the depth of the sensor being studied? What impact do these parameters have on the signal? The answers to these questions have an impact on the quality of the results obtained, the location of sources - seismic or acoustic - and the characterisation of the amplitude of signals are examples of this. Here, a first approach to study this calibration is proposed. Acoustic noise generated by passing ships in the vicinity of a 42km long optical fibre off Toulon, south-east France, is used to obtain signals for which the position and the signal of the source are known. Then, the synthetic and theoretical signal representing the ship's passage is modelled (3D model, AIS Long/Lat coordinates and depth, propagation speed in water c₀ = 1530m/s). This simulation allows us to compare the real and synthetic signals, in order to make assumptions about the actual cable configuration. We compare the signals through beamforming, f-k diagram and time-frequency diagram in particular. The grid search approach allowed us to determine the new position or orientation of a portion of the antenna. This new position is then evaluated from the signals of different vessels.

How to cite: Papotto, L., DeCacqueray, B., and Rivet, D.: Calibration and repositioning of an optical fibre cable from acoustic noise obtained by DAS technology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7311, https://doi.org/10.5194/egusphere-egu22-7311, 2022.

EGU22-7742 | Presentations | SM2.1

Strain evolution on a submarine cable during the 2020-2021 Etna eruption 

Shane Murphy, Pierre Garreau, Mimmo Palano, Stephan Ker, Lionel Quetel, Philippe Jousset, Giorgio Riccobene, Salvatore Aurnia, Gilda Currenti, and Marc-Andre Gutscher

On the 13th December 2020, a Strombolian eruption occurred on Mount Etna. We present a study of the temporal and spatial variation of strain measured at the underwater base of volcano during this event. 

As part of the FOCUS project, a BOTDR (Brillouin Optical Time Domain Reflectometry) interrogator has been connected to the INFN-LNS ( Istituto Nazionale di Fisica Nucleare - Laboratori Nazionali del Sud) fibre optic cable that extends from the port of Catania 25km offshore to TTS (Test Site South) in a water depth of 2km. This interrogator has been continuously recording the relative strain changes at 2m spacing along the length of the cable every 2 hrs since May 2020. 

On preliminary analysis, a change in strain is observed at the around the time of the eruption, however this variation occurs close to the shore where seasonal variations in water temperatures are in the order of 5°C. As Brillouin frequency shifts are caused by both temperature and strain variations, it is necessary to remove this effect. To do so, numerical simulations of seasonal sea temperature specific to offshore Catania have used to estimate the change in temperature along the cable. This temperature change is then converted to a Brillouin frequency shift and removed from the frequency shift recorded by the interrogator before being converted to relative strain measurements. This processing produces a strain signature that is consistent with deformation observed by nearby geodetic stations on land.

How to cite: Murphy, S., Garreau, P., Palano, M., Ker, S., Quetel, L., Jousset, P., Riccobene, G., Aurnia, S., Currenti, G., and Gutscher, M.-A.: Strain evolution on a submarine cable during the 2020-2021 Etna eruption, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7742, https://doi.org/10.5194/egusphere-egu22-7742, 2022.

EGU22-8113 | Presentations | SM2.1

Exploration of Distributed Acoustic Sensing (DAS) data-space using a trans-dimensional algorithm, for locating geothermal induced microseismicity 

Nicola Piana Agostinetti, Emanuele Bozzi, Alberto Villa, and Gilberto Saccorotti

Distributed Acoustic sensing (DAS) data have been widely recognised as the next generation of  seismic data for applied geophysics, given the ultra-high spatial resolution achieved. DAS data are recorded along a fiber optic cable at pre-defined distances (called “channels”, generally with 1-10 meters spacing). DAS data have been benchmarked to standard seismic data (e.g. geophones) for tasks related to both exploration and monitoring of georesources.

The analysis of DAS data has to face two key-issues: the amount of data available and their “directionality”. First, the huge amount of data recorded, e.g. in monitoring activities related to georesources exploitation, can not be easily handled with standard seismic workflow, given the spatial and temporal sampling (for example, manual picking of P-wave arrivals for 10 000 channels is not feasible). Moreover, standard seismic workflow have been generally developed for “sparse" network of sensors, i.e. for punctual measurements, without considering the possibility of recording the quasi-continuous seismic wavefield along a km-long cable. With the term “directionality" we mean the ability of the DAS data to record horizontal strain-rate only in the direction of the fiber optic cable. This can be seen as a measure of a single horizontal component in a standard seismometer. Obviously, standard seismic workflow have not been developed to work correctly for a network of seismometers with a unique horizontal component, oriented with variable azimuth from one seismometer to the other. More important, “directionality” can easily bias the recognition of the seismic phase arriving at the channel, which could be, based on the cable azimuth and the seismic noise level, a P-wave or an S-wave. 

We developed a novel application for exploring DAS data-space in a way that: (1) data are automatically down weighted with the distance from the event source; (2) recorded phases are associated to P- or S- waves with a probabilistic approach, without pre-defined phase identification; and (3) the presence of outliers is also statistically considered, each phase being potentially a converted/refracted wave to be discarded. Our methodology makes use of a trans-dimensional algorithm, for selecting relevant weights with distance. Thus, all inferences in the data-space are fully data-driven, without imposing additional constrains from the seismologist.

How to cite: Piana Agostinetti, N., Bozzi, E., Villa, A., and Saccorotti, G.: Exploration of Distributed Acoustic Sensing (DAS) data-space using a trans-dimensional algorithm, for locating geothermal induced microseismicity, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8113, https://doi.org/10.5194/egusphere-egu22-8113, 2022.

EGU22-8294 | Presentations | SM2.1 | Highlight

Real-Time Magnitude Determination and Ground Motion Prediction using Optical Fiber Distributed Acoustic Sensing for Earthquake Early Warning 

Itzhak Lior, Diane Rivet, Anthony Sladen, Diego Mercerat, and Jean-Paul Ampuero

Distributed Acoustic Sensing (DAS) is ideally suited for the challenges of Earthquake Early Warning (EEW). These distributed measurements allow for robust discrimination between earthquakes and noise, and remote recordings at hard to reach places, such as offshore, close to the hypocenters of most of the largest earthquakes on Earth. In this study, we propose the first application of DAS for EEW. We present a framework for real-time strain-rate to ground accelerations conversion, magnitude estimation and ground shaking prediction. The conversion is applied using the local slant-stack transform, adapted for real-time applications. Since currently, DAS earthquake datasets are limited to low-to-medium magnitudes, an empirical magnitude estimation approach is not feasible. To estimate the magnitude, we derive an Omega-squared-model based theoretical description for acceleration root-mean-squares (rms), a measure that can be calculated in the time-domain. Finally, peak ground motions are predicted via ground motion prediction equation that are derived using the same theoretical model, thus constituting a self-consistent EEW scheme. The method is validated using a composite dataset of earthquakes from different tectonic settings up to a magnitude of 5.7. Being theoretical, the presented approach is readily applicable to any DAS array in any seismic region and allows for continuous updating of magnitude and ground shaking predictions with time. Applying this method to optical fibers deployed near on-land and underwater faults could be decisive in the performance of EEW systems, significantly improving earthquake warning times and allowing for better preparedness for intense shaking.

How to cite: Lior, I., Rivet, D., Sladen, A., Mercerat, D., and Ampuero, J.-P.: Real-Time Magnitude Determination and Ground Motion Prediction using Optical Fiber Distributed Acoustic Sensing for Earthquake Early Warning, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8294, https://doi.org/10.5194/egusphere-egu22-8294, 2022.

EGU22-8414 | Presentations | SM2.1

Towards microseismic moment tensor inversion in boreholes with DAS 

Katinka Tuinstra, Federica Lanza, Andreas Fichtner, Andrea Zunino, Francesco Grigoli, Antonio Pio Rinaldi, and Stefan Wiemer

We present preliminary results on a moment tensor inversion workflow for Distributed Acoustic Sensing (DAS). It makes use of a fast-marching Eikonal solver and synthetically modeled data. The study specifically focuses on borehole settings for geothermal sites. Distributed Acoustic Sensing measures the wavefield with high spatial and temporal resolution. In borehole settings, individual DAS traces generally prove to be noisier than co-located geophones, whereas the densely spaced DAS shot-gathers show features that would have otherwise been missed by the commonly more sparsely distributed geophone chains. For example, the coherency in the DAS records shows the polarity reversals of the arriving wavefield in great detail, which can help constrain the moment tensor of the seismic source. The synthetic tests encompass different source types and source positions relative to the deployed fiber to assess moment tensor resolvability. Further tests include the addition of a three-component seismometer at different positions to investigate an optimal network configuration, as well as various noise conditions to mimic real data. The synthetic tests are tailored to prepare for the data from future microseismicity monitoring with DAS in the conditions of the Utah FORGE geothermal test site, Utah, USA. The proposed method aims at improving amplitude-based moment tensor inversion for DAS deployed in downhole or underground lab contexts.

How to cite: Tuinstra, K., Lanza, F., Fichtner, A., Zunino, A., Grigoli, F., Rinaldi, A. P., and Wiemer, S.: Towards microseismic moment tensor inversion in boreholes with DAS, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8414, https://doi.org/10.5194/egusphere-egu22-8414, 2022.

EGU22-8664 | Presentations | SM2.1

Seismic Exploration and monitoring of geothermal reservoirs usiNg distributed fibre optic Sensing - the joint project SENSE 

CharLotte Krawczyk, Leila Ehsaniezhad, Christopher Wollin, Johannes Hart, and Martin Lipus

For a successful operation of energy or resources use in the subsurface, exploration for potential reservoir or storage horizons, monitoring of structural health and control of induced seismic unrest are essential both from a technical and a socio-economic perspective.  Furthermore, large-scale seismic surveys in densely populated areas are difficult to carry out due to the effort required to install sources and receivers and are associated with high financial and logistical costs.  Within the joint project SENSE*, a seismic exploration and monitoring approach is tested, which is based on fibre-optic sensing in urban areas.

Besides the further development of sensing devices, the monitoring of borehole operations as well as the development of processing workflows form central parts of the joint activities. In addition, the seismic wave field was recorded and the localisation of the cables was tested along existing telecommunication cables in Berlin. Further testing of measuring conditions in an urban environment was also conducted along an optic fibre separately laid out in an accessible heating tunnel.

We suggest a workflow for virtual shot gather extraction (e.g., band pass filtering, tapering, whitening, removal of poor traces before and after cross-correlation, stacking), that is finally including a coherence-based approach.  The picking of dispersion curves in the 1-7 Hz frequency range and inversion yield a shear wave velocity model for the subsurface down to a. 300 m depth.  Several velocity interfaces are evident, and a densely staggered zone appears between 220-270 m depth.  From lab measurements a distributed backscatter measurement in OTDR mode shows that high reflections and moderate loss at connectors can be achieved in a several hundred m distance.  Depending on drilling campaign progress, we will also present first results gained during the borehole experiment running until February 2022.

* The SENSE Research Group includes in addition to the authors of this abstract Andre Kloth and Sascha Liehr (DiGOS), Katerina Krebber and Masoud Zabihi (BAM), Bernd Weber (gempa), and Thomas Reinsch (IEG).

How to cite: Krawczyk, C., Ehsaniezhad, L., Wollin, C., Hart, J., and Lipus, M.: Seismic Exploration and monitoring of geothermal reservoirs usiNg distributed fibre optic Sensing - the joint project SENSE, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8664, https://doi.org/10.5194/egusphere-egu22-8664, 2022.

EGU22-8787 | Presentations | SM2.1

PSD analysis and seismic event detectability of Distributed Acoustic Sensing (DAS) mesurements from several monitoring sites 

Nasim Karamzadeh Toularoud, Jérôme Azzola, Emmanuel Gaucher, Thomas Forbriger, Rudolf Widmer-Schnidrig, Felix Bögelspacher, Michael Frietsch, and Andreas Rietbrock

High spatial and temporal resolution of distributed acoustic sensing (DAS) measurements makes them very attractive in different applications in seismology, such as seismic noise analysis (e.g. Bahavar et al 2020, Spica et al 2020) and seismic event detection (e.g. Ajo-Franklin et al 2019, Fernandez Ruiz 2020, Jousset 2020). The quantity measured by a DAS is strain or strain rate of an optic fiber cable, which is related to the spatial gradient of displacement and velocity that is usually measured by single point seismometers. The amplitude (and signal to noise ratio, SNR) and frequency resolutions of DAS recordings depend on spatial and temporal acquisition parameters, such as i.e. gauge-length (GL) and derivative time (DT), the latter being of importance only if the device records the strain rate.

In this study, our aims have been to investigate, experimentally, how to adapt the averaging parameters such as GL and DT to gain sensitivity in frequency bands of interests, and to investigate the seismic event detection capability of DAS data under specific set up. We recorded samples of DAS raw data, over a few hours at the German Black Forest Observatory (BFO) and in Sardinia, Italy.  We studied the spectral characteristics of strain and strain rate converted from DAS raw data, to analyze the sensitivity of DAS measurements to GL and DT. The power spectral densities are compared with the strain meter recordings at BFO site as a benchmark, which is recorded using the strain-meter arrays measuring horizontal strain in three different directions independently from the DAS (For details about the DAS measurement station at BFO see Azzola et al.  EGU 2022). We concluded about the lower limit of the DAS noise level that is achievable with employing different acquisition parameters. Accordingly, we applied suitable parameters for continuous strain-rate data acquisition at another experimental site in Georgia, which is related to the DAMAST (Dams and Seismicity) project.  

During the acquisition time periods at BFO and in Georgia, the visibility of local, regional and teleseismic events on the DAS data has been investigated. At both sites, a broadband seismometer is continuously operating, and can be considered as a reference to evaluate the event detection capability of the DAS recordings taking into account the monitoring set-up, i.e. cable types,  cable coupling to the ground, directional sensitivity and acquisition parameters. In addition, at BFO the DAS seismic event detection capability is evaluated comparing with the strain-meter array. Examples of detected seismic events by DAS are discussed, in terms of achievable SNR for each frequency content and comparison with the seismometers and strain-meter array.

How to cite: Karamzadeh Toularoud, N., Azzola, J., Gaucher, E., Forbriger, T., Widmer-Schnidrig, R., Bögelspacher, F., Frietsch, M., and Rietbrock, A.: PSD analysis and seismic event detectability of Distributed Acoustic Sensing (DAS) mesurements from several monitoring sites, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8787, https://doi.org/10.5194/egusphere-egu22-8787, 2022.

EGU22-10322 | Presentations | SM2.1

Strain accumulation along a 21km long optic fibre during a seismic crisis in Iceland, 2020 

Christopher Wollin, Philippe Jousset, Thomas Reinsch, Martin Lipus, and Charlotte Krawczyk

Slow slip plays an important role in accommodating plate motion along plate boundaries throughout the world. Further understanding of the interplay between aseismic and seismic slip has gained particular attention as it is crucial for the assessment of seismic risk. A wide range of instruments and acquisition techniques exist to quantify tectonic deformation which spans multiple orders of magnitude in duration as well as spatial extend. For example, seismometers acquire dense temporal data, however are sparsely deployed, leading to spatial aliasing. As opposite, remote sensing techniques have wide aperture but rather crude temporal resolution and accuracy (mm-range). In selected areas, strain is continuously measured with laser or borehole strainmeters.
In this contribution, we investigate the distribution of permanent strain along a telecommunication optic fibre on the Reykjanes Peninsula, South West Iceland. Continuous strain-rate was recorded via DAS (Distributed Acoustic Sensing) over a period of six months during the recent unrest of the Svartsengi volcano which began in January 2020. The interrogated fibre connects the town of Gridavik with the Svartsengi geothermal power plant and was patched to a second fibre leading to the western most tip of the Reykjanes Peninsula. It is approximately between 10 and 20km west of the active volcanic area which produced abundant local seismicity as well as surface uplift and subsidence in areas crossed with the optical fiber. The fibre was installed in a trench at less than one meter depth and consists of two roughly straight segments of 7 and 14km length. Whereas the longer segment trends WSW parallel to the strike of the Mid-Atlantic Ridge at this geographic height, the shorter segment trends NEN and thus almost coincides with the maximum compressive stress axis of the region.
Inspection of the spatio-temporal strain-rate records after the occurrence of local earthquakes indicates the accumulation of compressive as well as extensive strain in short fibre sections of a few dozen meters which could correlate with local geologic features like faults or dykes. This holds for events of M~2.5 and fibre segments in epicentral distances of more than 20km. Preliminary results regarding the total deformation of the fibre as response to an individual seismic event show a distinct behaviour for differently oriented fibre segments correlating with the overall stress regime, i.e. shortening in the order of some dozen nanometers in the direction of SHmax. Unfortunately, recordings of the two largest intermediate M>=4.8 events indicate saturation of the recording system or loss of ground coupling thus preventing a meaningful interpretation of their effect on permanent surface motion. 
Perspectively, our efforts aim at investigating the feasibility of distributed optical strain-rate measurements along telecommunication infrastructure to track locally accumulated strain.

How to cite: Wollin, C., Jousset, P., Reinsch, T., Lipus, M., and Krawczyk, C.: Strain accumulation along a 21km long optic fibre during a seismic crisis in Iceland, 2020, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10322, https://doi.org/10.5194/egusphere-egu22-10322, 2022.

EGU22-10574 | Presentations | SM2.1

Innovative high resolution optical geophysical instruments at the termination of long fibers: first results from the Les Saintes optical ocean bottom seismometer, and from the Stromboli optical strainmeter 

Pascal Bernard, Guy Plantier, Philippe Ménard, Yann Hello, Guillaume Savaton, Jean-Philippe Metaxian, Maurizio Ripepe, Marie-Paule Bouin, Frederick Boudin, Romain Feron, Sébastien Deroussi, and Roberto Moretti and the optic-OBS-strain-2022 team

In June 2022, in the frame of the PREST interreg Caraïbe project, we installed an optical OBS offshore the Les Saintes archipelago (Guadeloupe, Lesser Antilles), at the termination of a 5.5 km long optic cable buried in the sea floor and landing in Terre-de-Bas island (FIBROSAINTES campaign: Antea vessel from the FOF, plow from GEOAZUR). This innovative seismometer, developped in the last decade by ESEO, is based on Fabry-Perot (FP) interferometry, tracking at high resolution (rms 30 pm) the displacement of the mobile mass of a 10 Hz, 3 component, purely mechanical geophone (no electronics nor feed-back). This optically cabled OBS is the marine version of the optical seismometer installed at the top of La Soufrière volcano of Guadeloupe, in 2019, at the termination of a 1.5 km long fiber (HIPERSIS ANR project). Both seismometers are telemetered in real-time to the Guadeloupe Observatory (IPGP/OVSG). The optical seismometer, located at a water depth of 43 m near the edge of the immersed reef, is aimed at improving the location of the swarm-like seismicity which still persists after the Les Saintes 2004, M6.3 normal fault earthquake. The considerable advantage of such a purely optical submarine sensor over commercial, electric ones is that its robustness, due to the absence of electrical component, guarantees a very low probability of failure, and thus significantly reduces the costs of maintenance. In May 2022, an optical pressiometer and an optical hydrostatic tiltmeter designed and constructed by ENS shoud be installed offshore and connected to the long fiber, next to the optical OBS.

Based on the same FP interrogator, ESEO and IPGP recently developped a high resolution fiber strainmeter, the sensing part being a 5 m long fiber, to be buried or cemented to the ground. A prototype has been installed mid-September 2021 on the Stromboli volcano, in the frame of the MONIDAS (ANR) and LOFIGH (Labex Univearth, Univ. Paris) projects. The interrogator was located in the old volcanological observatory, downslope, and the optical sensors, at 500 m altitude, were plugged at the end of a 3 km optic cable. They consist of three fibers, 5 m long each, buried 50 cm into the ground. Their different orientation allowed to retrieve the complete local strain field. The four weeks of continuous operation clearly recorded the dynamic strain from the frequent ordinary summital explosion ( several per hour), and, most importantly, the major explosion of the 6th of October (only a few per year). The records show a clear precursory signal, starting 120s before this explosion, corresponding to a transient compression, oriented in the crater azimuth, peaking at 0.9 microstrain  10 s before the explosion.

These two successfull installations of optical instruments open promising perspectives for the seismic and strain real-time monitoring in many sites, offshore, on volcanoes, and more generally in any site, natural or industrial, presenting harsh environmental conditions, where commercial, electrical sensors are difficult and/or costly to install and to maintain, or simply cannot be operated.

How to cite: Bernard, P., Plantier, G., Ménard, P., Hello, Y., Savaton, G., Metaxian, J.-P., Ripepe, M., Bouin, M.-P., Boudin, F., Feron, R., Deroussi, S., and Moretti, R. and the optic-OBS-strain-2022 team: Innovative high resolution optical geophysical instruments at the termination of long fibers: first results from the Les Saintes optical ocean bottom seismometer, and from the Stromboli optical strainmeter, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10574, https://doi.org/10.5194/egusphere-egu22-10574, 2022.

EGU22-11311 | Presentations | SM2.1

Overcoming limitations of seismic monitoring using fibre-optic distributed acoustic sensing 

Regina Maaß, Sven Schippkus, Céline Hadziioannou, Benjamin Schwarz, Charlotte Krawczyk, and Philippe Jousset

Seismic monitoring refers to the measurement of time-lapse changes of seismic wave velocities and is a frequently used technique to detect dynamic changes in the Earth‘s crust. Its applications include a broad range of topics, such as natural hazard assessment and structural health monitoring. To obtain reliable measurements, results are usually stacked over time. Thereby, temporal resolution is lost, which makes the measurement less sensitive to short-term environmental processes. Another problem is that conventional datasets often lack spatial density and velocity changes can only be attributed to large areas. Recently, distributed acoustic sensing (DAS) has gained a lot of attention as a way to achieve high spatial resolution at low cost. DAS is based on Rayleigh-scattering of photons within an optical fibre. Because measurements can be taken every few meters along the cable, the fibre is turned into a large seismic array that provides information about the Earth’s crust at unprecedented resolution.

In our study, we explore the potential of DAS for monitoring studies. Specifically, we investigate how spatial stacking of DAS traces affects the measurements of velocity variations. We use data recorded by a 21-km-long dark fibre located on Reykjanes Pensinsula, Iceland. The cable is sampled with a channel spacing of 4 meters. We analyze the energy of the oceans microseism continuously recorded between March and September 2020. At first, we stack adjacent traces on the fibre in space. We then cross correlate the stacks to obtain approximations of the Green’s functions between different DAS-channels. By measuring changes in the coda waveform of the extracted seismograms, velocity variations can be inferred. Our analysis shows that spatial stacking improves the reliability of our measurements considerably. Because of that, less temporal stacking is required and the time resolution of our measurements can be increased. In addition, the enhancement of the data quality helps resolve velocity variations in space, allowing us to observe variations propagating along the cable over time. These velocity changes are likely linked to magmatic intrusions associated with a series of repeated uplifts on the Peninsula. Our results highlight the potential of DAS for improving the localization capabilities and accuracy of seismic monitoring studies.

How to cite: Maaß, R., Schippkus, S., Hadziioannou, C., Schwarz, B., Krawczyk, C., and Jousset, P.: Overcoming limitations of seismic monitoring using fibre-optic distributed acoustic sensing, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11311, https://doi.org/10.5194/egusphere-egu22-11311, 2022.

EGU22-11508 | Presentations | SM2.1 | Highlight

Building a new type of seafloor observatory on submarine telecom fiber optic cables in Chile 

Diane Rivet, Sergio Barrientos, Rodrigo Sánchez-Olavarría, Jean-Paul Ampuero, Itzhak Lior, Jose-Antonio Bustamente Prado, and German-Alberto Villarroel Opazo

In most subduction zones, a great portion of seismicity is located offshore, away from permanent onland seismic networks. Chile is not the exception; since the upgraded seismic observation system began operating in 2013, 35% of the ~7000 earthquakes with M≥3 recorded yearly were located offshore. Most importantly, the epicenters of the largest earthquakes (M>7.5) from 2014 to 2016 were located offshore as well.

The Chilean national seismic network is mainly composed of coastal and inland stations, except for two stations located on oceanic islands, Rapa Nui (Easter Island) and Juan Fernandez archipelago. This station configuration makes it difficult to observe in sufficient detail the lower-magnitude seismicity at the nucleation points of large events. Moreover, the lack of seafloor stations limits the efficiency of earthquake early warning systems during offshore events. These challenges could be overcome by permanently instrumenting existing submarine telecom cables with Distributed Acoustic Sensing (DAS).

Thanks to GTD, a private telecommunications company that owns a 3500-km-long network of marine fiber optic cables with twelve landing points in Chile (Prat project), from Arica (~ 18⁰S) to Puerto Montt (~ 41⁰S), we conducted the POST (Submarine Earthquake Observation Project in Spanish) DAS experiment on the northern leg of the Concón landing site of the Prat cable. This experiment, one of the first to be conducted on a commercial undersea infrastructure in a very seismically active region, was carried out from October 28 to December 3, 2021. Based on the longitudinal strain-rate data measured along 150 km of cable with a spatial resolution of 4 meters and a temporal sampling of 125 Hz, we present preliminary results of analyses to assess the possibility of building a new type of permanent, real-time and distributed seafloor observatory for continuous monitoring of active faults and earthquake early warning systems.

How to cite: Rivet, D., Barrientos, S., Sánchez-Olavarría, R., Ampuero, J.-P., Lior, I., Bustamente Prado, J.-A., and Villarroel Opazo, G.-A.: Building a new type of seafloor observatory on submarine telecom fiber optic cables in Chile, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11508, https://doi.org/10.5194/egusphere-egu22-11508, 2022.

EGU22-11599 | Presentations | SM2.1

Comparing two fiber-optic sensing systems: Distributed Acoustic Sensing and Direct Transmission 

Daniel Bowden, Andreas Fichtner, Thomas Nikas, Adonis Bogris, Konstantinos Lentas, Christos Simos, Krystyna Smolinski, Iraklis Simos, and Nikolaos Melis

Distributed Acoustic Sensing (DAS) systems have gained popularity in recent years due to the dense spatial coverage of strain observations; with one fiber and one interrogator researchers can have access to thousands of strain or strain-rate observations over a region. DAS systems have a limited range, however, with usual experiments being on the order of 10’s of kilometers, owing to their reliance on weakly backscattered light. In contrast, systems that transmit light through a fiber and measure signals on the other end (or looped back) can traverse significantly longer distances (e.g., Marra et. al 2018, Zhan et. al 2021, Bogris et. al 2021), and have the added advantages of being potentially cheaper and potentially operating in parallel with active telecommunications purposes. The disadvantage of such transmission systems is that only a single measurement of strain along the entire distance is given.

During September - October 2021, we operated examples of both systems side-by-side using telecommunications fibers underneath North Athens, Greece, in collaboration with the OTE telecommunications provider. Several earthquakes were detected by both systems, and we compare observations from both. The DAS system is a Silixa iDAS Interrogator measuring strain-rate. The newly designed transmission system relies on interferometric use of microwave frequency dissemination; signals sent along the fiber and back in a closed loop are compared to what was sent to measure phase differences (Bogris et. al 2021). We find that both systems are successful in sensing earthquakes and agree remarkably well when DAS signals are integrated over the length of the cable to properly mimic the transmission observations.

The direct transmission system, however, may not be as intuitive to interpret as an integral of displacement ground motions along the fiber. We discuss both theoretical and data-driven examples of how the observed phases depend on the curvature of a given length of fiber, and describe how asymmetries in the fiber’s index of refraction play a role in producing observed signals. Such an understanding is crucial if one is to properly interpret the signals from such a system (e.g., especially very long trans-oceanic cables). Given a full theoretical framework, we also discuss a strategy for seismic tomography given such a system: with a very long fiber, the spatial sensitivity should evolve over time as seismic signals reach different sections.

How to cite: Bowden, D., Fichtner, A., Nikas, T., Bogris, A., Lentas, K., Simos, C., Smolinski, K., Simos, I., and Melis, N.: Comparing two fiber-optic sensing systems: Distributed Acoustic Sensing and Direct Transmission, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11599, https://doi.org/10.5194/egusphere-egu22-11599, 2022.

EGU22-11864 | Presentations | SM2.1

Distributed Acoustic Sensing in the Athens Metropolitan Area: Preliminary Results 

Krystyna T. Smolinski, Daniel C. Bowden, Konstantinos Lentas, Nikolaos S. Melis, Christos Simos, Adonis Bogris, Iraklis Simos, Thomas Nikas, and Andreas Fichtner

Once a niche technology, Distributed Acoustic Sensing (DAS) has gained increasing popularity over the last decade, due to its versatility and ability to capture extremely dense seismic datasets in a wide range of challenging environments. While DAS has been utilised in some particularly remote locations, such as on glaciers and volcanoes, it also holds a great deal of potential closer to home; beneath our cities. As DAS is able to be used with existing telecommunication fibres, urban areas contain huge potential networks of strain or strain-rate sensors, right beneath our feet. This data enables us to monitor the local environment, recording events such as earthquakes, as well as characterising and monitoring the shallow subsurface. DAS experiments using dark fibres are unintrusive and highly repeatable, meaning that this method is ideal for long-term site monitoring.

In collaboration with the OTE Group (the largest telecommunications company in Greece), we have collected urban DAS data beneath North-East Athens, utilising existing, in-situ telecommunication fibres. This large dataset contains a wide range of anthropogenic signals, as well as many seismic events, ranging from small, local events, to an internationally reported Magnitude 6.4 earthquake in Crete.

We conduct a preliminary analysis of the dataset, identifying and assessing the earthquake signals recorded. This will be compared with the event catalogue of the local, regional network in Athens, to determine our sensitivity to events of different magnitudes, and in a range of locations. We hope to gain an understanding of how DAS could be combined with the existing network for seismic monitoring and earthquake detection.

Moving forward, we aim to also apply ambient noise methods to this dataset in order to extract dispersion measurements, and ultimately invert for a shallow velocity model of the suburbs of Athens.

How to cite: Smolinski, K. T., Bowden, D. C., Lentas, K., Melis, N. S., Simos, C., Bogris, A., Simos, I., Nikas, T., and Fichtner, A.: Distributed Acoustic Sensing in the Athens Metropolitan Area: Preliminary Results, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11864, https://doi.org/10.5194/egusphere-egu22-11864, 2022.

EGU22-11869 | Presentations | SM2.1

Long range distributed acoustic sensing technology for subsea geophysical applications 

Erlend Rønnekleiv, Ole Henrik Waagaard, Jan Petter Morten, and Jan Kristoffer Brenne

Recent advances in range and performance of distributed acoustic sensing (DAS) enable new geophysical applications by measuring fiber strain in existing telecom cables and subsea power cables that incorporate optical fibers. We will  present new field data showing the usability of DAS for environmental and geophysical applications, focusing especially on seabed surface waves and the sub-Hz domain. These examples show that highly sensitive DAS technology can be a valuable tool within seismology and oceanography.

The sensitive range along the fiber for DAS was previously limited to about 50 km. We will demonstrate a newly developed system (named OptoDAS) that allows for launching several orders of more optical power into the fiber, and thereby significantly improving the range beyond 150 km.

This new interrogation approach allows for high degree of flexibility optimizing the interrogation parameters to optimize the noise floor, spatial and temporal resolution according to the application. The gauge length (spatial resolution) can be set from 2 to 40 m. For interrogation of 10 km fiber, we achieve a record low noise floor of 1.4 pε/√Hz with 10 m spatial resolution. For interrogation of fibers beyond 150 km, we achieve a noise floor below 50 pε/√Hz up to 100 km. Above 100 km, the noise is limited by the level of reflected optical power, and the noise increases by ~0.3-0.4 dB/km, corresponding to the dual path optical loss in the fiber.

A modern instrument control interface allows for automatic optimalization of interrogation parameters based on application parameters in a few minutes. The instrument computer provides a flexible platform for different applications. The high-capacity storage system can store recorded time-series of several weeks to support e.g., geophysical investigations where extensive post-processing is required. The computational capacity can also be used for real-time visualization and advanced signal processing, for example for event detection and direct reporting of estimated parameters.

The OptoDAS system can convert a submarine cable into a 100 km+ densely sampled array.  From the recordings on a telecom cable in the North Sea, we will show examples of propagating Rayleigh and Love acoustical modes bounded to the seafloor surface. These modes can be excited by acoustic sources on or above the seafloor, such as trawls and anchors. The dense spatial sampling allows for accurate estimates of the location of these sources. The system also allows for applications in seismology and earthquake monitoring. When attached to a cable with non-straight geometry, the measurements have substantial information to determine the location of seismic events. This will be demonstrated using field data from the North Sea telecom cable.

From recordings on a submarine cable between Norway and Denmark, we present the DAS response in the frequency range 0.1 mHz-10Hz across a cable span of 120 km. The response in this frequency range will be a combination of temperature changes, ocean swells and tides. We show that increasing the gauge length in post-processing allows for improving the sensitivity for detecting ultra-low frequency signals.

How to cite: Rønnekleiv, E., Waagaard, O. H., Morten, J. P., and Brenne, J. K.: Long range distributed acoustic sensing technology for subsea geophysical applications, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11869, https://doi.org/10.5194/egusphere-egu22-11869, 2022.

Himalayas are seismically very active regions of the world due to ongoing continent-continent collision between India and Eurasia. The Himalayas are known to have hosted deadliest earthquakes in the past century and considering the exponential growth of population in megacities of Gangetic plains, a proper seismic hazard evaluation is very critical in this region. In this regard, the present and past slip rates along the Himalayan Frontal Thrust (HFT) are very important for understanding the convergence pattern and recurrence intervals of major earthquakes. Although geodetically derived short-term convergence rates are consistence with geologically derived long-term slip rates, this correlation is based on selected studies of uplifted Holocene terraces reporting geologically derived slip rates in Central and North-West Himalayas. There is no such reporting of Geological uplift rates from Nahan Salient in NW Himalayas. We have identified uplifted and truncated quaternary terraces along HFT in Nahan Salient Northwest Himalayas through cartosat-I stereo data. We mapped and dated the uplifted terraces in order to understand the long-term convergence rates over Holocene time period. The vertical incision rates are then calculated with the help of OSL ages and height of terraces. Assuming the vertical uplift is due to repeated past earthquakes along HFT dipping at 30°, vertical uplift rates are calculated to be 2.6 mm/yr, which equates to a fault slip rate of 5.16 mm/yr and a horizontal shortening rate of 3 mm/yr. Along with that last tectonic activity along HFT is also bracketed using age of uplifted terraces and unfaulted capping units from an exposed section of HFT fault plane along river section. The OSL ages suggest that the HFT was active between 3.8±0.4Ka and 0.706±0.15Ka. Assuming that no deformation has occurred along HFT after 0.706±0.15Ka a slip deficit of 3.6 m has been accumulated which is sufficient to generate a large earthquake in the Nahan Salient NW Himalayas.

How to cite: Singh, G., Thakur, M., and Malik, J. N.: Incision and Fault slip rates along Himalayan Frontal Thrust in Nahan Salient in Northwestern Himalayas: Implications for seismic hazard assessment., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-561, https://doi.org/10.5194/egusphere-egu22-561, 2022.

EGU22-1557 | Presentations | TS4.7

Long-term coastal uplift due to non-recoverable forearc deformation during the interseismic phase of the subduction earthquake cycle 

Bar Oryan, Jean-Arthur Olive, Romain Jolivet, Lucile Bruhat, and Luca Malatesta

Simple elastic dislocation models have been widely used to describe the surface displacements associated with subduction zone earthquake cycles. To first order, these assume a portion of the plate interface is locked during the interseismic period, inducing subsidence in the offshore domain and uplift in the onshore region. In contrast, megathrust earthquakes will impart the opposite surface displacement with offshore uplift and onshore subsidence. Such a purely elastic description of the earthquake cycle implies that interseismic deformation should be entirely compensated by large megathrust earthquakes, amounting to effectively zero deformation over numerous cycles. Recent studies however propose that spatial patterns of interseismic (short-term) deformation are reflected in long-term trends of coastal uplift (Jolivet et al., 2020), as well as in the morphology of subduction margins, which is shaped over 100s of kyrs by the interaction of tectonic and surface processes (Malatesta et al., 2021). This suggests that the repetition of seemingly elastic cycles somehow leads to non-recoverable long-term deformation.

We postulate that a small increment of inelastic deformation accumulates during each interseismic phase, leading to a long-term unbalance of co-, post- and interseismic strain. To test this hypothesis, we evaluate the variations in upper plate stress imparted by down-dip gradients in megathrust locking during the interseismic period in the Chile and Cascadia subduction zones. We add these changes to the estimated background stress state of the upper plate, and assess the extent of frictional yielding within the forearc as a function of interseismic slip deficit and upper plate strength. We find that the onset of yielding in the late interseismic phase coincides with observed areas of microseismicity at these subduction margins, typically located above the downdip end of the locked zone.

We then estimate the permanent surface uplift imparted by this upper plate yielding employing a statistical approach. We model frictional yielding of the forearc as incremental slip on a population of small faults whose spatial distribution reflects the fraction of the interseismic phase duration spent at yield. We further assume that the temporal distribution of these slip follows a Gutenberg-Richter distribution of parameters consistent with the observed microseismicity. Upon summing the displacements due to each of these dislocations, we estimate the irreversible surface displacement field associated with multiple seismic cycle.  This ultimately amounts to permanent uplift concentrated above the transition from freely slipping to fully coupled megathrust, and is consistent with the geometry and rates of long-term uplift recorded in Chile. We also demonstrate how our model can explain the recently reported correlation between location of downdip locking limit and shelf break in many active margins.

How to cite: Oryan, B., Olive, J.-A., Jolivet, R., Bruhat, L., and Malatesta, L.: Long-term coastal uplift due to non-recoverable forearc deformation during the interseismic phase of the subduction earthquake cycle, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1557, https://doi.org/10.5194/egusphere-egu22-1557, 2022.

EGU22-3457 | Presentations | TS4.7

Geodetic inference on decadal afterslip following the 2011 Tohoku-oki earthquake 

Sambuddha Dhar and Jun Muto

The postseismic deformation in the aftermath of the 2011 Tohoku-oki earthquake showed a stronger surface movement in northeastern Japan (NE) with subsequent decays over time. In response to the coseismic stress perturbation, afterslip on the megathrust interface is held responsible for the short-term deformation while viscoelastic relaxation in the surrounding lithosphere largely contributes to the long-term crustal deformation (e.g., Ozawa et al. 2012, JGR). On the contrary, decade-long studies on the postseismic model implied the prevalence of viscoelastic flow during the early phase of postseismic deformation (e.g., Sun et al. 2014, Nature, Watanabe et al. 2014, GRL, Freed et al. 2017, EPSL; Muto et al. 2016, GRL). Although geodetic displacement at any GNSS station may not indicate the single domination of either viscoelastic relaxation or afterslip over the longer period after the earthquake, the densely deployed nationwide GNSS observations (GEONET) till ~2021 provides a definite opportunity to resolve the contributions of various source mechanisms and their evolution over time.

 

Time series of geodetic observations are mainly explained using a numerical simulation of the source mechanisms (e.g., Agata et al. 2019 Nat. commun.; Luo & Wang 2021, Nat. Geosci.; Muto et al. 2019, Sci. Adv.; Fukuda & Johnson 2021, JGR) or non-linear regression of a fitting function (Tobita 2016, EPS). Utilizing the lesson learnt from the postseismic model built on laboratory-derived constitutive laws, we proposed an analytical fitting function for the GNSS time-series over the NE Japan. We deploy statistical approaches to ensure its stability and robustness. Our analytical function can be used to fit and predict the postseismic displacements at GNSS stations and understand the relative contributions of source mechanisms in lesser efforts.  We conclude that the afterslip at the downdip of the main rupture zone may continue for several decades following the megathrust earthquake. The decade-long records of repeating earthquakes on the plate boundary reiterate a similar conclusion concerning the longer persistence of afterslip in the Japan subduction zone (Igarashi & Kato 2021, Commun. Earth Env.; Uchida 2019, PEPS).

 

Our results also show that viscoelastic relaxation dominates immediately following the mega-earthquake at most inland GNSS stations. This conclusion can be supported by comparing the geodetic displacements with aftershock decay patterns (Morikami & Mitsui 2020, EPS), including recently developed stress-dependent postseismic deformation models (Agata et al. 2019, Nat. Commun; Fukuda & Johnson 2021, JGR; Muto et al. 2019, Sci. Adv).  Nevertheless, the previous studies indicate a change in the dominant mechanism of the postseismic deformation after the year ~2013-2015, particularly evident in the vertical motion (Morikami & Mitsui 2020, EPS; Yamaga & Mitsui 2019, GRL). We suggest that the transient deformation of the viscoelastic mantle decayed significantly during the ~3-4 years of the postseismic period, allowing the afterslip rate to supersede. The higher uplift rate along the Pacific coast of NE Japan, even after a decade, may reflect the shift in the dominant mechanism to the afterslip, persisting at the downdip of the main rupture zone.

How to cite: Dhar, S. and Muto, J.: Geodetic inference on decadal afterslip following the 2011 Tohoku-oki earthquake, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3457, https://doi.org/10.5194/egusphere-egu22-3457, 2022.

At the end of 2020, anomalous transient surface deformation was observed by an operational GNSS network at the Noto peninsula, Japan. Although the Noto peninsula locates far from the plate boundary, seismic observations recorded that seismic swarms were accompanied with this transient deformation. Nishimura et al. (2021, presentation at the 2021 Geodetic Society of Japan) estimated that this deformation and swarms may be associated with the intrusion of water from the subducting oceanic plate. Here I performed Sentinel-1 InSAR time series analysis to obtain more detailed view of this transient displacement and to investigate the mechanism of this phenomenon.
In the analysis, at first I created interferograms from Sentinel-1 IW SLCs using ISCE2 software. Then these interferograms were used for the LiCSBAS time series analysis. Orbital and topographic fringes were modeled and removed based on precise orbit information and SRTM 1-arcsecond DEM. No atmospheric corrections were applied. I used both ascending and descending paths so that I could calculate 2.5 dimensional analysis to derive quasi-horizontal and quasi-vertical displacements.
The result of Sentinel-1 time series showed that the transient displacement seems to start since the end of 2020, which is consistent with the result from the GNSS observation. The estimated largest surface velocities became 13 mm/year in ascending and 15 mm/year in descending. The 2.5 dimensional analysis suggested that the uplift was concentrated at the eastern front of the peninsula, which is also consistent with the GNSS observation. The derived displacement fields suggested that there is an inflation source but this need to be further investigation by, for example, using elastic spherical and/or rectangular fault models.
By the presentation, I will perform the InSAR atmospheric correction and source modelling and show these results.

How to cite: Kinoshita, Y.: Transient small displacement since the end of 2020 at Noto peninsula, Japan, revealed by Sentinel-1 InSAR time series analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7145, https://doi.org/10.5194/egusphere-egu22-7145, 2022.

EGU22-7507 | Presentations | TS4.7

Slip model of the 2013 April 16 Mw 7.7 Saravan intra-slab earthquake (Makran subduction zone) derived from InSAR, GPS, and Teleseismic P-wave modeling 

Andrea Walpersdorf, Meysam Amiri, Erwan Pathier, Zahra Mousavi, Fatemeh Khorrami, and Sergey V. Samsonov

The 2013 April 16 Mw 7.7 Saravan earthquake, an intra-slab earthquake with a normal faulting mechanism at of 50 km depth, occurred in the western part of the Makran subduction zone, where the Arabian oceanic lithosphere subducts northward under Iran and Pakistan. This event was the first instrumental recorded earthquake with a magnitude larger than Mw 6 since the last century. Studying this earthquake using geodetic and seismological data brings a unique opportunity to measure surface displacement due to the earthquake and assess causative fault parameters. Furthermore, it enables us to address some problems in the Makran subduction zone including slab dip angle, depth of dip angle change.

We used interferograms generated from RADARSAT-2 Synthetic Aperture Radar (SAR) data and coseismic GPS velocity field to combine with teleseismic P-wave data to model source fault parameters. First, we apply uniform slip modeling using a Bayesian bootstrap optimization nonlinear inversion method to find causative fault parameters. We specify search grids based on the LOS displacement map and focal mechanism solutions for each fault parameter to find the best solutions. These parameters include length, width, depth, strike, dip, rake, slip, location of the fault plane, rupture nucleation point, and origin time. Based on some prior tests and seismological information of earthquake, we decreased the search area of each parameter: depth 30- 70 km, dip 40˚- 80˚, strike 200˚-250˚, length 50-120 km, width 30-50 km, rake -150˚ -80˚ slip 1-4 m and let rupture nucleation point and origin time to be wide enough implying that all possible and reasonable fault geometry and kinematics parameters can be explored. Synthetic static displacements and seismic waveforms in a layered medium were computed with the Green's functions calculated using QSSP and PSGRN/PSCMP, respectively (Wang et al., 2006; Wang et al., 2017). A Green's function store contains pre-calculated Green's functions on a grid for combinations of source depth and source-receiver surface distance. For the layered half-space medium, we used the velocity structure of the GOSH seismic station to derive the Green Functions (Sebastian et al., 2016). After 450,000 iterations, the waveform fits, subsampled surface displacements as observed, modeled, and residual maps based on the best model are resolved. The distributions and resulting confidence intervals indicate that the parameters were well constrained. The joint inversion's best result indicates that the Saravan 2013 causative fault is a North-dipping normal fault with a dip of ~ 67°. The earthquake source length and width are approximately 120 and 80 km respectively.  In the second step, we model the derived fault plane in the previous step to retrieve the distributed slip model, allowing the slip to vary across the fault plane. In this step, all the parameters assumed fixed except slip. We extend fault length and width to 150 km and 100 km to prevent unwanted slip in the corners. The slip variation along the causative fault is characterized by one significant patch at the depth between 30-65 km with a maximum magnitude of about 4 m at 42-52 km.

How to cite: Walpersdorf, A., Amiri, M., Pathier, E., Mousavi, Z., Khorrami, F., and Samsonov, S. V.: Slip model of the 2013 April 16 Mw 7.7 Saravan intra-slab earthquake (Makran subduction zone) derived from InSAR, GPS, and Teleseismic P-wave modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7507, https://doi.org/10.5194/egusphere-egu22-7507, 2022.

EGU22-7630 | Presentations | TS4.7

InSAR constraints on interseismic slip-rate of the Esfarayen fault, northeastern Iran 

Zahra Mousavi, Andrea Walpersdorf, Erwan Pathier, and Richard Walker

In the last decades, GNSS constraints and geological estimates of the fault slip rates improve the understating of the kinematics of faulting across Iran, particularly in the northeastern part of the country. Here, we complete the sparse GNSS vectors from previous reported studies around the Baghan Quchan fault zone (BQFZ) in northeastern Iran, by processing the Sentinel-1 archives covering this zone. According to tectonic and geodetic studies, the right-lateral BQFZ and the left-lateral Esfarayen fault constitute the northeastern and southern limits, respectively, of the easternmost part of the South Caspian Basin. While the BQFZ is limiting the SCB towards Eurasia, the Esfarayen fault is its border towards the Iranian microplate. We constructed 452 interferograms with 102 images from 2014.10.29 to 2019.10.27 (5 years) in descending geometry using the NSBAS package. We combined all three swaths (iw1, iw2, iw3) to cover the area of interest. The revisit time is 24 days between 2014.10.29 and 2017.02. 15, and 12 days from 2017.02.15 to 2019.10.27. To remove the hydrogeological land displacement effect (charge and discharge of aquifers), we chose the first (2014.10.29) and the last image (2019.10.27) at the same time of the year. Following the SBAS time series analysis approach, we created interferograms with short temporal (one or two months) and spatial baselines. Also, to avoid introducing any artificial signal in the mean velocity map, we created some interferograms with longer temporal baselines (maximum one year). We removed the neutral atmospheric delay using global reanalysis data provided by the European Centre for Medium-Range Weather Forecasts (ECMWF). Then, we filtered and unwrapped the generated interferograms. We applied the SBAS time series analysis on the generated interferograms to obtain displacement variations in time and a mean velocity map in the line of sight (LOS) direction of the satellites. The first noticeable point is the LOS mean velocity change across the BQFZ fault reaching up to ~1.5 mm/yr in the LOS direction, compatible with right-lateral displacement. Moreover, the mean velocity map varies significantly across the Esfarayen fault, in a sense coherent with left-lateral displacement. This velocity map points out that the NW motion of the South Caspian basin is effectively accommodated by the Esfarayen fault, while previous work based on the sparse GNSS network (Mousavi et al., 2013) suggested that the Bojnord fault further north is accommodating this NW motion. In particular, the new InSAR map indicates that the velocity vector of the permanent GNSS station ESFN used by Mousavi et al. (2013) is contaminated by subsidence motion and cannot be representative of a tectonic motion. This study brings new information for assessing seismic hazard in NE Iran with large population centers. Moreover, the retrieved mean velocity map indicates significant subsidence in Nishabour and Jajarm cities and Joveyn, Chahar Borj, Chenaran, Faruj and Ribat Jaz villages in Iran, as well as in the Yashklik city in Turkmenistan. This is the first report of subsidence occurring in Turkmenistan.

How to cite: Mousavi, Z., Walpersdorf, A., Pathier, E., and Walker, R.: InSAR constraints on interseismic slip-rate of the Esfarayen fault, northeastern Iran, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7630, https://doi.org/10.5194/egusphere-egu22-7630, 2022.

EGU22-8195 | Presentations | TS4.7

Spatial distribution of creep on a creeping thrust fault: Joint inversion using geodetic data and repeating earthquakes 

Wei Peng, Mathilde Radiguet, Erwan Pathier, and Kate Huihsuan Chen

The Chihshang fault in Taiwan serves as one of the best examples of faults with a primarily thrust component that rapidly creep at the surface (2-3 cm/yr), while it is also known to have produced magnitude 6 earthquakes. The deeper portion of this thrust fault is typically offshore, where land-based geodetic measurements are insensitive to fault slip at greater depth. The understanding of inter-seismic slip rate at depth therefore, remains elusive. Taking advantages of slip rates inferred from repeating earthquake sequences (RES) at greater depth, here we present a modified method that embeds RES derived slip rate into the neighboring fault patch for geodetic data inversion. Using the geodetic and seismological data from 2007 to 2011, we reach the higher resolution of interseismic slip rate distribution below the depth of 15 km. The inferred low coupling ratio establishes the extensive creeping area that coincides with the location of abundant repeating earthquakes and swarm events. The inferred high coupling ratio on the other hand, delineates the locked area corresponding to the co- seismic slip zone of the 2003 Mw6 Chengkung earthquake. The postseismic area however, is found to mainly overlapped with the low coupling ratio area at shallow depth (freely creeping) but not where the microseismcity, repeating and swarm events are located (partially creeping). We propose that the strongly locked area is concentrated in the middle of the fault extending from near surface to the depth of 25 km, surrounded by the creeping areas where microseismicity, repeating and swarm events are taking place. We estimate that a slip rate deficit equivalent to Mw 6.26 has accumulated annually, which may be able to generate greater than Mw 7 event over an interval of 20 years. It is thus importance, to follow up by time-dependent kinematic model in the future for better estimate of large earthquake potential in this creeping fault.

How to cite: Peng, W., Radiguet, M., Pathier, E., and Chen, K. H.: Spatial distribution of creep on a creeping thrust fault: Joint inversion using geodetic data and repeating earthquakes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8195, https://doi.org/10.5194/egusphere-egu22-8195, 2022.

Bob Elliott, Ken McCaffrey, Richard Walters (all Durham University), Dave Mackenzie (3vGeomatics), Laura Gregory (Leeds University)

Characterising near-fault deformation can improve understanding of how major co-seismic slip at depth is transferred to the surface. Deformation observed close to the fault scarp can identify where there has been shallow slip deficit, and the role of minor faults adjacent to the main faults as controlling influences in co-seismic slip distribution. However, field work and remote sensing techniques such as InSAR and GNSS are often inefficient or unreliable in characterising near-fault deformation due to exposure and data resolution issues. We use high resolution topographical models from optical satellite data from the Pleiades constellations to help identify the co-seismic deformation associated with the 30th October 2016 Norcia earthquake.  We jointly inverted a total of 11 datasets including Pleiades-derived DEM difference data, InSAR and GNSS (far-field and short baseline)) for slip at depth following the method of Okada (1985). Compared to previous models derived from geodetic datasets, we used a relatively complicated fault geometry set-up in the area covered by the Pleiades datasets. By combining the near-fault input provided by the Pleiades data with far-field data we were able to model near-surface slip as well as slip at depth with a good fit to the Pleiades data, without losing the fit to the far-field data. The results show remarkable detail of slip transfer from the main faults onto minor structures in the hanging wall of the Monte Vettore fault within the top 2 km below the surface. Slip vectors near the surface also display considerable divergence from slip vectors at depth. This research provides valuable insight into the distribution of near-fault co-seismic slip in an area of complex faulting, 

How to cite: Elliott, B.: Characterising near-fault deformation in the Apennines through the use of high-resolution Pleiades optical satellite data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8527, https://doi.org/10.5194/egusphere-egu22-8527, 2022.

Despite decades-long debate over the mechanics of low-angle normal faults dipping less than 30°, many questions about their strength, stress, and slip remain unresolved. Recent geologic and geophysical observations have confirmed that gently-dipping detachment faults can slip at such shallow dips and host moderate-to-large earthquakes. Here, we analyze the first 3D dynamic rupture models to assess how different stress and strength conditions affect rupture characteristics of low-angle normal fault earthquakes. We model observationally constrained spontaneous rupture under different loading conditions on the active Mai’iu fault in Papua New Guinea, which dips 16-24° at the surface and accommodates ~8 mm/yr of horizontal extension. We analyze four distinct fault-local stress scenarios: 1) Andersonian extension, as inferred in the hanging wall; 2) back-rotated principal stresses inferred paleopiezometrically from the exhumed footwall; 3) favorably rotated principal stresses well-aligned for low-angle normal-sense slip; and 4) Andersonian extension derived from depth-variable static fault friction decreasing towards the surface. Our modeling suggests that subcritically stressed detachment faults can host moderate earthquakes within purely Andersonian stress fields. Near-surface rupture is impeded by free-surface stress interactions and dynamic effects of the gently-dipping geometry and frictionally stable gouges of the shallowest portion of the fault. Although favorably-inclined principal stresses have been proposed for some detachments, these conditions are not necessary for seismic slip on these faults. Finally, we explore how off-fault damage and slip on steeper splay faults in the hanging wall of a detachment fault influences shallow rupture patterns and coseismic surface displacement during large earthquakes. We present a new suite of models with synthetic or antithetic splay faults dipping 45°, 60°, or 75° that incorporate off-fault plastic failure for different host rock strengths. Coseismic splay fault reactivation limits shallow slip on the detachment and localizes surface displacements outboard of the detachment trace, most strongly when synthetic shallowly-dipping splay faults are present. Our results demonstrate how integrated geophysical and geologic observations can constrain dynamic rupture model parameters to develop realistic rupture scenarios of active faults that may pose significant seismic and tsunami hazards to nearby communities.

How to cite: Biemiller, J., Gabriel, A., and Ulrich, T.: Mechanics of shallow slip in low-angle normal fault earthquakes: insight from 3D dynamic rupture models constrained by multi-timescale observations, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10556, https://doi.org/10.5194/egusphere-egu22-10556, 2022.

EGU22-10732 | Presentations | TS4.7

Shear of simulated quartz-feldspar aggregates under conditions spanning the brittle-plastic transition 

Miho Furukawa, Berend A. Verberne, Jun Muto, Miki Takahashi, and Hiroyuki Nagahama

Continental earthquakes often nucleate at the brittle-plastic transition zone in the upper crust. Since the strength of the crust reaches the maximum here, it is inferred that strain is localized, leading to seismic rupture. Fault rock deformation experiments under pressure-temperature conditions simulating the brittle-plastic transition are key to unravel the processes triggering continental earthquakes. We investigated the mechanical behavior and post-mortem microstructure of simulated quartz-feldspar gouges using a Griggs-type solid medium apparatus. The samples consist of mixtures of powdered quartz: albite = 50 : 50 (wt%), which were sheared under pressure-temperature conditions simulating depths of 7 to 30 km, realizing a geothermal gradient of 30 °C/km and a lithostatic pressure corresponding to a granitoid rock density of 2700 kg/m3. Specifically, experiments were carried out at temperatures ranging from 210 °C to 900 °C and confining pressures ranging from 185 MPa to 870 MPa. The bulk shear strain rate was sequentially stepped between ~10-3 and ~10-4 /s. After the experiments, each sample was analyzed using optical and scanning electron microscopy.

Experimental results show a clear positive dependence of the shear strength on temperature and pressure up to 720 °C and 750 MPa, suggesting the dominance of brittle deformation. On the contrary, when the condition rises to 900 °C and 870 MPa, the strength dropped by about 550 MPa compared with that of at 720 °C and 750 MPa. This may imply that the plastic deformation gradually has taken over the deformation. Microstructural observation revealed elongated grains with their long axes intersecting with the direction of a Riedel-1(R1) shear plane (i.e., similar to a S-C fabric). Some grains were reduced in size to the nanometer range. Our observations suggest that shear strain was highly concentrated within fine-grained zones, which, we speculate, may lead to catastrophic rupture. Crack distributions illuminated by image analysis indicate that the formation mechanism of crack changes with temperature and pressure. At the lower temperature (~ 240 °C) and pressure (~ 212 MPa), cracks are short and oriented to various directions. However, as the temperature and pressure increase to 300 °C and 265 MPa, they become longer and the ratios of R1- and Y- shears increase. This implies that cracks coalesce in the kinematically favored orientations for slip, making it easy to cause a rapid seismic rupture. Since such microstructural changes occur at relatively low temperatures (below 720 °C), it is expected that the structures at higher temperatures (720 °C or higher) show predominance of the plastic deformation. Our results imply that the brittle-plastic transition gradually takes place at the microscopic scale, even within the range where the bulk mechanical behavior indicates brittle deformation.

How to cite: Furukawa, M., Verberne, B. A., Muto, J., Takahashi, M., and Nagahama, H.: Shear of simulated quartz-feldspar aggregates under conditions spanning the brittle-plastic transition, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10732, https://doi.org/10.5194/egusphere-egu22-10732, 2022.

EGU22-12020 | Presentations | TS4.7 | Highlight

Source parameters and locations of the 1949 Mw7.4 Khait and 1907 Mw7.6 Karatag earthquakes: implications for how mountain ranges collide 

Ben Johnson, Galina Kulikova, Eric Bergman, Frank Krueger, Ian Pierce, James Hollingsworth, Alex Copley, Mike Kendall, and Richard Walker

The 1949 Mw7.4 Khait and 1907 Mw7.6 Karatag earthquakes are the two largest earthquakes of the last ~100 years within Tajikistan, in a zone of convergence between the Pamir and Tian Shan ranges at a rate of ~1cm/yr. The historical nature of these events means seismological and geodetic data are lacking. As such, their locations and source parameters have been very uncertain – preventing our understanding of how they fit into the tectonic model of the north-western Pamir.  

Here we present calibrated earthquake relocations for the 1949 earthquake and focal mechanisms determined from digitised seismograms for the 1949 and 1907 earthquakes. We also present a catalog of precise relocations for moderate magnitude earthquakes from 1949 to the present in vicinity of the Vakhsh Thrust. Finally, we present earthquake surface rupture mapping from the Vakhsh Valley, determined from ultra-high resolution elevation models derived from satellite stereo-imagery.  

We find that the 1949 Khait earthquake did not occur on the Vakhsh Fault, a major right-lateral fault that bounds the northern margin of the Pamir, as previously thought. Instead it occurred on an unmapped fault in the Tian Shan basement. However, 10-20m scarps observed on the south Vakhsh valley show this fault is capable of producing large earthquakes. This tells us the Pamir–Tian Shan convergence is distributed across several basement faults capable of producing large earthquakes. It also tells us that the largest earthquakes may occur on faults which may appear minor in the landscape, which has implications for seismic hazard in the region.  

How to cite: Johnson, B., Kulikova, G., Bergman, E., Krueger, F., Pierce, I., Hollingsworth, J., Copley, A., Kendall, M., and Walker, R.: Source parameters and locations of the 1949 Mw7.4 Khait and 1907 Mw7.6 Karatag earthquakes: implications for how mountain ranges collide, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12020, https://doi.org/10.5194/egusphere-egu22-12020, 2022.

EGU22-462 | Presentations | SM6.1

Hydroacoustic observations of a seismic cluster at Melville Fracture Zone along the Southwest Indian Ridge in 2016-17 

Vaibhav Vijay Ingale, Sara Bazin, and Jean-Yves Royer

Seismic clusters of volcanic and tectonic events along mid-oceanic ridges are inherent to seafloor spreading. Due to the rapid attenuation of seismic waves in the solid Earth, land-based seismic networks lack the low-level seismicity associated with such clusters. However, regional studies using autonomous underwater hydrophones overcome this difficulty due to their sensitivity to low-frequency hydroacoustic waves, known as T-waves, that travel in the SOund Fixing And Ranging (SOFAR) channel over very long distances with little attenuation. Using hydroacoustic records from the temporary OHASISBIO network and permanent stations of the CTBT Organization, we have examined a seismic cluster near the Melville Fracture Zone (FZ) at 61°E along the ultraslow spreading Southwest Indian Ridge (spreading rate: 14-15 mm/yr).

Near 61°E, 259 events were reported in the International Seismological Center (ISC) catalogue between 9th June 2016 and 25th March 2017 in the region of 3 x 3 degrees in latitude and longitude around Melville Transform. Out of them, 17 events display normal faulting mechanisms parallel to the ridge axis (Global Centroid Moment Tensor (GCMT) solutions).

In the preliminary analysis, we have detected 4273 hydroacoustic events between 9th June and 11th July 2016, vs 28 events in the ISC catalogue, so with ~150-fold increase in the event detections. These events are mostly aligned parallelly to the ridge axis near its intersection with the Melville FZ. The event median uncertainties are ~4.7 km in latitude and longitude, and ~1.4 s in origin time. Their median acoustic magnitude or Source Level (SL) is 225.26 dB.

This seismic cluster includes several highly energetic and short duration (~10 s) impulsive events, located on the slopes of seamounts near the FZ at 61.2°E. These events are interpreted as thermal explosions resulting from direct magma supplies on the seafloor. Also, most of the hydroacoustic events are clustered around the same seamounts. There is no evidence for long mainshock-aftershock sequence at the onset of this seismic cluster. These observations point to a magmatic origin for this seismic cluster with an active source located near a chain of seamounts in the vicinity of Melville FZ.

How to cite: Ingale, V. V., Bazin, S., and Royer, J.-Y.: Hydroacoustic observations of a seismic cluster at Melville Fracture Zone along the Southwest Indian Ridge in 2016-17, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-462, https://doi.org/10.5194/egusphere-egu22-462, 2022.

EGU22-1068 | Presentations | SM6.1

Injection-induced sequences give us insights about what is happening at depth during natural earthquake swarms 

Philippe Danre, Louis De Barros, and Frédéric Cappa

Natural earthquake swarms occur in various geological contexts, and are usually interpreted as driven by fluid pressure diffusion. However, little is known about their fluid-driving processes, as no direct observations of either fluid and deformation are possible at such depths. To improve our understanding of the processes involved in swarms, we develop a quantitative comparison between natural and injection-induced swarms. Fluid injections in the crust, for instance geothermal reservoir development or wastewater storage, are accompanied by a prolific seismicity, that can be related to the fluid-pressure perturbation and potentially in association with aseismic slip at depth. It is well-accepted that the released seismic moment scales with injected fluid volume, but proposed relations usually not consider the contribution of aseismic deformation. Constraining such a relation might provide information on what happens at depth during natural earthquake swarms. Indeed, based on the numerous similarities observed between natural and injection-induced swarms, we confirm that both types of sequences seem to obey the same physics. In our work, we establish a framework to relate seismic observables to the fluid volume circulating at depth. This allows us to quantify aseismic slip for all types of swarms, but also to estimate the volume of fluids circulating at depth during natural earthquake swarms. By focusing on several natural swarms, this sheds a new light on the processes driving swarms of seismicity.

How to cite: Danre, P., De Barros, L., and Cappa, F.: Injection-induced sequences give us insights about what is happening at depth during natural earthquake swarms, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1068, https://doi.org/10.5194/egusphere-egu22-1068, 2022.

EGU22-2319 | Presentations | SM6.1

Spatio-temporal distribution of seismicity in the northern Armutlu Peninsula (northwest Turkey) 

Gian Maria Bocchini, Patricia Martínez-Garzón, Alessandro Verdecchia, Rebecca M. Harrington, Marco Bohnhoff, Taylan Turkmen, and Murat Nurlu

The Armutlu Peninsula, bounded between two major sub-branches of the North Anatolian Fault (NAF) at the eastern Sea of Marmara, hosts the only onshore NAF segment along the Marmara seismic gap. It also hosts intense seismic and hydrothermal activity and documented episodes of aseismic slip. Here, we investigate the spatio-temporal distribution of seismicity in the northern Armutlu Peninsula to identify primary deformational mechanisms (i.e. seismic vs aseismic) and investigate the processes driving the seismicity. We employ multi-station matched-filter techniques to generate an enhanced seismicity catalog using up to 30 seismic stations, including regional permanent stations augmented by temporary stations from the SMARTnet network. We detect 7,677 events between 2019.01.25 and 2020.02.10, and successfully relocate 4,182 of them using double-difference methods. The enhanced seismicity catalog reveals four week-long sequences with up to ~> 200 events per day alternating in month-long periods with only < 10-20 events per day. Earthquakes primarily concentrate within a narrow region of ~80 km2 between 40.540°-40.600° N and 28.920°-29.025° E, forming linear structures striking from NW-SE to N-S at 5-12 km depth. Nearest-neighbor cluster analysis shows a gradual decrease of the ratio between swarm-like and burst-like activity, accompanied by a decrease of the background activity rates from the first to the fourth seismic sequence. Periods with predominantly swarm-like behavior and increased background activity exhibit a higher b-value. We invert focal mechanism solutions of background seismicity and obtain an extensional stress regime for the broader Armutlu Peninsula and a transtensional stress regime for the narrow, most seismically active region. Within the narrow seismically most active region the minimum compressive stress (σ3) is approximately horizontal and well defined, while the maximum (σ1) and intermediate (σ2) compressive stresses are close in magnitude and less well constrained. Moreover, in the most seismically active region, we observe that the principal stress orientations obtained from aftershocks is similar to that estimated from background seismicity. In contrast, the respective orientations of σ1 and σ2 inferred from foreshocks switch from vertical and horizontal to horizontal and vertical. Clusters of both normal faulting and strike-slip events identified through waveform based clustering analysis are optimally oriented with respect to the regional stress field, where normal faulting kinematics are predominant. We observe negligible seismic activity associated with the onshore segment of the NAF in the Marmara seismic gap. In contrast, we observe seismicity at 5-12 km depth that highlights the geometry of a major normal fault structure, the Waterfall fault, in the northern Armutlu Peninsula. The seismicity distribution and stress-field orientation suggest that the Waterfall fault exerts a primary control in the deformation of the northern Armutlu Peninsula.

How to cite: Bocchini, G. M., Martínez-Garzón, P., Verdecchia, A., Harrington, R. M., Bohnhoff, M., Turkmen, T., and Nurlu, M.: Spatio-temporal distribution of seismicity in the northern Armutlu Peninsula (northwest Turkey), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2319, https://doi.org/10.5194/egusphere-egu22-2319, 2022.

Seismic swarms at volcanic regions are important manifestations of volcanic unrest. While they are often inferred to be related to fluid or magma movements, their underlying process remains an active research topic. In particular, quantifying the proportion of seismic swarms that are related to magma movement can potentially improve their utility for eruption forecasting. To better understand the relationship between seismic swarms and magma movement, we focus on the Akutan volcano where episodic inflations have been recorded every 2-3 years since 2002. We first applied template matching on continuous seismic waveforms between 2005-2017 to improve the earthquake catalog’s magnitude of completeness. We further classified the events as long-period (LP) or regular volcano-tectonic (VT) events based on their frequency content. After waveform-based double-difference relocation, we find that the VT and LP events are concentrated above and below the shallow magma reservoir respectively. We clustered the VT and LP events based on their spatiotemporal evolution and find that most clusters are swarm-like with no clear mainshock-aftershock sequences. Based on their temporal relation to the inflation episodes, we infer that the LP swarms are related to ascending magma into the shallow reservoir, which sometimes triggers VT swarms through stress transfer.

How to cite: Song, Z. and Tan, Y. J.: Relationship between seismic swarms and episodic inflations at Akutan Volcano in Alaska, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3364, https://doi.org/10.5194/egusphere-egu22-3364, 2022.

EGU22-3468 | Presentations | SM6.1 | Highlight

A massive earthquake swarm driven by magmatic intrusion at the Bransfield Strait, Antarctica 

Simone Cesca, Monica Sugan, Łukasz Rudzinski, Sanaz Vajedian, Peter Niemz, Simon Plank, Gesa Petersen, Zhiguo Deng, Eleonora Rivalta, Alessandro Vuan, Milton Percy Plasencia Linares, Sebastian Heimann, and Torsten Dahm

A swarm of ~85,000 volcano-tectonic earthquakes started in August 2020 at the Bransfield Strait, between the South Shetland Islands and the Antarctic Peninsula. The Bransfield Basin is a unique back-arc basin, where the past active subduction slowed down dramatically ~4 Ma, leaving a small remnant of the former Phoenix plate incorporated in the Antarctic plate. Today there is no clear evidence for recent normal seafloor spreading. Continental crust is thinning to develop oceanic crust and the current extension is either attributed to the Phoenix Block subduction and rollback or to shear between the Scotia and Antarctic plates. The 2020 seismicity occurred close to the Orca submarine volcano, previously considered inactive. Geodetic data reported a transient deformation with up to ~11 cm northwestward displacement over King George Island. We use a wide variety of geophysical data and methods to reveal the complex migration of seismicity, accompanying the intrusion of 0.26-0.56 km3of magma off the Orca seamount at ~20 km depth. Deeper, clustered strike-slip earthquakes mark the magmatic intrusion at depth, while shallower normal faulting events are induced by the growth of a lateral dike, extending ~20 km NE-SW. Seismicity abruptly decreased after the largest Mw 6.0 earthquake, suggesting the magmatic dike lost pressure with the slipping of a large fault and the opening of upward paths. A seafloor eruption is likely, but not confirmed by sea surface roughness or temperature anomalies. The unrest documents episodic magmatic intrusion in the Bransfield Strait and provides unique insights into active continental rifting.

How to cite: Cesca, S., Sugan, M., Rudzinski, Ł., Vajedian, S., Niemz, P., Plank, S., Petersen, G., Deng, Z., Rivalta, E., Vuan, A., Plasencia Linares, M. P., Heimann, S., and Dahm, T.: A massive earthquake swarm driven by magmatic intrusion at the Bransfield Strait, Antarctica, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3468, https://doi.org/10.5194/egusphere-egu22-3468, 2022.

EGU22-5154 | Presentations | SM6.1

The nature of seismicity in a complex volcanic rift setting 

Miriam Christina Reiss, James Muirhead, Amani Laizer, Emmanuel Kazimoto, Cynthia Ebinger, Frederik Link, and Georg Rümpker

Deciphering the nature of seismicity in regions of active magmatic and tectonic areas is critical when examining the interplay between faulting, magmatism and magmatic fluids. Here, we present a rich seismic data set from a 15-month temporary network from the Natron basin of the East African Rift System, which provides an ideal location to study these processes owing to its recent magmatic-tectonic activity and ongoing active carbonatite volcanism at Oldoinyo Lengai. We report seismicity, seismic swarms and their fault plane solutions which we use to constrain the complex volcanic plumbing system and long-term tectonic processes.

Between March 2019 and May 2020, we locate ~10 000 earthquakes with ML -0.85 to 3.6. These are related to ongoing magmatic and volcanic activity in the region, as well as regional tectonic extension. We observe seismicity down to ~17 km depth north and south of Oldoinyo Lengai and shallow seismicity (3 - 10 km) beneath the inactive shield volcano Gelai, including two likely fluid driven swarms. The deepest seismicity (down to ~20 km) occurs above a previously imaged magma body below Naibor Soito volcanic field. These seismicity patterns reveal a detailed image of a complex volcanic plumbing system, supporting potential lateral and vertical connections between shallow- and deep-seated magmas, where fluid and melt transport to the surface is facilitated by intrusion of dikes and sills.

Focal mechanisms vary spatially and are a strong indicator for differences between magmatic and tectonic forces. T-axis trends reveal dominantly WNW-ESE extension near Gelai, while strike-slip mechanisms and a radial trend in P-axes are observed in the vicinity of Oldoinyo Lengai. These observations support local variations in the state of stress, resulting from a combination of volcanic edifice loading and magma-driven stress changes imposed on a regional extensional stress field. Our results indicate that the southern Natron basin is a segmented rift system, in which fluids preferentially percolate vertically and laterally in a region where strain transfers from a border fault to a developing magmatic rift segment.

How to cite: Reiss, M. C., Muirhead, J., Laizer, A., Kazimoto, E., Ebinger, C., Link, F., and Rümpker, G.: The nature of seismicity in a complex volcanic rift setting, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5154, https://doi.org/10.5194/egusphere-egu22-5154, 2022.

EGU22-5645 | Presentations | SM6.1

Spatiotemporal evolution of the 2020 Perachora peninsula earthquake sequence (East Corinth Rift, Greece) and its association with pore-fluid pressure diffusion 

Georgios Michas, Vasilis Kapetanidis, Ioannis Spingos, George Kaviris, and Filippos Vallianatos

In 2020, a pronounced earthquake sequence occurred at the Perachora peninsula, at the eastern edge of the active continental Corinth Rift (Greece). The sequence evolved as a swarm over the course of four months, with the largest magnitude event (Mw=3.7) occurring approximately 2 months after its initiation. The sequence was widely felt by the local population, rising public concern regarding its evolution and a possibly impending stronger and damaging event. Herein, we use seismic waveform data from the Hellenic Unified Seismic Network (HUSN) to decipher the spatiotemporal evolution of the sequence and to investigate the possible triggering mechanisms. We use a custom velocity model for the area and apply the double-difference algorithm to relocate earthquake hypocenters at the East Corinth Rift for the period January 2020 – June 2021. Although the area lacks a local dense network, the herein analysis is able to reduce the relative location uncertainties and to enhance the spatial resolution of the catalogue, providing clues on the activated structures at depth. The spatiotemporal evolution of the sequence presented distinct characteristics of earthquake migration. The Perachora earthquake swarm initiated at shallow depths at the easternmost side of the activated area and progressively migrated towards greater depths to the northwest and then west. The observed seismicity migration pattern is consistent with an expanding parabolic front of hydraulic diffusivity D=2.8 m2/s and an average velocity of 0.22 km/day, indicating pore-fluid pressure diffusion as the primary triggering mechanism. This result is further supported by the relatively high diffusion exponent of the sequence (α=0.89±0.06), which is consistent with anomalous fluid transport phenomena in heterogeneous and fractured media. Overall, the analysis and results demonstrate that the sequence was triggered by fluid overpressures. The source of fluids is likely the down-going flux of meteoric water, possibly combined with fluids of hydrothermal affinity due to the area’s proximity to the Sousaki geothermal system. The activated structures are linked with the Pisia Fault Zone, a major tectonic feature in the area that was activated during the 1981 Alkyonides earthquakes; a series of three Mw > 6 events within a period of few days, which caused severe damage and fatalities in the broader area, including Athens.          

Acknowledgements

The research project was supported by the Hellenic Foundation for Research and Innovation (H.F.R.I.) under the “2nd Call for H.F.R.I. Research Projects to support Post-Doctoral Researchers” (Project Number: 00256).

How to cite: Michas, G., Kapetanidis, V., Spingos, I., Kaviris, G., and Vallianatos, F.: Spatiotemporal evolution of the 2020 Perachora peninsula earthquake sequence (East Corinth Rift, Greece) and its association with pore-fluid pressure diffusion, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5645, https://doi.org/10.5194/egusphere-egu22-5645, 2022.

EGU22-5869 | Presentations | SM6.1

Analysis of fluid induced earthquake swarms in Northern Main Ethiopian Rift 

Martina Raggiunti, Derek Keir, Carolina Pagli, and Aude Lavayssière

An increase of fluid pressure can induce fault slip and therefore lead to the occurrence of earthquakes. The aim of our works is to investigate this phenomenon from a seismic point of view.

We analyzed the EAGLE seismic database, that includes the earthquakes that occurred in the Northern Main Ethiopian Rift (NMER) from October 2001 to February 2003, with the aim of achieving accurate earthquake locations that show subsurface fault structure and temporal behavior. The earthquakes in the database were relocated with a number different methods including double difference relative relocation following waveform cross correlation. We focus on the Fentale-Dofan magmatic segment, an area involved in the active rifting process with a widespread seismicity and with the presence of surface hydrothermal deposits that suggest ongoing hydrothermal activity. The earthquakes were first relocated with NonLinLoc using a non-linear method and the velocity model from controlled source seismology. The events relocated with NonLinLoc was divided in four distinct clusters, with three clusters in the rift and one cluster on the western border fault. Each cluster was then relocate separately with HypoDD double-difference location algorithm, including implementation of waveform cross correlation. From the earthquake magnitudes, b-values and seismic moment were also computed. Seismic data was interpreted with hydrothermal surface data obtained from automated remote mapping from Landasat 8 images.

The analysis of the temporal-spatial distribution of earthquakes shows that some of the clusters are strongly concentrated in time and in space, and therefore swarm-like. These swarms are characterized by events with similar waveforms. There is direct correlation between the increase of seismic rate in the cluster and the presence of families of similar earthquakes. The values found for the seismic moment suggest that the events are originated from activation of rift related structures. This is supported by the N to NE elongation strike of seismic clusters highlighted by the HypoDD location, in accordance with the tectonic setting of the area. The events are mostly localized in the top 15 km of the crust. The b-values calculated for the clusters are smaller than 1, with the exception for the cluster localized near Dofan volcanic complex. The hydrothermal deposits mapped by us are mainly focused in two areas: on the western side of Dofan volcanic complex, in an area intense faulted by NNE-SSW faults; and around the Fentale volcano with a circular pattern on southern side of volcanic edifice.

The no clear correlation between seismicity and mapped hydrothermal deposits suggesting that seismicity is not driven by shallow hydrothermal fluid flow. It is possible to conclude that these earthquakes have a component fluid induced, but the origin of these fluids are deeper than the fluids that feed the hydrothermal systems.

How to cite: Raggiunti, M., Keir, D., Pagli, C., and Lavayssière, A.: Analysis of fluid induced earthquake swarms in Northern Main Ethiopian Rift, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5869, https://doi.org/10.5194/egusphere-egu22-5869, 2022.

EGU22-6917 | Presentations | SM6.1

Aseismic slip and cascade triggering process of foreshocks leading to the 2021 Mw 6.1 Yangbi Earthquake 

Xiao Ge Liu, Wen Bin Xu, Zi Long He, Li Hua Fang, and Zhi Dan Chen

Understanding the nature of foreshock evolution is important for earthquake nucleation and hazard evaluation. Aseismic slip and cascade triggering processes are considered to be two end-member precursors in earthquake nucleation processes. However, to perceive the physical mechanisms of these precursors leading to the occurrence of large events is challenging. In this study, the relocated 2021 Yangbi earthquake sequences are observed to be aligned along the NW-SE direction and exhibit several evident spatial migration fronts towards the hypocenters of large events including the mainshock. An apparent static Coulomb stress increase on the mainshock hypocenter was detected, owing to the precursors. This suggests that the foreshocks are manifestations of aseismic transients that promote the cascade triggering of both the foreshocks and the eventual mainshock. The temporal depth of the brittle-ductile transition exhibit deepening, followed by shallowing during the foreshock-mainshock-aftershock sequence. By jointly inverting both InSAR and GNSS data, we observe that the mainshock ruptured on a blind vertical fault with a peak slip of 0.8 m. Our results demonstrate that the lateral crustal extrusion and lower crustal flow are probably the major driving  mechanisms of mainshock. Additionally, the potential seismic hazards on the Weixi-Weishan and Red River faults deserve further attention

How to cite: Liu, X. G., Xu, W. B., He, Z. L., Fang, L. H., and Chen, Z. D.: Aseismic slip and cascade triggering process of foreshocks leading to the 2021 Mw 6.1 Yangbi Earthquake, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6917, https://doi.org/10.5194/egusphere-egu22-6917, 2022.

EGU22-7757 | Presentations | SM6.1

Clustering and event similarity based fault characterization of post mining induced seismicity of Gardanne mine, France 

Dalija Namjesnik, Peter Niemz, Jannes Kinscher, Simone Cesca, Isabelle Contrucci, Pascal Dominique, and Hideo Aochi

In post-mining environments, seismic hazard is still not very well understood, as number of research studies remains limited. Seismicity is often considered in post-mining risk mitigation procedures as a precursory of failure initiation in rocks within the mining works leading to ground instabilities. However, flooding of the mines can also lead to perturbations of stress states and pore pressures within the rock mass leading to failure of pre-existing faults, which may have more important impact on public safety due to a potentially longer period of activity and possibly higher magnitudes of the induced seismic events depending on the fault size.  

In a former coal mine in Gardanne, France, which was abandoned in 2003 and flooded afterwards, seismicity started appearing and raising concerns since 2010, when flooding reached the center of the mining basin. The seismic activity has been occurring approximately every two years in the form of crises. Events were also felt by the local population. A sparse temporary monitoring network has been installed in 2013 in this seismically active area. Based on research results so far, seismicity originates from the reactivation of faults underlying the mining excavations and is influenced by flooding, pumping of the water, and seasonal meteorological conditions. 

We investigate the clustering behavior and multiplet occurrences within the seismic events recorded by the sparse temporary microseismic network between 2014 and 2017. Detailed cluster analyses, the spatio-temporal distribution, recurrence time patterns, and source parameters help to characterize seismically active structure(s) below the mining works. The triggering of the seismic activity in each cluster appears to be differently influenced by the hydro-meteorological conditions, with some clusters being more affected by rainfall, while other by dry period. The variations of the pumping rate strongly affect the rate of seismicity in this area as well. The analysis is complemented by incorporating a new dataset recorded by an enhanced monitoring network during 2019, which allows to follow the evolution of the cluster activity. 

How to cite: Namjesnik, D., Niemz, P., Kinscher, J., Cesca, S., Contrucci, I., Dominique, P., and Aochi, H.: Clustering and event similarity based fault characterization of post mining induced seismicity of Gardanne mine, France, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7757, https://doi.org/10.5194/egusphere-egu22-7757, 2022.

EGU22-8100 | Presentations | SM6.1

Insight into the mechanics of seismic swarms triggered by water-reservoir impoundment 

Beata Orlecka-Sikora, Grzegorz Lizurek, Łukasz Rudziński, Dorota Olszewska, and Taghi Shirzad

Water Reservoir Impoundment (WRI) can trigger swarms and strong earthquakes under favorable geological conditions. Although many studies have investigated the relationship between the pore pressure changes due to WRI and the observed seismicity, hydromechanical models that explain the observed processes are rare. We investigated the role of hydromechanical interactions in producing earthquake swarm bursts under pore pressure changes, using the Song Tranh 2 Water Reservoir Impoundment (WRI) in Vietnam as an example. Our work contributes to the investigation of the physical mechanisms responsible for earthquake swarms. We find that the seismic swarms accompanying WRI represent the shearing of a damage fault zone composed of multiple interfering surfaces. The source parameters of seismic swarms image the quasi-dynamic weakening of the fault damage zone. Fault weakening during the propagation of seismic rupture is a key process governing the earthquake rupture dynamics and energy partitioning. Quasi-dynamic weakening evolution means here that it captures histories of fault zone slip, including the seismic slip phases within this zone, and slip weakening shows a memory effect that fades with time. Based on the calculated traction evolution within the damage zones in ST2 we estimate the effective slip-weakening distance , which is a significant parameter for characterizing a fault-weakening process. The observed quasi-dynamic weakening process is fluid driven at slower migration velocity of the order of meters/day but over short duration the migration of seismicity accelerates to velocities of kms/day. We therefore conclude that the seismic swarms are driven by a combination of fluid pressurization and stress perturbation through aseismic slip induced by pore pressure changes.

This work was partially financed by National Statutory Activity of the Ministry of Education and Science of Poland No 3841/E-41/S/2021 (BOS, ŁR, TS, GL), and Polish National Science Centre grant No UMO-2017/27/B/ST10/01267 (GL), and co-financed by the European Union and the Polish European Regional Development Fund grant No POIR.04.02.00-14-A003/16 (DO)

How to cite: Orlecka-Sikora, B., Lizurek, G., Rudziński, Ł., Olszewska, D., and Shirzad, T.: Insight into the mechanics of seismic swarms triggered by water-reservoir impoundment, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8100, https://doi.org/10.5194/egusphere-egu22-8100, 2022.

EGU22-9312 | Presentations | SM6.1

Triggered Earthquakes Reveal Hydraulic Properties of the Subsurface 

Andrew Delorey, Xioafei Ma, and Ting Chen

Seismicity both at The Geysers geothermal field (northern California) and in north-central Oklahoma is heavily influenced by industrial activities related to energy production, though the mechanism in which earthquakes are induced or triggered is different. At The Geysers, much of the seismicity is linked to thermoelastic stresses caused by injecting cold water into hot rocks, while in Oklahoma the seismicity is linked to a reduction of confining stress on faults due to increasing pore pressure resulting from wastewater injections. Here we show that these contrasting conditions are also evident in tidally-triggered earthquakes. At The Geysers, earthquakes preferentially occur during maximum extensional strain, which does not occur at the same time as maximum shear strain on optimally oriented faults in the regional stress field. In Oklahoma, earthquakes preferentially occur during maximum shear strain on optimally oriented faults, rather than maximum extensional strain. The magnitude of tidal extensional strain is naturally much greater than tidal shear strain. However, in a fluid saturated environment, pore pressure responds to changes in volume, which can counteract or reduce the effect of the applied stress. The difference in behavior at these two sites is indicative of the level of coupling between applied stress and pore pressure, corresponding to unsaturated conditions at The Geysers and high pore pressure in Oklahoma.

How to cite: Delorey, A., Ma, X., and Chen, T.: Triggered Earthquakes Reveal Hydraulic Properties of the Subsurface, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9312, https://doi.org/10.5194/egusphere-egu22-9312, 2022.

Earthquake swarms are generally interpreted as resulting from the redistribution of stresses within the crust. Swarms develop in response to fluid flow and poro-thermo-elastic stresses in reservoirs, aseismic slip on major faults, or during magmatic events in volcanic areas. However, our ability to quantify stress changes at depth from the observation of earthquake swarms is still very limited.  In his seminal study (Dieterich, 1994) was able to develop a model leading to a quantitative relationship between stress and seismicity rate. This model, based on non-interacting spring-and-slider systems undergoing rate-and-state friction was successful in determining stress conditions from seismicity rate in several active areas involving both tectonic and magmatic processes. This approach nevertheless relies on very strong assumptions, one of them being that no stress redistribution occurs following an earthquake. Stress redistributions are however known to drive earthquake sequences as observed during foreshock aftershock sequences. Ignoring this contribution might lead to wrong estimations of stress conditions at depth from seismicity rate.
In order to evaluate the role of stress redistribution in earthquake swarm dynamics, I present a new physics based earthquake simulator extending Dieterich's model. It consists of a set of planar rate-and-state frictional faults distributed in a 3D homogeneous elastic medium, and loaded by a prescribed stress history. Faults can have any size and orientation. Stress redistributions are thus fully accounted for.
The model is then used to investigate the relationship between seismicity rate and stressing history under different loading conditions (constant tectonic stressing, periodic loading) and fault properties (initial stress, frictional properties, relative distance between faults). In many cases, Dieterich's theory ignoring stress transfers captures many features of the seismicity rate patterns. This is particularly true for periodic loading, which generates frequency dependent seismicity modulation: at low frequency, seismicity rate scales exponentially with the loading stress, while at higher frequencies it tracks the stressing rate. The period separating the two modulation regimes is correctly predicted by Dieterich's theory. Under constant loading, seismicity rate is also constant (as predicted by Dieterich's theory) if the sequences are analysed over long enough time series involving several seismic cycles on each fault. At a shorter time scale however, significant clustering (not predicted by Dieterich's approach) arises, in particular for compact fault distributions enhancing the stress redistributions. 
More generally, the approach presented here allows to define the mechanical conditions leading to a significant contribution of stress transfers in the development of earthquake swarms.

How to cite: Dublanchet, P.: What is the contribution of stress redistribution in earthquake swarm dynamics?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10369, https://doi.org/10.5194/egusphere-egu22-10369, 2022.

EGU22-10517 | Presentations | SM6.1

Earthquake swarms and clusters in stable continental regions: a case study from Northern Norway 

Hasbi Ash Shiddiqi, Lars Ottemöller, Felix Halpaap, and Stéphane Rondenay

Parts of northern Norway, located between the rifted Mid Norwegian margin and the Northern Scandinavian mountains, are seismically active despite being situated in a stable continental region. Previously, seismic swarms have been observed in different places along the coast, but detailed studies on the swarms could not yet be carried out due to sparse seismic networks. During the last decade, the number of seismic stations has increased significantly, allowing for a more detailed study of the seismicity. Here, we develop a machine-learning-based earthquake catalog from eleven years of continuous data (2010-2021) and combine it with the earthquake catalog from the Norwegian National Seismic Network. To improve accuracy, we perform relative earthquake relocation using differential times, and clustering analysis based on waveform cross-correlation. The relocation results reveal distinct clusters of possibly repeating events and several swarm sequences. A prominent seismic swarm occurred in the Jektvik area between 2014 – 2016 with the largest magnitude of ML 3.2. We compare the spatio-temporal distribution, b-value, seismic moment rate, and seasonal variation of each sequence. The Jetkvik swarm exhibits a diffusive pattern, which together with a low VP anomaly found by a previous tomography study suggests that fluids may play a role in the source process. We find that the possibly repeating clusters are not as diffuse in space, and mostly spread along the vertical axis. These earthquake clusters may be attributed to fault intersections, and fluids may not be a major factor in their generation. 

How to cite: Shiddiqi, H. A., Ottemöller, L., Halpaap, F., and Rondenay, S.: Earthquake swarms and clusters in stable continental regions: a case study from Northern Norway, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10517, https://doi.org/10.5194/egusphere-egu22-10517, 2022.

EGU22-11943 | Presentations | SM6.1

Spatio-temporal patterns of fluid-driven aseismic slip transients: implications to seismic swarms 

Alexis Sáez and Brice Lecampion

Seismic swarms are often interpreted to be driven by natural fluid pressurization in the Earth’s crust, when seismicity is observed to spread away from a common origin and follows approximately a square-root-of-time pattern of growth. On the other hand, a growing body of literature suggests that aseismic fault slip seems to be a frequent result of fluid injections and may trigger seismicity due to the stress transfer of quasi-statically propagating ruptures in critically stressed regions. Although in some conditions a nominal pore pressure perturbation front may evolve proportionally to the square root of time, much less is known about the temporal patterns of fluid-driven aseismic slip fronts. The latter hinders efforts to distinguish whether some seismic swarms are driven by aseismic slip episodes or not. In this contribution, we provide an extensive set of physics-based solutions that describes the evolution of fluid-driven aseismic slip fronts for a wide range of conditions in terms of in-situ stress state and fluid flow. Our solutions show that fluid-driven aseismic slip fronts may result in many different patterns of propagation, depending on the characteristics of the fluid source (e.g., constant-pressure source, constant-rate source, among others) and also if simplified 2-D or fully 3-D elasticity is considered. Other parameters such as the initial stress state and fault hydraulic properties are also relevant in the propagation of the slip fronts. Our family of solutions includes cases in which aseismic slip fronts propagate following a square-root-of-time dependence, a linear expansion with time, power laws of time with exponents lower than ½, and some other more complex evolutions. These results are based on the model of a fluid-driven frictional shear crack that propagates on a planar fault interface characterized by a constant friction coefficient and a constant permeability, embedded in an infinite linearly elastic medium with an initially uniform state of stress. Although the basic assumptions of the model are simple, it results in a significant amount of complexity in terms of possible spatio-temporal patterns of rupture propagation. Since a constant friction coefficient corresponds to a fault interface with zero fracture energy, we show by analyzing the rupture-front energy balance of fluid-driven aseismic slip transients with non-zero fracture energy, that an asymptotic regime in which the fracture energy is negligible is always ultimately reached. This regime is approached asymptotically when the rupture has propagated over a distance larger than a characteristic length-scale depending on the frictional fracture energy and the in-situ stress state. We expect our results to provide a simple means to interpret observations of seismic swarms for which fluid-driven aseismic slip transients are thought to be a relevant mechanism in the triggering of seismicity.

How to cite: Sáez, A. and Lecampion, B.: Spatio-temporal patterns of fluid-driven aseismic slip transients: implications to seismic swarms, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11943, https://doi.org/10.5194/egusphere-egu22-11943, 2022.

EGU22-13176 | Presentations | SM6.1

March 2021 Thessaly, central Greece, seismic sequence:  domino effect of a complex normal fault system 

Vincenzo Convertito, Vincenzo De Novellis, Diego Reale, Guido Maria Adinolfi, and Eugenio Sansosti

The Thessaly seismic sequence (TSS) in Central Greece, started on 3 March 2021 with a Mw 6.3 event that struck an area located about 25 km WNW of the Larissa town. In the following days, TSS was affected by other two major events: An Mw 6.0 on March 4, localized about 7 km to the northwest of the first one, and a Mw 5.6 on March 12, located 12 km further towards the northwest of the second one. A large number of smaller events have been also recorded until mid-April when the sequence decreased in frequency and magnitude. The TSS represents the largest seismic sequence affecting a continental extensional domain in Greece that has been monitored by modern geodetic techniques. Thanks to the short satellite revisit time, InSAR measurements made it possible to isolate each contribution of the three major earthquakes of the sequence, thus allowing the study of their interactions. In addition, available geological data indicate that the northern sector of Thessaly represents a large seismic gap. This may be a direct consequence of the limited size of the faults (less than 20 km) and their intrinsic capability to originate earthquakes of small-to-moderate magnitude only. TSS, which finally filled the gap, confirmed this hypothesis.

We modelled the available InSAR deformation maps to retrieve the parameters characterizing some finite dislocation sources, which were used to perform a Coulomb stress transfer in order to investigate possible faults interactions. To constrain the geometry and location of the main fault structures involved during the TSS, we considered 1853 earthquakes occurred in the area from 28 February 2021 to 26 April 2021 with magnitude ranging between 0.2 and 6.3. Our model shows that the TSS has nucleated at shallow depths (<12 km) and is related to the activation of several blind, previously unknown, faults; moreover, the seismic sequence developed in a sort of domino effect involving a complex interaction among the normal faults within the activated crustal volume. As for the temporal evolution of the sequence, the delayed triggering of the Mw 6.0 earthquake can be explained by the distribution of the events occurred earlier, which encircle the asperities that will fail in the subsequent event together with a fluid diffusion in the seismogenic volume.

Finally, we highlight the key role played by the configuration of the Thessaly Basin characterized by blind faults interconnected at depth, particularly interesting from the neotectonics point of view. The used approach can help improving our knowledge on the seismic potential of the Thessaly region and refine the associated seismic hazard.

How to cite: Convertito, V., De Novellis, V., Reale, D., Adinolfi, G. M., and Sansosti, E.: March 2021 Thessaly, central Greece, seismic sequence:  domino effect of a complex normal fault system, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13176, https://doi.org/10.5194/egusphere-egu22-13176, 2022.

TS5 – Tectonics and surface processes

EGU22-226 | Presentations | GD2.1

Exhumation signals and forcing mechanisms in the Southern Patagonian Andes (Torres del Paine and Fitz Roy plutonic complexes) 

Veleda Astarte Paiva Muller, Christian Sue, Pierre Valla, Pietro Sternai, Thibaud Simon-Labric, Joseph Martinod, Matias Ghiglione, Lukas Baumgartner, Frédéric Herman, Peter Reiners, Cécile Gautheron, Djordie Grujic, David Shuster, and Jean Braun

Late Miocene calc-alkaline intrusions in the back-arc of Southern Patagonia mark an eastward migration of the arc due to accelerated subduction velocity of the Nazca plate or slab flattening preceding active ridge subduction. Amongst these intrusions are the emblematic Torres del Paine (51°S) and Fitz Roy (49°S) plutonic complexes, crystalised at ca. 12.5 and ca. 16.5 Ma, respectively (Leuthold et al., 2012; Ramírez de Arellano et al., 2012). Both intrusions are located at the eastern boundary of the Southern Patagonian Icefield and form prominent peaks with steep slopes that are ~3 km higher in elevation than the surrounding low-relief foreland. Their exhumation has been proposed as a response to glacial erosion and associated glacial rebound since ca. 7 Ma (Fosdick et al., 2013), and/or by regional dynamic uplift between 14 and 6 Ma due to the northward migration of subducting spreading ridges (Guillaume et al., 2009). Here we present a new data set of apatite and zircon (U-Th)/He from both plutonic complexes, numerically modelled to unravel their late-Neogene to Quaternary thermal histories. Our results show three rapid cooling periods for the Fitz Roy intrusion: at ca. 9.5 Ma, at ca. 7.5 Ma, and since ca. 1 Ma. For Torres del Paine, inverse thermal modelling reveals short and rapid cooling at ca. 6.5 Ma followed by late-Quaternary final cooling. The 10 Ma cooling signal only evidenced in the northern plutonic complex (Fitz Roy) may represent an exhumation response to the northward migrating subduction of spreading ridge segments, causing localized dynamic uplift. Thus, the absence of exhumation signal before 6.5 Ma in the southern part (Torres del Paine) suggest that the spreading ridge subduction must have occurred before its 12.5 Ma emplacement. On the other hand, rapid cooling by similar magnitude in both plutonic complexes between ca. 7.5–6.5 Ma, likely reflects the onset of late-Cenozoic glaciations in Southern Patagonia. Finally, the late-stage Quaternary cooling signals differ between Torres del Paine and Fitz Roy, likely highlighting different exhumation responses (i.e. relief development vs. uniform exhumation) to mid-Pleistocene climate cooling. We thus identify and distinguish the causes of rapid exhumation periods in the Southern Patagonian Andes, and propose a first Late Miocene exhumation pulse due to subduction of spreading ridge dynamics, and two Late Cenozoic exhumation episodes due to regional climate changes that have shaped alpine landscapes in this region.

References:

Leuthold J., et al. 2012. Time resolved construction of a bimodal laccolith (Torres del Paine, Patagonia). EPSL.

Ramírez de Arellano C., et al. 2012. High precision U/Pb zircon dating of the Chaltén Plutonic Complex (Cerro Fitz Roy, Patagonia) and its relationship to arc migration in the southernmost Andes. Tectonics.

Fosdick J. C., et al. 2013. Retroarc deformation and exhumation near the end of the Andes, southern Patagonia. EPSL.

Guillaume B. 2009. Neogene uplift of central eastern Patagonia: Dynamic response to active spreading ridge subduction? Tectonics.

How to cite: Paiva Muller, V. A., Sue, C., Valla, P., Sternai, P., Simon-Labric, T., Martinod, J., Ghiglione, M., Baumgartner, L., Herman, F., Reiners, P., Gautheron, C., Grujic, D., Shuster, D., and Braun, J.: Exhumation signals and forcing mechanisms in the Southern Patagonian Andes (Torres del Paine and Fitz Roy plutonic complexes), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-226, https://doi.org/10.5194/egusphere-egu22-226, 2022.

EGU22-354 | Presentations | GD2.1 | Highlight

Constraining Neogene Mantle Dynamics of Western Mediterranean Region Encompassing Iberia by Quantitative Modeling of Basalt Geochemistry 

Chia-Yu Tien, Nicky White, John Maclennan, and Benedict Conway-Jones
Dynamic topography is the surface expression of sub-plate mantle convective processes. In recent years, there has been considerable interest in combining a wide range of geophysical, geological and geomorphic observations with a view to determining the amplitude, wavelength and depth of mantle thermal anomalies. Here, we are interested in exploring how quantitative modelling of major, trace and rare earth elements can be used to constrain the depth and degree of asthenospheric melting for a mantle peridotitic source. Our focus is on a region that encompasses the Iberian Peninsula where previous research suggests that long-wavelength topography is supported by a significant sub-plate thermal anomaly which is manifest by reduced shear-wave velocities. Stratigraphic and fluvial studies imply that this dynamic support is a Neogene phenomenon. We analyzed 48 Neogene basaltic rocks that were acquired from Iberia in September 2019 and combined these analyses with previously published datasets. Both major element thermobarometry and rare earth element inverse modelling are used to determine the asthenospheric potential temperature and lithospheric thickness. These values are compared with those estimated from calibrated shear-wave tomographic models. Our geochemical results indicate that potential temperatures and lithospheric thicknesses are 1300-1375 °C and 50-80 km, respectively. These values broadly agree with calibrated tomographic models which yield values of 1300-1360 °C and 45-70 km. We conclude that a region encompassing Iberia is dynamically supported by a combination of warm asthenosphere and thinned lithosphere.

How to cite: Tien, C.-Y., White, N., Maclennan, J., and Conway-Jones, B.: Constraining Neogene Mantle Dynamics of Western Mediterranean Region Encompassing Iberia by Quantitative Modeling of Basalt Geochemistry, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-354, https://doi.org/10.5194/egusphere-egu22-354, 2022.

EGU22-373 | Presentations | GD2.1

Dynamic Topography of the Australian Continent and its Margins 

Philippa Slay, Nicholas White, and Simon Stephenson

Mantle convection generates transient vertical motion at the surface, which is referred to as dynamic topography. The bulk of topography and bathymetry is isostatically supported by variations in the thickness and density of both the crust and the lithosphere which means that dynamic topography generated by sub-plate density anomalies needs to be isolated from these dominant isostatic signals. Australia’s isolation from plate boundaries and its rapid northwards translation suggest that long-wavelength dynamic topography is primarily controlled by the interplay between plate motion and sub-plate convection. Along the eastern seaboard of Australia, the coincidence of elevated topography, positive long-wavelength free-air gravity anomalies and Cenozoic basaltic magmatism imply that a combination of asthenospheric temperature anomalies and thinned lithosphere generate and maintain regional topography. Distributions of onshore and offshore intraplate magmatism reflect both plate motion and convective instabilities. Compilations of deep seismic reflection profiles, wide-angle surveys and receiver function analyses are used to determine crustal velocity structure across Australia. Residual (i.e. dynamic) topographic signals are isolated by isostatically correcting local crustal structure with respect to a reference column that sits at sea level. The resultant pattern of dynamic topography is consistent with residual bathymetric anomalies from oceanic lithosphere surrounding Australia. Significant positive dynamic topography occurs along the eastern seaboard and in southwest Australia (e.g. Yilgarn Craton). These signals are corroborated by independent geologic evidence for regional uplift.

How to cite: Slay, P., White, N., and Stephenson, S.: Dynamic Topography of the Australian Continent and its Margins, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-373, https://doi.org/10.5194/egusphere-egu22-373, 2022.

Lithosphere removal beneath orogenic plateaus are transient events that must often be inferred from the absence of evidence: for example, unexplained topographic uplift in the geologic record, or the absence of high-velocity mantle lithosphere. Even when foundering events do leave traces of their occurrence on the surface, the low preservation potential of such evidence leaves incomplete and ambiguous records. Distinctive features include isotopically juvenile magmatism and transient surface subsidence that form localized, internally drained hinterland basins and playas. However, basaltic volcanism and related lacustrine sediments are rarely well preserved, and this limits our ability to evaluate the role of lithosphere removal in orogenesis to only select localities. To develop a more comprehensive record of this process, and facilitate comparisons between regions with copious surface and/or geophysical evidence of lithospheric foundering with regions where the evidence is scant, whether poorly preserved or not yet recognized, we present the detrital record from young strata in internally-drained hinterland basins as a proxy for foundering-related magmatism. The detrital samples include unconsolidated to poorly consolidated lacustrine sediment of the Bidahochi paleolake from the Colorado Plateau, which is associated with the isotopically juvenile (positive epsilon Nd) Hopi Buttes Volcanic field; Oligocene siltstone from the Pamir Plateau with juvenile isotopic signature (positive epsilon Hf); and Eocene-Oligocene sandstone from several localities on the Tibetan Plateau. Integration of isotope geochemistry, trace element geochemistry, and thermochronology of detrital zircon and apatite presents a promising approach to reconstruct a continuous record of low-volume magmatism, both eroded and preserved. Ti-in-zircon thermometry, Ce-U-Ti oxybarometry, and REE proxies for depth of magmatic differentiation potentially provide a means of distinguishing zircon crystals associated with hinterland magmatism from that associated with arc magmatism. Using these datasets, we consider whether lithospheric foundering can be associated with recognizable patterns that are similar across orogens, and whether geochemical shifts in hinterland magmatism reveal first-order differences in the temporal scale of lithosphere removal in different orogens. 

How to cite: He, J. and Kapp, P.: Evaluating scant surface evidence of deep lithosphere removal: Towards a more comprehensive record, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-443, https://doi.org/10.5194/egusphere-egu22-443, 2022.

EGU22-2113 | Presentations | GD2.1

Imaging the meso-scale structure of the upper mantle beneath the southern and central Atlantic ocean 

Barbara Romanowicz, Federico Munch, Max Rudolph, and Sujoy Mukhopadhyay

Although seismic tomography has provided important constraints on the long-wavelength structure of the mantle and its planform of convection, much is yet not well understood about the dynamic interaction of tectonic plates and deep mantle circulation at intermediate wavelengths (i.e., below plate-scale). In particular, a better understanding of the seismic structure of the oceanic upper mantle could potentially help unraveling the relationships between different scales of mantle convection, hotspot volcanism, and surface observables (e.g., MORB geochemistry, gravity gradients and bathymetry). We here present a new tomographic model of the shear-wave velocity and radial anisotropy structure beneath the central and southern Atlantic ocean constructed from the inversion of surface and body waves waveforms down to 30s period. Preliminary results confirm the existence of quasi-periodically distributed low-velocity regions in the upper mantle (200–350 km depth) organized in horizontally elongated bands some of which are parallel to the direction of absolute plate motion, as previously found in a lower resolution global tomographic models SEMum2 (French et al., 2013) and SEMUCB_WM1 (French and Romanowicz, 2014). Many of these elongated structures overlie vertically elongated plumelike conduits that appear to be rooted in the lower mantle, located, when projected vertically to the surface, in the vicinity of major hotspots.  However, there is no direct vertical correspondence between the imaged plumelike conduits and hotspots locations suggesting a complex interaction between the upwelling flow and the lithosphere/asthenosphere system. We discuss possible relations of this structure with trace element geochemistry of the corresponding hotspots.

How to cite: Romanowicz, B., Munch, F., Rudolph, M., and Mukhopadhyay, S.: Imaging the meso-scale structure of the upper mantle beneath the southern and central Atlantic ocean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2113, https://doi.org/10.5194/egusphere-egu22-2113, 2022.

EGU22-3461 | Presentations | GD2.1

Widely-spaced Double Hotspot Chains due to Forked Plumes sample Lower Mantle Geochemical Structure 

Maxim Ballmer and Valerie Finlayson

Age-progressive volcanic “hotspot” chains result from the passage of a tectonic plate over a thermochemical mantle plume, thereby sampling the otherwise-inaccessible lowermost mantle. A common feature in oceanic hotspot tracks is the occurrence of two parallel volcanic chains with an average separation of ~50 km (e.g., Loa and Kea chains in Hawaii). Some other tracks (including Tristan-Gough, Shona, the Line Islands, Wake seamounts, Tuvalu and Cook-Austral) feature a 200-400 km spacing, but the origin of such widely-spaced melting zones in the mantle remains unknown. Here, we explore 3D Cartesian geodynamic models of thermochemical plume ascent through the upper mantle. We explore various distributions of intrinsically-dense eclogitic material across the plume stem. For a wide range of eclogite distributions, the plume pools in the depth range of 300~410 km, where the excess density of eclogite is greater than above and below, as also predicted by Ballmer et al., EPSL 2013. This “Deep Eclogitic Pool” then splits up into two lobes that feed two separate shallow plumelets, particularly at high eclogite contents in the center of the underlying plume stem. The two plumelets feed two separate melting zones at the base of the lithosphere, which are elongated in the direction of plate motion due to interaction with small-scale convection. This “forked plume” morphology can account for hotspot chains with two widely-spaced (250~400 km) tracks and with long-lived (>5 My) coeval activity along each track. Forked plumes may also provide an ideal opportunity to study geochemical zonation of the lower-mantle plume stem, as each plumelet ultimately samples the opposite side of a deep plume conduit that potentially preserves spatial heterogeneity from the lowermost mantle. We compare this model to geochemical asymmetry evident along the Wake, Tuvalu and Cook-Austral double-chain segments, which make up the extensive (>100 Ma) Rurutu-Arago hotspot track. The preservation of a long-lived NE-SW geochemical asymmetry along the Rurutu-Arago double chain indicates a deep origin, likely from the southern boundary of the Pacific large low shear-velocity province. Our findings highlight the potential of the hotspot geochemical record to map lower-mantle structure over space and time, complementing the seismic-tomography snapshot.

How to cite: Ballmer, M. and Finlayson, V.: Widely-spaced Double Hotspot Chains due to Forked Plumes sample Lower Mantle Geochemical Structure, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3461, https://doi.org/10.5194/egusphere-egu22-3461, 2022.

EGU22-3756 | Presentations | GD2.1 | Highlight

Large-scale drainage disequilibrium in central Australia 

Gregory Ruetenik, John Jansen, Mike Sandiford, and Robert Moucha

It has been hypothesized that Australia is experiencing long-wavelength uplift and subsidence in response to intraplate stresses and/or dynamic topography (e.g. Beekman et al., 1997; Czarnota et al., 2013). In central Australia, intraplate stresses are of particular interest due to the presence of several enigmatically long-lived (500+ Myr) Bouguer anomalies of magnitude + 150 mgal. Additionally, a recent study by Jansen et al. (2022) showed that the Finke river, which drains away from a large gravity high, is actively responding to cyclic changes in uplift. Here, transient uplift and subsidence of up to ~150 m may be driven by the the flexural response to variable in-plane stresses in the presence of large loads embedded within the lithosphere.  The in-plane stress changes may be associated with shear at the base of the lithosphere and therefore inherently linked to plate velocity and mantle dynamics.
     Here, we explore mechanisms of uplift in central Australia and investigate their signatures within the geomorphic record through numerical modeling and χ analysis. We observe strong χ variations across drainage divides associated with gravity anomalies, which we link to episodic transitions from exorheic to endorheic drainage during periods of uplift and subsidence.  Landscape evolution models that incorporate flexural uplift in response to time-transient variations in horizontal stresses suggest that depositional patterns, spatial χ variations, and river profiles can be explained by this uplift mechanism.  In a more general sense, these results demonstrate that the cyclic loss and gain of drainage area during periods of endorheism and exorheism can result in drastic, sudden changes in χ which correspond to waxing and waning of basinal areas.

How to cite: Ruetenik, G., Jansen, J., Sandiford, M., and Moucha, R.: Large-scale drainage disequilibrium in central Australia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3756, https://doi.org/10.5194/egusphere-egu22-3756, 2022.

EGU22-5259 | Presentations | GD2.1

Plume conduits rooted at the core-mantle boundary beneath the Réunion hotspot 

Mathurin Dongmo Wamba, Barbara Romanowicz, Jean-Paul Montagner, and Frederik Simons

Mid-plate volcanoes are well known as hotspots. They represent the surface signature of mantle plumes, nevertheless their origin and their role in geodynamics are still a challenge in the Earth sciences. Even though plate tectonics and mantle plumes were discovered at the same time, the latter cannot be explained by the former. Plumes’ birth, life and death play a fundamental role on the evolution of life on Earth and on plate-tectonic reorganization. La Réunion hotspot is known as one of the largest on the Earth, that created the Deccan volcanic traps in India (almost 2 million km2) and the death of more than 90% of life on the Earth including dinosaurs ~65Ma ago. So far the origin of the mantle plumes and their role in geodynamics are still unclear in Earth sciences. In that respect, we use the dataset from the French-German RHUM-RUM experiment around La Réunion hotspot (2012-2013), from IRIS data center and FDSN to extensively investigate the deep structure of the plume along its complete track from its birth to its present stage, as well as from the upper mantle to the lowermost mantle. Several shear-wave anomalies are resolved underneath Indian Ocean and the upper mantle beneath this region is fed by mantle plume rising from the core-mantle boundary. The lower mantle thermochemical dome associated to the South-African Large Low-Shear Velocity Province (LLSVP) is found to be composed of several conduits. Plume branches are highlighted at ~900 km depth. Thermal instability and thermochemical heterogeneities in the D" layer are likely the principal reasons of the plumes birth at the core-mantle boundary, and therefore an indicator of long-life of the Réunion hotspot.

How to cite: Dongmo Wamba, M., Romanowicz, B., Montagner, J.-P., and Simons, F.: Plume conduits rooted at the core-mantle boundary beneath the Réunion hotspot, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5259, https://doi.org/10.5194/egusphere-egu22-5259, 2022.

EGU22-5561 | Presentations | GD2.1

Investigating the effects of plate-driving forces on observed surface deformation using global mantle flow models 

Arushi Saxena, Juliane Dannberg, and Rene Gassmoeller

Geodynamic models based on seismic tomography have been utilized to understand a wide range of physical processes in the Earth's mantle ranging from lithospheric stress states to plate-mantle interactions. However, the influence of various model components and the associated physical properties of the mantle on the observed surface deformation is still an open question and requires further research. In this study, we develop global mantle flow models based on high-resolution seismic tomography to quantify the relative importance of the plate driving and resisting forces on the surface motions. Our models include temperature and density variations based on seismic tomography, lithospheric structure, and the observed locations of subducted slabs, using the geodynamics software ASPECT. We use a diffusion/dislocation creep rheology with different parameters for the major mantle phases. To facilitate plate-like deformation, we prescribe weak plate boundaries at the locations given by global fault databases. We resolve the resulting strong viscosity variations using adaptive mesh refinement such that our global models have a minimum resolution of <10 km in the lithosphere. We analyze the influence of slab viscosity, plate boundary friction, asthenospheric viscosity, and plate boundary geometry on reproducing the observed GPS surface velocities. Our parameter study identifies model configurations that have up to 85% directional correlation and a global velocity mean within 10% difference with the observed surface motions. Our results also suggest that the modeled velocities are very sensitive to the plate boundary friction, particularly to variations in viscosity, dip angles, and the plate boundary geometry, i.e., open vs closed boundaries, or localized vs. diffused deformation zones. These models show the relative influence of plate-driving forces on the surface motions in general, and in particular the importance of using accurate models of plate boundary friction for reproducing observed plate motions. In addition, they can be used as a starting point to separate the influences of lithospheric structure and mantle convection on surface observables like strain rate, stress field, and topography.

How to cite: Saxena, A., Dannberg, J., and Gassmoeller, R.: Investigating the effects of plate-driving forces on observed surface deformation using global mantle flow models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5561, https://doi.org/10.5194/egusphere-egu22-5561, 2022.

EGU22-5992 | Presentations | GD2.1 | Highlight

Mantle dynamics and intraplate orogeny: The Atlas of Morocco 

Riccardo Lanari, Claudio Faccenna, Claudio Natali, Ebru Sengul, Giuditta Fellin, Thorsten Becker, Oguz Gogus, Nasser Youbi, and Sandro Conticelli

Most orogenic belts are close to convergent plate margins. However, some orogens are formed far away from plate boundaries, as a result of compressional stress propagating within plates, basal loading, or a combination of thereof. We focus on the Atlas of Morocco, which is such an intraplate orogeny and shows evidence of mantle driven uplift, and plume-related volcanism. How these processes interact each other is still poorly constrained and it provides clues about intraplate stress propagation, strain localization, and lithospheric weakening due to mantle dynamics. 

We present three sets of observations constructed by integrating previous data with new analyses. Crustal and thermal evolution constraints are combined with new analyses of topographic evolution and petrological and geochemical data from the Anti-Atlas volcanic fields. Our findings reveal that: i) crustal deformation and exhumation started during middle/late Miocene, contemporaneous with the onset of volcanism; ii) volcanism has an anorogenic signature with a deep source; iii) a dynamic deep mantle source supports the high topography. Lastly, we conducted simple numerical tests to investigate the connections between mantle dynamics and crustal deformation. This leads us to propose a model where mantle upwelling and related volcanism weaken the lithosphere and favor the localization of crustal shortening along pre-existing structures due to plate convergence.

How to cite: Lanari, R., Faccenna, C., Natali, C., Sengul, E., Fellin, G., Becker, T., Gogus, O., Youbi, N., and Conticelli, S.: Mantle dynamics and intraplate orogeny: The Atlas of Morocco, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5992, https://doi.org/10.5194/egusphere-egu22-5992, 2022.

EGU22-6571 | Presentations | GD2.1 | Highlight

Parallel volcanic chains generated by plume-slab interaction 

Ben Mather, Maria Seton, Simon Williams, Joanne Whittaker, Rebecca Carey, Maëlis Arnould, Nicolas Coltice, Angus Rogers, Saskia Ruttor, and Oliver Nebel

Deep mantle plumes are buoyant upwellings rising from the Earth’s core-mantle boundary to its surface, and describing most hotspot chains. Mechanisms to explain dual chains of hotspot volcanoes for the Hawaiian-Emperor and Yellowstone chains fail to explain the geochemical similarity and large distances between contemporaneous volcanoes of the Tasmantid and Lord Howe chains in the SW Pacific. Using numerical models of mantle convection, we demonstrate how slab-plume interaction can lead to sustained plume branching over a period of >40 million years to produce parallel volcanic chains that track plate motion. We propose a three-part model: first, slabs stagnate in the upper mantle, explaining fast upper mantle P-wave velocity anomalies; second, deflection of a plume conduit by a stagnating slab splits it into two branches 650-900 km apart, aligning to the orientation of the trench axis; third, plume branches heat the stagnating slab causing partial melting and release of volatiles which percolate to the surface forming two contemporaneous volcanic chains with slab-influenced EM1 signatures. Our results highlight the critical role of long-lived subduction on the evolution and behaviour of intraplate volcanism.

How to cite: Mather, B., Seton, M., Williams, S., Whittaker, J., Carey, R., Arnould, M., Coltice, N., Rogers, A., Ruttor, S., and Nebel, O.: Parallel volcanic chains generated by plume-slab interaction, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6571, https://doi.org/10.5194/egusphere-egu22-6571, 2022.

EGU22-9038 | Presentations | GD2.1

Quaternary magmatism above a slab tear, Northern Andes of Colombia 

Camilo Conde-Carvajal, Andreas Kammer, Michael Avila-Paez, Sofia Cubillos, Alejandro Piraquive, and Albrecht von Quadt

The north Andean block evidences by its shallow to intermediate seismicity a juxtaposition of a southern, relatively steeply dipping slab segment with a correlating volcanic arc and a northern flat slab domain, where a margin-parallel volcanic arc became extinct since the Late Miocene. The clear-cut offset of the seismic pattern suggests the presence of a slab tear, which has its correlative morphological expression by a distinct lineament in the Cauca Valley and separates, within the Eastern Cordillera of Colombia, a southern narrow antiformal cordilleran tract from a northern composite belt with an axial depression that constitutes the High Plain of Bogotá. Faults are consistently blind and associated with tight, basement-cored folds with inverted limbs at the mountain front and distinct domes separated by marginal synclines. These structures belong to a young deformation phase as they were superposed on older cylindrical fold trains. Their ductile deformation style may be associated with a thermal anomaly as evidenced by abnormally high Ro data. In order to assess the age of this folding we extracted zircons from a rhyolitic dike that straddles a marginal syncline of a major dome. U-Pb age data indicate a recycling of these crystals from a Neoproterozoic volcanoclastic sequence that composes the basement of this marginal part of the Cordillera. Euhedral overgrowths yield, however, Quaternary ages that we tentatively associate to the advance of the outer bend of the flat slab to its present position.

How to cite: Conde-Carvajal, C., Kammer, A., Avila-Paez, M., Cubillos, S., Piraquive, A., and von Quadt, A.: Quaternary magmatism above a slab tear, Northern Andes of Colombia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9038, https://doi.org/10.5194/egusphere-egu22-9038, 2022.

EGU22-9199 | Presentations | GD2.1

Plume-Fracture Zone interactions in the NE Atlantic 

Lea Beloša, Carmen Gaina, Sara Callegaro, Adriano Mazzini, Christine Meyzen, Stephane Polteau, and Michael Bizimis

Typically, the change in lithospheric thickness associated with fracture zones relates directly to the vigor of secondary convection or mantle flow patterns. Therefore, one might expect that mantle flow considerably boosted by the presence of a mantle plume would easily overcome the lithospheric steps created at fracture zone locations. However, to date, there are no studies to verify this assumption. Numerical models based on an example from the SW Indian Ridge suggest that the axial flow driven by a plume (the Marion plume) is indeed likely to be curtailed by the long-offset fracture zones1.

We have investigated the interactions between the Jan Mayen fracture zone and Iceland mantle plume in the NE Atlantic by considering (a) the lithospheric and asthenospheric regional configuration and (b) the geochemistry of rocks produced by submarine volcanism.

Several global lithospheric models indicate a thinning of the lithosphere on both sides of the Jan Mayen Fracture transform, despite the difference in age of the two adjacent oceanic basins. However, the tomographic models indicate a gap in the asthenospheric flow at the lithosphere-asthenosphere depth under Jan Mayen transform fault, and only a narrow northward channel of this flow is visible under the westernmost part of the fracture zone.

Vesteris seamount is an alkaline seamount placed in the central part of the Greenland Basin, located ca. 480 km west from slow-spreading Mohn's ridge and ca. 250 km north from the Jan Mayen Fracture Zone. Vesteris is a solitary volcanic center far away from an active ridge regime with an eruptive age ranging from 650 – 10 ka 2. Here we report new results from geochemical analysis of several samples dredged during the East Greenland Sampling campaign EGS-2012 from the flanks of Vesteris. Whole-rock major and trace elements, together with isotopes and olivine phenocryst mineral data, are used to decipher the source of volcanism at Vesteris Seamount.

The Sr-Nd-Pb isotopic signatures indicate that Vesteris volcanism is unrelated to the Iceland mantle plume. Low NiO concentrations in highly forsteritic olivines from Vesteris alkali basalt suggest that the source was dominantly peridotitic. Rare Earth Elements profiles indicate very low degrees of partial melting of a deep mantle source in the presence of residual garnet.

Vesteris seamount was formed in a location of a relatively steep gradient of the lithospheric-asthenospheric boundary and close to the northward mantle flow that is carving the Greenland thick lithosphere. The results suggest that the Iceland mantle flow may not have crossed the Jan Mayen Transform Fault; instead, the seamount tapped into a mantle reservoir in the Greenland Basin that preserved the complex history of the Greenland craton and adjacent terranes.   REFS. (1) Georgen and Lin, 2003, Plume-transform interactions at ultra-slow spreading ridges: Implications for the SW Indian Ridge, G-cubed, doi:10.1029/2003GC000542; (2) Mertz & Renne, 1995, Quaternary multi-stage alkaline volcanism at Vesteris Seamount (Norwegian—Greenland Sea): evidence from laser step heating 40Ar/39Ar experiments, Journal of Geodynamics, doi:10.1016/0264-3707(94)E0001-B.

How to cite: Beloša, L., Gaina, C., Callegaro, S., Mazzini, A., Meyzen, C., Polteau, S., and Bizimis, M.: Plume-Fracture Zone interactions in the NE Atlantic, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9199, https://doi.org/10.5194/egusphere-egu22-9199, 2022.

EGU22-12422 | Presentations | GD2.1

Plume push force: a relevant driver of plate tectonics that can be constrained by horizontal and vertical plate motions 

Ingo Stotz, Berta Vilacís, Jorge N. Hayek, Hans-Peter Bunge, and Anke M. Friedrich

Earth's surface moves in response to a combination of tectonic forces from the thermally convective mantle and plate boundary forces. Plate motion changes are increasingly well documented in the geologic record and they hold important constraints. However, the underlying forces that initiate such plate motion changes remain poorly understood. I have developed a novel 3-D spherical numerical scheme of mantle and lithosphere dynamics, aiming to exploit information of past plate motion changes in quantitative terms. In order to validate the models and single out those most representative of the recent tectonic evolution of Earth, model results are compared to global plate kinematic reconstructions. Additionally, over the past years a pressure driven, so-called Poiseuille flow, model for upper mantle flux in the asthenosphere has gained increasing geodynamic attention–for a number of fluid dynamic arguments. This elegantly simple model makes a powerful testable prediction: Plate motion changes should coincide with regional scale mantle convection induced elevation changes (i.e., dynamic topography). For this the histories of large scale vertical lithosphere motion recorded in the sedimentary record holds important information.

Here, I will present analytical results that help to better understand driving and resisting forces of plate tectonics – in particular the plume push force. Moreover, numerical results indicate that mantle convection plays an active role in driving plate motions through pressure driven upper mantle flow. Altogether, theoretical and observational constrains provide powerful insights for geodynamic forward and inverse models of past mantle convection.

How to cite: Stotz, I., Vilacís, B., Hayek, J. N., Bunge, H.-P., and Friedrich, A. M.: Plume push force: a relevant driver of plate tectonics that can be constrained by horizontal and vertical plate motions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12422, https://doi.org/10.5194/egusphere-egu22-12422, 2022.

EGU22-13092 | Presentations | GD2.1

Dynamic topographic observations of Antarctica and its fringing oceanic basins 

Aisling Dunn, Nicky White, Megan Holdt, and Robert Larter

Constraining the dynamic topography of Antarctica and its surrounding seas is required in order to gauge the pattern of mantle convection beneath this continent. However, such studies are limited by this continent’s geographical remoteness, by the lack of bedrock exposure and by extensive glaciation. Oceanic residual depth measurements provide a well-established proxy for offshore dynamic topography. Here, over 400 seismic reflection profiles have been interpreted to calculate residual depth measurements throughout the oceans that surround Antarctica. These measurements have been carefully corrected for sedimentary loading and, where possible, for crustal thickness variations. When combined with previous global compilations, these new residual depths significantly improve spatial resolution across the region, providing excellent constraints on dynamic topographic basins and swells. In the continental realm, an improved understanding of dynamic topography will help to quantify temporal and spatial variations in ice sheet stability. Volcanism and slow shear wave velocity anomalies beneath the continent indicate dynamic support.  By mapping offshore dynamic topography to a higher resolution, greater context is provided for future onshore studies.

How to cite: Dunn, A., White, N., Holdt, M., and Larter, R.: Dynamic topographic observations of Antarctica and its fringing oceanic basins, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13092, https://doi.org/10.5194/egusphere-egu22-13092, 2022.

EGU22-862 | Presentations | GM9.1 | Highlight

How the co-evolution of major mountain ranges affects global climate 

Sebastian G. Mutz and Todd A. Ehlers

The topographic formation of large mountains and plateaus significantly impacts regional and global climate. Previous studies demonstrated that major mountain ranges can explain important aspects of synoptic scale climate dynamics and notable features of the climate system, such as the position of the intertropical convergence zone. Quantifying the synergistic climatic effects of the coeval evolution of major mountain ranges fosters a deeper understanding of climate and Earth system dynamics. Furthermore, it helps estimate where (and by how much) a regional climate signal recorded in a geological archive is affected by topographic changes in distant, off-site orogens. In this study, we use ECHAM5-wiso General Circulation Model (GCM) simulations to explore the synergistic global effects of systematically co-varying the height of the Andean and Himalaya-Tibet Plateaus. The simulations are conducted with different topographic evolution scenarios for these orogens, while environmental boundary conditions, such as global ice cover and greenhouse gas concentrations, are kept constant. More specifically, the topographies of the orogens are incrementally reduced by 25% of their current height. This results in 5 topographic scenarios for the Himalaya-Tibet by setting its elevation to 100%, 75%, 50%, 25% and 0% of current values. These are nested in the analogous 5 topographic scenarios for the Andes, resulting in a total of 25 scenarios and GCM simulations. We then conduct an empirical orthogonal functions (EOF) analysis on the pressure fields produced by each of the simulations to track changes in quasi stable pressure systems. Furthermore, we track changes in cross-equatorial atmospheric transport and synoptic scale atmospheric flow. While most of the regional impacts of evolving topographies can be explained by atmospheric lapse rates and physical air flow disruption, global impacts can be explained by changes in surface heat distribution and pressure centres affecting synoptic scale atmospheric flow. We also find that the height of Himalaya-Tibet modifies the impact of Andean topography on northern hemisphere climate, highlighting interhemisphere climate teleconnections between the two orogens. Our results suggest that robust interpretations of climate signals recorded in geological archives in many regions on Earth are only possible when the global climatic effects of the topography of distant, off-site orogens are considered.

How to cite: Mutz, S. G. and Ehlers, T. A.: How the co-evolution of major mountain ranges affects global climate, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-862, https://doi.org/10.5194/egusphere-egu22-862, 2022.

EGU22-1311 | Presentations | GM9.1

Landscape response to the linkage of two normal faults 

Chuanqi He, Ci-Jian Yang, Gang Rao, Duna C. Roda-Boluda, Xiaoping Yuan, Rong Yang, Lin Gao, and Li Zhang

Normal fault linkage has significant impacts on uplift patterns and erosional processes in extensional regions. However, geomorphic process-based constraints on landscape response to normal fault linkage are still scarce. Here, we use landscape evolution models to examine how a landscape responds to the linkage of two normal faults. The results demonstrate that topography dynamically responds to the changes in uplift patterns that accompany fault linkage. Specifically, our results indicate that after fault linkage, (1) the steepest topography and the highest erosion rate shift from the center of each fault segment to the linkage zone; and (2) the main drainage divide evolves from an M-shape to a bow shape. We apply these findings to the Langshan Mountains in northern China, and suggest that the two piedmont fault segments have linked and that a high geohazard risk exists near the linkage zone, where the steep, transient topography is experiencing intense erosion.

How to cite: He, C., Yang, C.-J., Rao, G., Roda-Boluda, D. C., Yuan, X., Yang, R., Gao, L., and Zhang, L.: Landscape response to the linkage of two normal faults, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1311, https://doi.org/10.5194/egusphere-egu22-1311, 2022.

EGU22-1508 | Presentations | GM9.1

Recent deformation in the frontal Jura fold-and-thrust belt from a deep-seated thrust fault: evidence from Late Quaternary fluvial terraces 

Ana Lorena Abila, Vincenzo Picotti, Christoph Schmidt, and Georgina King

The Jura Mountains represent the outermost deformation of the ongoing Alpine orogen (Laubscher, 1972; Madritsch et al., 2010a). While previous studies have focused on nearby units (e.g. Upper Rhine Graben, Bresse Graben, Plateau Jura) to understand ongoing deformation, Late Quaternary to present deformation is still poorly constrained in the outermost edge of the Jura fold-and-thrust belt – the Besançon Zone – despite previously reported Quaternary uplifted fluvial terraces (Campy, 1984; Madritsch et al., 2010a-b) and recorded seismic activity, notably the 2004 Rigney ML 4.8 earthquake near the town of Besançon.

This study aims to understand the active tectonic deformation in the area through mapping of geologic units and uplifted terraces along the Doubs River (Eastern France), carving the Besançon Zone from the northeast (Clerval) to the southwest (Besançon), and supported by luminescence dates from fluvial deposits. Multiple, truncated ridges lie parallel to the river, composed of anticlines of Mesozoic units bounded by northeast-southwest trending thrust faults, the northernmost of which is the Avant-Monts Fault (Madritsch et al., 2008; 2010a-b). On the slopes of these ridges, a flight of three fluvial terraces was mapped throughout the area, the lower two of which show uniformly-uplifted straths (1 m and 5 m respectively) above the riverbed, suggesting regional, large-wavelength recent tectonic deformation. Topographic and regional geologic sections show a long-wavelength anticline centered in the Besançon Zone. These observables, together with earthquake records, point towards the Avant-Monts Fault as the responsible thrust fault, continuing with depth and possibly being rooted in the Alpine orogen (Madritsch et al., 2008). Luminescence dating of an exceptional outcrop of terrace fill yielded an age of ~35 ka, thus an average large-wavelength uplift of 0.14 mm/yr. With this information, interpolation between terraces suggests ages of 7 ka and 140 ka for the higher and lower terraces.

These results show that the frontal Jura fold-and-thrust belt has been dominated by regional uplift from a deep-seated, slow slip thrust fault since the late Quaternary, which is accommodating the present-day shortening in the Jura Mountains from the ongoing Alpine collision.

References

Campy, M. (1984) Signification dynamique et climatique des formations et terrasses fluviatiles dans un environnement de moyenne montagne. Bulletin de l’Association francaise pour l’Etude du Quaternaire 1, 87–92.

Laubscher, H. (1972) Some overall aspects of Jura dynamics. Am J Sci 272, 293–304.

Madritsch, H., Schmid, S. & Fabbri, O. (2008). Interactions between thin- and thick-skinned tectonics at the northwestern front of the Jura fold-and-thrust belt (Eastern France). Tectonics 27. 10.1029/2008TC002282.

Madritsch, H., Preusser, F., Fabbri, O., Bichet, V., Schlunegger, F., & Schmid, S. (2010a). Late Quaternary folding in the Jura Mountains: Evidence from syn-erosional deformation of fluvial meanders. Terra Nova 22, 147-154. 10.1111/j.1365-3121.2010.00928.x.

Madritsch, H., Fabbri, O., Hagedorn, EM. et al. (2010b). Feedback between erosion and active deformation: geomorphic constraints from the frontal Jura fold-and-thrust belt (eastern France). Int J Earth Sci (Geol Rundsch) 99, 103–122. https://doi.org/10.1007/s00531-009-0468-7

How to cite: Abila, A. L., Picotti, V., Schmidt, C., and King, G.: Recent deformation in the frontal Jura fold-and-thrust belt from a deep-seated thrust fault: evidence from Late Quaternary fluvial terraces, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1508, https://doi.org/10.5194/egusphere-egu22-1508, 2022.

EGU22-1788 | Presentations | GM9.1

Timing of incision of the western margin of the Colorado Plateau, new thermochronological data from Zion Canyon 

Audrey Margirier, Stuart Thomson, and Peter Reiners

The Colorado Plateau is a typical continental orogenic plateau characterized by a low-relief surface at high elevation that has been incised by the Colorado River system, forming outstanding canyons including the Grand Canyon and Zion Canyon. Although canyons are key features of ecosystems and water resources across the Colorado Plateau and form some of the most dramatic landscapes on Earth, the chronology of plateau uplift, subsequent canyon incision, and the controlling processes remain debated. The relative importance of mantle processes, tectonics, pre-existing geological structures, river drainage evolution, and climate remains controversial. Most studies addressing the timing of canyon incision and landscape evolution across the Colorado Plateau have focused on the Grand Canyon which shows the most spectacular incision with more than 1500 m of relief. Two end-member models of the Grand Canyon incision have been proposed: a 80-60 Ma incision or a 6-5 Ma incision. These models have important implications for processes driving Colorado Plateau uplift and incision, and for feedbacks on regional climate. However, studies quantifying the timing of canyon incision and surface uplift are lacking in other areas of the plateau. We used apatite fission-track and (U-Th-Sm)/He analysis to infer the incision history of Zion Canyon by the Virgin River on the Western margin of the Colorado Plateau. These low temperature thermochronological systems are sensitive to temperature ranging from 120 to 50°C. Despite the canyon only being a maximum of ~1 km deep, a high local geothermal gradient of >50°C / km means these thermochronometers provide a record of the timing of this incision. Preliminary inverse thermal modelling of apatite fission-track and (U-Th-Sm)/He data suggest reheating following Jurassic deposition to maximum temperatures of ~70-80 °C during the later Cenozoic, with onset of incision-related increased cooling rates in the last 10 Ma. Our results are in agreement with the recent work of Walk et al. (2019) indicating incision by the Virgin River during the last 4 to 3 Myr in the Zion area. Together with existing structural cross-sections and reconstructions of the timing of surface uplift and incision by the Virgin River in the Zion area, our thermochronological data support that Zion Canyon was carved since the late Miocene following tectonically driven rock and surface uplift along the western edge of the Colorado Plateau.  

How to cite: Margirier, A., Thomson, S., and Reiners, P.: Timing of incision of the western margin of the Colorado Plateau, new thermochronological data from Zion Canyon, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1788, https://doi.org/10.5194/egusphere-egu22-1788, 2022.

Despite decades of controversy, our understanding of the formation of the Tibetan Plateau remains limited. The role of competing mechanisms, such as distributed crustal thickening versus lateral propagation of thrust faulting at crustal or lithospheric scales, is still poorly understood. Conceptual models explaining observations at the continental scale are based on hypotheses that are hard to reconcile, on the one hand buoyancy forces dominating with low influence of upper crustal faulting, on the other hand faults dominating by favour discrete propagation of rigid upper crustal thickening since the onset of collision at ~50 Ma. However, in view of the 3D nature and temporal complexity of the involved deformation processes, no numerical model taking into account the role of strike-slip faults in accommodating stepwise evolution of thrust faulting, as well as the interaction between the deep crust and the surface, has yet been implemented. Therefore, it remains difficult to test the mechanical and rheological consistency, and the ability to explain observations, of end-member conceptual models at the scale of the Tibetan Plateau.

In order to generate new insights in deformation modes in Tibet, I will present models to study the mechanical behaviour in the lower crust of the upper crustal thrust faults observed along the Tibet eastern edge, which setup is based upon recent thermo-kinematic modelling of thermochronology data (Pitard et al., 2021). During the PhD of Paul Pitard, in collaboration with Cédric Thieulot and Marie-Pierre Doin, we made schematic 2-D viscous models of thrusts embedded in the crust, to study eastern Tibet thrust activity in the building of the topography through time. We show that both the high viscosity upper crust in which the fault is embedded and more surprisingly the low viscosity lower crust with no fault, are driven toward the surface by the fault. This generates along the fault a parallel zonation of the vertical velocity field, with high velocities close to the fault, decreasing away from it, fitting well the rejuvenation of cooling ages observed toward the thrust of SE Tibet.

In order to explore the influence of erosion during the building of the plateau, I will also present thermo-kinematic modelling of thermochronology data along the Mekong River at the eastern edge of Tibet, including schematic erosion process (Ou et al., 2020). During the PhD of Xiong Ou, in collaboration with Pieter van der Beek, we estimated that the Mekong River incision, locally more than 2000m, is 25-30% of the total exhumation since 10 Ma. Strong differences in elevation and relief on both sides of the Mekong River are linked to strongly differing tectonic imprint, with high elevation low relief surfaces observed when tectonic imprint is low, in part due to glacial “buzzsaw-like” processes, and high elevation high relief massif observed when tectonic imprint is high and when glacial processes are not sufficient to erase the topography created.

How to cite: Replumaz, A.: Building the Tibetan orogenic plateau : the role of thrust faults and the influence of erosion on the eastern edge., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2037, https://doi.org/10.5194/egusphere-egu22-2037, 2022.

EGU22-3155 | Presentations | GM9.1

Tectonic highlights of the recent deformation field of the Pamir, the Tajik basin, and the Hindu Kush, observed by high-resolution satellite-geodesy 

Sabrina Metzger, Łukasz Gągała, Najibullah Kakar, Lothar Ratschbacher, Alexander Zubovich, Jonas Kley, Tilo Schöne, Bernd Schurr, Milan Lazecký, Yasser Maghsoudi, Cornelia Zech, Bolot Moldobekov, and Azamat Sharshebaev

At the northwestern tip of the India-Asia collision zone, the north-advancing Pamir orocline overrides the Tajik-Tarim Basin along a low-angle décollement with N–S shortening rates of 10-15 mm/yr. The Pamir’s advance is buttressed in the North by the Tian Shan. Westward collapse of Pamir crust into the Tajik basin leads to overall E–W shortening in the ~N-trending Tajik fold-thrust-belt. Crustal seismicity highlights fault systems at the northern rim of the Pamir and, since the 2017 Mw7.2 Sarez earthquake, the Sarez-Karakul fault system that separates the western from the eastern Pamir as a surface expression of the northwestern tip of the underthrusting Indian cratonic mantle lithosphere. Towards southwest, the Pamir connects to the rarely sampled Hindu Kush with sparse crustal but abundant intermediate-depth seismicity; the latter is an effect on an ongoing slab break-off.

We recorded displacements along the most active structures creating the recent regional deformation field by multiple satellite-geodetic observations. Up to 4.5-yr-long radar-interferometric time-series (InSAR) provide E–W and vertical surface deformation fields in unprecedented spatio-temporal resolution of 400 m and 12-24 days. The relative InSAR rate maps were tied to and complemented with accurate rates derived from Global Navigation Satellite System (GNSS) data. We collected these data in continuous and survey mode along—sometimes km-spaced—profiles across the most active faults in the region.

We confirm the high interseismic strain localization along the Pamir’s northern thrust front and an increased dextral component towards the northwestern edge of the thrust belt of >8 mm/yr, accommodating the westward collapse of the orocline. The sinistral Sarez earthquake at 120-170 km distance from the front activated the basal décollement, as suggested by mm-to-cm-scale, sharp surface offsets along the whole frontal segment. Relocking occurred gradually in the following four years. Similar co-seismic offsets were observed along the sinistral, NE-trending Darvaz fault, separating the western Pamir from the Tajik basin. The Tajik fold-thrust-belt exhibits ~10 mm/yr of internal E–W shortening, in agreement with fossil shortening rates of 12-8 mm/yr since ~12 Ma. The majority of the deformation is accommodated by the Babadag backthrust (~6 mm/yr)—a major thrust located far west in the belt, and the sinistral Ilyak fault (~6 mm/yr) that bounds the belt to the North. The belt also hosts spectacular horizontal spreading rates of 350 mm/yr at the Hoja Mumin salt fountain. Along the most prominent fault of the Hindu Kush, the Panjsheer fault, a fault-perpendicular GNSS profile observed sinistral slip of >1-4 mm/yr. The fault is probably only locked in the upper ~km as suggested by a sharp, InSAR line-of-sight rate increase of ~6 mm/yr across the fault. This could explain the absence of shallow seismicity in the region.

How to cite: Metzger, S., Gągała, Ł., Kakar, N., Ratschbacher, L., Zubovich, A., Kley, J., Schöne, T., Schurr, B., Lazecký, M., Maghsoudi, Y., Zech, C., Moldobekov, B., and Sharshebaev, A.: Tectonic highlights of the recent deformation field of the Pamir, the Tajik basin, and the Hindu Kush, observed by high-resolution satellite-geodesy, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3155, https://doi.org/10.5194/egusphere-egu22-3155, 2022.

EGU22-3592 | Presentations | GM9.1

Terraces response to different uplift modes at subduction margins: a forward modelling approach 

Silvia Crosetto, Albert de Montserrat, and Onno Oncken

Marine terraces are preserved along the coast when their uplift rate overcomes the rate of sea level increase. Generally, if the relative sea level history is known, elevation and age of marine terraces can be used to quantify the average uplift rate.

At subduction margins, large-scale topography of the fore-arc is the result of complex subduction mechanisms. The existence of uplifted marine terraces along fore-arc coastal areas indicates that the topography is subject to long-term permanent uplift. However, it is yet not known when this permanent uplift is accommodated. Geodetic observations show that, of the total deformation occurring during the megathrust earthquake cycle, only a minimal part (<10-20%) is translated into permanent vertical deformation of the topography. Additionally, particularly high uplift rates (~1 mm/yr) of fore-arcs observed geodetically, or geologically using uplifted marine terraces, suggest the existence of uplift transients or pulses that seem to reflect earthquake clustering on upper plate faults lasting 10 to 100 kyrs, while underplating cycles deduced from field observations and derived from numerical models occur at time scales from 0.5 to 6 Myrs.

We use numerical models to investigate whether different uplift styles are reflected in the geometry of the marine terraces sequences. In particular, we aim at spotting the occurrence of diagnostic patterns representative of different uplift ‘modes’: constant uplift rate, uplift by earthquake pulses (permanent uplift only), or uplift resulting from interseismic and coseismic vertical displacements. The results show that the variability of the terrace staircase morphology subject to different uplift modes increases with the earthquake recurrence time. Preliminary comparison with natural case studies displaying an analogue variability confirms our argument.

How to cite: Crosetto, S., de Montserrat, A., and Oncken, O.: Terraces response to different uplift modes at subduction margins: a forward modelling approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3592, https://doi.org/10.5194/egusphere-egu22-3592, 2022.

Active faults play a major role in relief building, partly through the accumulation of vertical co seismic displacement during major earthquakes. Triangular facets are geomorphic features recording normal fault cumulative displacements on relatively long time scales (10-100ka). To unravel the relationships between the rate at which slip accumulates on a fault scarp and the long-term evolution of triangular facets, we have to acquire quantitative datasets on normal fault slip rates at various timescales and rates of erosion of the facets.

Here we present a study on facet build-up over 10-100 ka time range in the central Apennines in Italy. The normal fault systems that control the present tectonic activity of the range are very well studied with numerous detailed paleoseismological records. We focus on the Magnola-Velino fault system which displays well preserved triangular facets and accurate chronological constraints on the 10-20m high fault scarp located at the base of the facets. We combine high resolution morphometric analysis (gullies steepness, facets slope and others), using Digital Elevation Models derived from Pléiades imagery and a new dataset for cosmogenic nuclides concentration (36Cl) including 54 bedrock samples on 9 gullies and facets profiles above the scarps. Magnola-Velino fault system is 20-25km long, and morphometric parameters such as steepness index display a systematic evolution along strike. First measured 36Cl concentrations, on Magnola, range from 6 to 50 x104 at/g on gullies and 50 to 150 x104 at/g on facets, with systematic variations along strike. We document the joint evolution of geochronological data and morphological parameters for this fault system and compare it with existing constraints on long-term slip rate.

How to cite: Desormeaux, C., Godard, V., Benedetti, L., and Fleury, J.: Comparison of normal fault slip to long-term landscape building. Insights from morphometry analysis and geochronological data on the Magnola-Velino fault system (central Apennines, Italy), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4793, https://doi.org/10.5194/egusphere-egu22-4793, 2022.

Drainage divide migration has drawn growing attention in recent years because it can induce changes in drainage areas and confound inference of spatial or temporal changes in tectonic or climatic forcing from river profiles. Recent studies have used different metrics of divide stability, such as cross-divide contrasts in topography, to quantify a divide’s susceptibility to migration. These metrics are based on expectations of cross-divide differences in fluvial or hillslope erosion rates, yet glacial erosion may be the primary driver of topographic evolution and drainage reorganization in many mid-latitude mountain ranges. Here we report a case study in the northeastern Qilian Shan, a northwest-southeast-trending mountain belt on the northeast margin of the Tibetan Plateau. The northeast-facing range front in Qilian Shan today receives less solar insolation but more summer monsoonal precipitation than the southwest-facing front and thus hosts more small, high elevation valley glaciers. We quantify cross-divide contrasts in topography using different metrics and find stronger glacial modification of topography on northeast-facing slopes than on southwest-facing slopes. The northeast-facing range front displays oversteepened U-shaped valleys and evidence of extensive Quaternary glaciation, whereas the southwest-facing front is incised by V-shaped valleys that hosted only small Quaternary glaciers. Near the drainage divide, valleys on the northeast-facing front have steeper headwalls and higher headwall relief than valleys on the southwest-facing front. Based on these observations, we proposed a conceptual model of divide migration in the northeastern Qilian Shan: during the last glacial period, strong glacial modification on the northeast-facing range front caused headward expansion of valleys and drove southwestward divide migration. Since the onset of the present interglacial period, faster postglacial hillslope processes in northeast-facing valleys have sustained this southwestward divide migration. We develop a numerical model to test this conceptual model and discuss the impact of Quaternary glaciation on drainage reorganization in the Qilian Shan. We suggest that Quaternary glaciation and following postglacial adjustment have important impacts on divide migration and drainage reorganization in mid-latitude mountain ranges.

How to cite: Lai, J. and Huppert, K.: Cross-divide topographic contrasts created by asymmetrical glaciation: A case study from the northeastern Qilian Shan, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5535, https://doi.org/10.5194/egusphere-egu22-5535, 2022.

EGU22-5696 | Presentations | GM9.1

River reorganization based on geomorphic indices in the Huashan Mountains, central China 

Mengyue Duan, Jörg Robl, Franz Neubauer, Xiaohu Zhou, Moritz Liebl, and Anne-Laure Argentin

In many mountainous regions on Earth, strong spatial variations in uplift with a fault-bounded transition from uplift to subsidence drive the coevolution of high mountain topography and adjacent low-lying basins. In this study, we investigate which topographic patterns are characteristic for such a geodynamic setting where actively subsiding and uplifting regions in direct vicinity are tightly linked via dynamically evolving drainage systems. The Huashan Mountains, which is part of the Qinling Mountains range, and the adjacent Weihe Graben close to the city of Xi’an (China) are the perfect locations to investigate the formation of topography in an active basin and range system, and this area links directly to the uplift of the Tibet plateau. The Weihe Graben formed in an extensional environment and experienced significant subsidence with up to ∼7000m Cenozoic sediments. Contemporaneously, topography has formed in the Huashan Mountains bordering the Weihe Graben. Major earthquakes in this region (e.g. the M∼8.5 Huaxian earthquake in the year 1556), pristine fault scarps, bedrock fractures, and loess crevices are evidence for recent tectonic activity. The high relief between the Huashan Mountains and the Weihe Graben favors fluvial bedrock incision and related mass wasting at hillslopes as a response to local relief formation. Frequent landslides triggered by both seismic and storm events are distributed throughout the Huashan Mountains. To quantify the impact of gradients in uplift rate on topography and active tectonics, we applied several DEM-based morphological analyses and compared catchments that drain north to the low-lying Weihe Graben with those that drain south, which were not affected by tectonically induced base level lowering. We analyzed longitudinal channel profiles, channel steepness (ksn), catchment hypsometry, and geophysical relief. To quantify the topographic state of the Huashan Mountains and detect drainage divides that are potentially mobile, we computed χ maps and χ-profiles of these drainage systems. We found that rivers at the northern steep slope of the Huashan Mountains, which is directed towards the Weihe Graben, are in general steeper with a higher valley relief, and feature lower χ value compared to rivers south of the drainage divide. Large across divide gradients in χ could indicate a southward migration of the watershed. Analyzing the drainage pattern close to the watershed, we found strong evidence for two river piracy events (wind gaps, beheaded rivers) suggesting that catchments north of the drainage divide indeed grow at the expense of those in the south. We conclude that the evolution of high, tectonically-driven relief in the Huashan - Weihe region with rising mountain ranges and subsiding basins in direct vicinity causes a state of morphological disequilibrium, where the observed reorganization of the drainage system represents the adjustment towards a morphological steady state. We suggest that strong gradients in uplift rate between Huashan Mountains and adjacent Weihe Graben, and their link via dynamic drainage systems control channel and hillslope morphology, the topology of the drainage system, eventually the overall architecture of the orogen, and to the creation of morphology related to the uplift of the Tibet plateau.

How to cite: Duan, M., Robl, J., Neubauer, F., Zhou, X., Liebl, M., and Argentin, A.-L.: River reorganization based on geomorphic indices in the Huashan Mountains, central China, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5696, https://doi.org/10.5194/egusphere-egu22-5696, 2022.

EGU22-6048 | Presentations | GM9.1

Drainage network as an indicator of tectonic evolution of mountain belts: insight from the Middle Atlas (Morocco). 

Ahmed Yaaqoub, Abderrahim Essaifi, Romano Clementucci, Paolo Ballato, and Claudio Faccenna

In actively deforming regions, the geometry and evolution of fluvial systems are sensitive to surface uplift, style of deformation and erosion processes. The uplift influences drainages via base level changes, drainage reversals, and capture processes. Although drainage development and reorganization might be complex in some cases, it can be used to unravel the tectonic evolution of a region.

The Middle Atlas is an intracontinental fold-and-thrust belt that results from the tectonic inversion of a Triassic to Jurassic continental rift basin. The compressional regime leading to basin inversion has produced limited crustal shortening and thickening in association with the growth of mountain ridges with a wavelength of few km.  These topographic features have been superimposed by a long-wavelength, mantle-driven surface uplift, occurred since the late Cenozoic.

Here, we carry out a topographic and fluvial analysis to investigate at which extent the geomorphic features, mainly the drainage network, reflect the tectonic evolution of the Middle Atlas. Two main drainage divides can be defined in the Middle Atlas: 1) a longitudinal divide that separates an eastern flank draining into the Mediterranean Sea through the Moulouya river from a western flank draining into the Atlantic Ocean through the Sebou and Oum Rbia rivers; 2) a transverse divide that sets apart the catchments of the Sebou and Oum Rbia  rivers. In the eastern flank, where the slopes are steep, the tributaries of the Moulouya river show a parallel pattern and are transversal to the trend of the orogen, whereas in the western flank the rivers are longitudinal and controlled by the tectonic structures. Our results indicate that the topography and drainage are in a disequilibrium condition and in an early stage of evolution. The discrepancy in the rivers network between the two flanks, suggests an asymmetric tectonic uplift history. Specifically the eastern flank of the orogen appears to have accommodated a higher magnitude of late Cenozoic contractional deformation than the western flank

How to cite: Yaaqoub, A., Essaifi, A., Clementucci, R., Ballato, P., and Faccenna, C.: Drainage network as an indicator of tectonic evolution of mountain belts: insight from the Middle Atlas (Morocco)., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6048, https://doi.org/10.5194/egusphere-egu22-6048, 2022.

EGU22-6121 | Presentations | GM9.1

Modelling the influence of fluvial and glacial erosion on mountain range relief using a stream-power approach 

Moritz Liebl, Jörg Robl, Stefan Hergarten, Kurt Stüwe, and Gerit Gradwohl

A common issue in geomorphology is to understand how tectonically induced uplift and climatically driven erosion control the height and steepness of entire mountain ranges. The evolution of characteristic landforms towards a hypothetical steady state topography is well studied for mountain ranges eroded by rivers, but a counterpart for glacial conditions is lacking.

Numerical models of landform evolution are increasingly used to determine the topographic imprint of various processes. However, the complexity arising from multiple processes and possible feedbacks between climate, tectonics and topography leads to process-based but computationally intensive numerical models (e.g., iSOSIA), which have limited applicability on large scales. The open source 2D landform evolution model OpenLEM allows seamless coupling of fluvial and glacial erosion with sediment transport, with almost the same computational efficiency as under purely fluvial conditions (Hergarten, 2021). The calculation of water and ice flow dynamics is not required, as the erosion rate is calculated directly from the properties of the topography (i.e., contributing drainage area and local gradient in the flow direction).

Benchmarking against a process-based landform evolution model (iSOSIA, Egholm et al., 2011) shows that the conversion from fluvial to glacial landscapes produces a consistent glacial signal in the topography, despite local differences in the erosion pattern of both models. Starting from an initial fluvial steady-state mountain range, we investigate the evolution of channel networks with progressive glacial landscape transformation over large time scales where the interaction of earth surface processes with tectonics become relevant. The model shows that both the uplift rates and the parameters of glacial and fluvial erosion control the relief and average slope of the glaciated mountain range. This reflects a situation that is not fundamentally different to fluvial landscapes. Different scenarios are investigated under which conditions a glacial topographic signal accumulates over several glacial cycles or whether the glacial imprint is predominantly removed in interglacial periods.

 

Egholm, D. L., Knudsen, M. F., Clark, C. D., and Lesemann, J. E. (2011): Modeling the flow of glaciers in steep terrains: The integrated second-order shallow ice approximation (iSOSIA), J. Geophys. Res., 116, F02012, doi:10.1029/2010JF001900.

Hergarten, S. (2021): Modeling glacial and fluvial landform evolution at large scales using a stream-power approach, Earth Surf. Dynam., 9, 937–952, https://doi.org/10.5194/esurf-9-937-2021.

How to cite: Liebl, M., Robl, J., Hergarten, S., Stüwe, K., and Gradwohl, G.: Modelling the influence of fluvial and glacial erosion on mountain range relief using a stream-power approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6121, https://doi.org/10.5194/egusphere-egu22-6121, 2022.

EGU22-6143 | Presentations | GM9.1

The usefulness of applying morphometric analyses in intrabasinal faults: the Galera Fault (central Betic Cordillera, S Spain) 

Ivan Medina-Cascales, Francisco Juan García-Tortosa, Iván Martín-Rojas, José Vicente Pérez-Peña, and Pedro Alfaro

Here we prove the usefulness of applying morphometric analyses, typically used in basin-border faults, to evaluate the geomorphic expression of an intrabasinal structure. The target fault of our study is the Galera Fault, a SW-NE, ca. 30 km-long fault located in the Guadix-Baza Basin (central Betic Cordillera, southern Spain). This fault is characterized by low displacement rates, with a major left-lateral (0.5±0.3 mm/yr) and minor (0.02-0.05 mm/yr) vertical slip components. Moreover, the Galera Fault cuts across the Plio-Quaternary basin infilling, so poorly-lithified sedimentary rocks crop out in both fault blocks.

Since the Guadix-Baza Basin was captured in the Middle Pleistocene, it has been dominated by extensive erosion, which has shaped a very young landscape influenced by the activity of the Galera Fault. To evaluate the imprint of the fault on the landscape, we carried out an analysis of the topography and the drainage network from high-resolution digital elevation models (DEMs). In addition, we apply different geomorphic indices, such as the profile relief ratio (PRR), the normalized channel steepness index (ksn), the asymmetry factor (AF), and the valley floor width-to height ratio (Vf).

Our study evidence that the combination of low slip rates and the high erodibility of the juxtaposed rocks favors a rapid landscape response to fault displacement that erases many landscape effects related to active tectonics. This masking is more effective on features generated by strike-slip displacement, leaving only subtle evidence, such as local stream deflections and upstream widening of catchments. In contrast, geomorphic effects related to vertical displacement are better preserved, including the control of the geometry of the main rivers and morphological differences in the drainage network between the two fault blocks. On the upthrown block, streams are generally shorter, steeper and valley incision is more accentuated. These differences between fault blocks are reflected in the development of an impressive badland landscape that is restricted to the upthrown block.

Slow intrabasinal faults can be difficult to detect in studies involving structural mapping, seismic hazard assessment, or exploration of resources, especially when they offset highly erodible deposits and do not present a marked uplift. However, here we demonstrate that the geomorphic anomalies that these structures can leave on the landscape can be identified by applying a proper morphometric analysis.

How to cite: Medina-Cascales, I., García-Tortosa, F. J., Martín-Rojas, I., Pérez-Peña, J. V., and Alfaro, P.: The usefulness of applying morphometric analyses in intrabasinal faults: the Galera Fault (central Betic Cordillera, S Spain), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6143, https://doi.org/10.5194/egusphere-egu22-6143, 2022.

EGU22-6376 | Presentations | GM9.1 | Highlight

Mountains as a source of CO2: a global model of erosion, weathering and fossil organic carbon oxidation 

Jesse Zondervan, Robert Hilton, Fiona Clubb, Mathieu Dellinger, Tobias Roylands, and Mateja Ogrič

For over a century, geologists have vigorously debated the influence of mountains on global climate via links among rock uplift, erosion, chemical weathering, and the geological carbon cycle. For decades, the focus has been on the role of mountain building in drawing down atmospheric carbon dioxide (CO2) via silicate weathering. However, it is now recognized that mountain building and the exhumation of sedimentary rocks can release CO2 through the oxidation of organic carbon in rocks (rock OC). We quantify this flux at a global scale and show that over geological timescales this source is as important as CO2 emissions from volcanism.

We explore the controls of mountain erosion on CO2 release to the atmosphere with a spatially explicit global simulation model that uses empirical constraints on rock OC oxidation flux. We know that erosion is a major control on this flux: rock OC oxidation increases with erosion, up to and greater than erosion rates of ~ 2 mm yr-1. This contrasts with silicate weathering, where rates are limited by reaction kinetics at high erosion rates. We here constrain the spatial distribution of high erosion rates and their overlap with OC-rich bedrock lithologies. The effect of erodibility of such lithologies means that these are predisposed to high rates of CO2 release through weathering. Hence our model relies on lithological mapping to constrain the relationship between topography and exhumation rates, and global rock OC stock. We produce a probabilistic rock OC stock map by combining global lithological maps with the USGS Rock Geochemical Database, which includes over 167,000 samples for our analysis. We consider the role of erosion and chemical weathering by using a probabilistic approach that is built on catchment-scale 10Be denudation rates, while rhenium-based estimates of oxidative weathering intensity and flux from river catchments around the world are used to constrain patterns in rock OC oxidation. To extrapolate the major controls on erosion and weathering we use local slopes derived from 90 m resolution digital elevation model (DEM) data and lithological maps. We combine the erosion, rock chemistry data and weathering intensity estimates to simulate global rock OC weathering rates at a 1 km grid scale via a statistical probability ensemble (Monte Carlo).

We will present the results of our model compilation, including the effect of lithology on erosion, weathering and CO2 emission rates. We demonstrate that the size of the organic carbon stock in the first 1 m of bedrock is of a similar magnitude to the carbon stock of global soils, and that the emissions of CO2 from this geological source are as large as the emissions from volcanic degassing. We identify regions of the Earth’s surface where rock OC could emit substantial amounts of CO2 and provide new constraints on a major natural CO2 flux derived from the erosion of mountains.

How to cite: Zondervan, J., Hilton, R., Clubb, F., Dellinger, M., Roylands, T., and Ogrič, M.: Mountains as a source of CO2: a global model of erosion, weathering and fossil organic carbon oxidation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6376, https://doi.org/10.5194/egusphere-egu22-6376, 2022.

EGU22-7337 | Presentations | GM9.1

Eustatic change modulates exhumation in the Japanese Alps 

Georgina King, Floriane Ahadi, Shigeru Sueoka, Frédéric Herman, Leif Anderson, Cécile Gautheron, Sumiko Tsukamoto, Nadja Stalder, Rabiul Biswas, Matthew Fox, Guillaume Delpech, Stéphane Scharwtz, and Takahiro Tagami

The exhumation of bedrock is controlled by the interplay between tectonics, surface processes and climate. The highest exhumation rates of cm/yr are recorded in zones of highly active tectonic convergence such as the southern Alps of New Zealand or Himalayan syntaxes, where high rock uplift rates combine with very active surface processes. Here, we use a combination of different thermochronometric systems, and notably trapped-charge thermochronometery, to show that such rates also occur in the Hida Range, Japanese Alps. Our results imply that cm/yr rates of exhumation may be more common than previously thought.

The Hida Range is the most northern and most extensive of the Japanese Alps, and reaches elevations of up to 3000 m a.s.l. The Hida Range is thought to have uplifted in the last 3 Myr in response to E-W compression and magmatism. Our study focuses on samples from the Kurobe gorge, which is one of the steepest gorges in Japan. Previous work has shown that exhumation rates in this region are exceptionally high, as documented by the exposure of the ~0.8 Ma Kurobe granite (Ito et al., 2013) in the gorge. We combined 12 new zircon (U-Th/He) ages and 11 new OSL-thermochronometry ages together with existing thermochronometric data to investigate the late Pleistocene exhumation of this region.

We found that exhumation rates increased to ~10 mm/yr within the past 300 kyr, likely in response to river base-level fall that increased channel steepness due to climatically controlled eustatic changes. Our thermochronometry data allow the development of time-series of exhumation rate changes at the timescale of glacial-interglacial cycles and show a four-fold increase in baseline rates over the past ~65 kyr. This increase in exhumation rate is likely explained by knickpoint propagation due to a combination of very high precipitation rates, climatic change, sea-level fall, range-front faulting and moderate rock uplift. Our data show that in regions with horizontal convergence, coupling between climate, surface processes and tectonics can exert a significant effect on rates of exhumation.

References

Ito, H., Yamada, R., Tamura, A., Arai, S., Horie, K., Hokada T., 2013. Earth’s youngest exposed granite and its tectonic implications: the 10-0.8 Ma Kurobegawa Granite. Scientific Reports 3: 1306.

 

How to cite: King, G., Ahadi, F., Sueoka, S., Herman, F., Anderson, L., Gautheron, C., Tsukamoto, S., Stalder, N., Biswas, R., Fox, M., Delpech, G., Scharwtz, S., and Tagami, T.: Eustatic change modulates exhumation in the Japanese Alps, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7337, https://doi.org/10.5194/egusphere-egu22-7337, 2022.

EGU22-8123 | Presentations | GM9.1

Understanding landscape evolution parameters using global 10Be erosion rates 

Gregory Ruetenik, John Jansen, and Pedro Val

Landscape evolution models simulate erosional and depositional changes in terrain surface over time and have proven useful for studying surface processes at a variety of scales. These models rely on several input parameters such as a coefficient of hillslope diffusion (D), as well as stream power exponents of drainage basin area (m) and slope (n), a value of minimum drainage area (Ac) below which advective fluvial processes dominate over diffusive hillslope processes, and an effective stream power/advection coefficient of rock ‘erodibility’ (k). In spite of the widespread application of landscape evolution models, values of these input parameters and their variation through space and time are generally poorly constrained in large part due to the large number of processes and physical properties which are amalgamated into the advection-based SP equation. Several recent studies have looked at global controls on erosion rates using stream power parameters and other river metrics by making use of sophisticated stream profile analysis tools, and we aim to build on these past studies by using a landscape evolution modelling framework.  Here, we make use of a global catalog of basin-averaged cosmogenic 10Be-derived apparent erosion rates to tune several landscape evolution model parameters. We employ an Approximate Bayesian Computation (ABC) approach which is based on the performance of many combinations of randomly selected parameters with respect to a likelihood function that measures how well a model fits a sample of observations for a given set of parameter values. Prescribing the commonly observed stream concavity ratio (m/n) of 0.5, maximum agreement between LEM-predicted and 10Be apparent erosion rates is obtained when the free parameters of stream power slope coefficient (n) is approximately 2, the ratio of hillslope diffusivity (D) to effective stream power coefficient (K) is between 103 and 104 mn-1 yr-1 and when critical drainage area (Ac) is ~0.1 km2. Additionally, we find that models can be optimized to a greater degree when the diffusive component of the LEMs is squared, in line with recent studies. Finally, we perform a search for optimal parameters in the face of variable stream concavity, climate, and geology which are encompassed in k, D, m, and n,  all of which show considerable variability over different climatic, lithologic, and ecologic regimes. Ultimately, this demonstrates that globally optimal parameters may not be applicable at the local to regional scale, but continent to global scale analyses could benefit from understanding these optimal parameters.

How to cite: Ruetenik, G., Jansen, J., and Val, P.: Understanding landscape evolution parameters using global 10Be erosion rates, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8123, https://doi.org/10.5194/egusphere-egu22-8123, 2022.

EGU22-8794 | Presentations | GM9.1

Sedimentary record of tectonic inversion and basin partitioning in the South-Central Pyrenees during the Late Cretaceous. 

Oriol Oms, Jaume Dinarès-Turell, Enric Vicens, Carme Boix, Javier Gil-Gil, José García-Hidalgo, and Pedro Ramírez-Pérez

The tectosedimentary evolution of the Pyrenees is a well-known example of the interaction among growth strata, sediment routing, sequence stratigraphy and evolving depositional environments. During the Late Cretaceous a general tectonic inversion from rift to foreland basin is recorded. Such evolution is related to the Iberian plate kinematics and is evidenced by the substitution of carbonate systems by mixed and clastic ones, that will persist until Oligocene times.

The precise evolution and timing of the inversion stages is addressed by studying the Noguera Pallaresa river transect (composite Collegats -Font de la Plata section) which is further compared with other areas. This classical transect also permits to study successive structure reactivations after inversion started. Robust magnetostratigraphic results from several stratigraphic units (Font de les Bagasses marls, Riu Boix platform or Montsec sands) permit an accurate dating of the beginning of the inversion stage within the Santonian and also provide time constraints (together with absolute datings) for the rest of the Late Cretaceous. The role of the Montsec thrust as paleohigh controlling basin partitioning is also evidenced by a large paleocurrent database obtained from the Areny sandstone formation. Sedimentological data and carbonate microfacies determinations also provide refinements of the complex interaction between tectonic and climatic factors.

Finally, the combined biomagnetostratigraphic age model is compared with the peripheral areas of the foreland such as Serres Marginals, Eastern and Northern Pyrenees. It is strongly suggested that the formation of accommodation space for sedimentation due to the inversion was fully synchronous all over the orogen.

How to cite: Oms, O., Dinarès-Turell, J., Vicens, E., Boix, C., Gil-Gil, J., García-Hidalgo, J., and Ramírez-Pérez, P.: Sedimentary record of tectonic inversion and basin partitioning in the South-Central Pyrenees during the Late Cretaceous., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8794, https://doi.org/10.5194/egusphere-egu22-8794, 2022.

EGU22-8815 | Presentations | GM9.1

Quantifying the growth and decay of topography in collisional orogens 

Sebastian G. Wolf, Ritske S. Huismans, Jean Braun, and Xiaoping Yuan

It is widely recognized that mountain belt topography is generated by crustal thickening and lowered by river incision, linking climate and tectonics. However, it remains enigmatic whether surface processes or lithospheric strength control mountain belt height, width, and longevity, reconciling high erosion rates observed for instance in Taiwan and New Zealand and low erosion rates in the Tibetan and Andean plateaus, as well as long-term survival of mountain belts for several 100s of million years as observed in the Urals and Appalachians. Here we use a tight coupling between a landscape evolution model (FastScape) and a thermo-mechanically coupled mantle-scale tectonic model (Fantom) to investigate mountain belt growth and decay. Using several end-member models and introducing the new non-dimensional Beaumont number, Bm, we quantify how surface processes and tectonics control mountain growth and define three end-member types of growing orogens: Type 1, non-steady state, strength controlled; Type 2, flux steady state, strength controlled; and Type 3, flux steady state, erosion controlled. Orogenic decay is determined by erosional efficiency and can be subdivided into two phases with variable isostatic rebound characteristics and associated timescales: First short-wavelength relief is removed within a few Myr, followed by removal of long-wavelength topography and effectively local isostatic rebound. Comparing model and scaling results to natural orogens explains why different orogens on Earth are rheology or erosion- (climate)-limited, and why long-term survival of topography seems to be the norm rather than the exception.

How to cite: Wolf, S. G., Huismans, R. S., Braun, J., and Yuan, X.: Quantifying the growth and decay of topography in collisional orogens, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8815, https://doi.org/10.5194/egusphere-egu22-8815, 2022.

EGU22-9531 | Presentations | GM9.1

Plio-/Pleistocene landscape evolution in the Eastern Alps: new insights from cosmogenic nuclide dating 

Gerit Gradwohl, Kurt Stüwe, Jörg Robl, Lukas Plan, Derek Fabel, Finlay Stuart, Moritz Liebl, and Luigia Di Nicola

The Eastern Alps hold an abundance of landscapes with noticeably low topographic gradients at higher elevations above much steeper slopes. Many of these elevated low-relief landscapes (ELRL) are organized in distinct surface levels. Sub-horizontal cave systems can often be found at similar elevations. Utilizing spatial statistics of these ELRL and over 15000 caves, we show that the formation of both the surface and sub-surface landscapes is connected and can help deciphering the landscape evolution of the Eastern Alps from the Late Neogene until today. New cosmogenic nuclide data (10Be, 21Ne, 26Al) of allogenic quartzous sediments from caves and surfaces of distinct elevation levels in the Eastern Alps are used to quantify the incision and ultimately surface uplift history. Burial ages of cave sediments scatter between 0.5 and over 5 Ma. The preliminary data indicate a mean surface uplift of some 0.15 – 0.25 mm/year for much of the Pliocene. We also show that most ELRL in the Eastern Alps can be interpreted in terms of pre-Pleistocene relict landscapes, especially in the only minorly glaciated eastern part.  However, the data also show some impact of the Pleistocene glacial cycles on the ELRL and the mobilization of sediments associated with them.

How to cite: Gradwohl, G., Stüwe, K., Robl, J., Plan, L., Fabel, D., Stuart, F., Liebl, M., and Di Nicola, L.: Plio-/Pleistocene landscape evolution in the Eastern Alps: new insights from cosmogenic nuclide dating, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9531, https://doi.org/10.5194/egusphere-egu22-9531, 2022.

EGU22-11244 | Presentations | GM9.1

Propagating uplift controls on high-elevation, low-relief landscape formation in Southeast Tibetan Plateau 

Xiaoping Yuan, Kim Huppert, Jean Braun, Xiaoming Shen, Jing Liu-Zeng, Laure Guerit, Sebastian Wolf, Junfeng Zhang, and Marc Jolivet

High-elevation, low-relief surfaces are widespread in many mountain belts. However, the origin of these surfaces has long been debated, with previous studies proposing that they either represent a relict low-relief surface, uplifted and eroded by a wave of upstream incision instigated by a Cenozoic increase in rock uplift, or that they formed by tectonic shortening and consequent drainage reorganization. In particular, the Southeast (SE) Tibetan Plateau has extensive low-relief surfaces perched above deep valleys and in the headwaters of three of the world’s largest rivers (Salween, Mekong and Yangtze). Various geologic data, synthesized low-temperature thermochronologic data, and geodynamic models show that many mountain belts grow first to a certain height and then laterally in an outward propagation sequence. By translating this information into a kinematic propagating uplift function in a landscape evolution model, we propose that the high-elevation, low-relief surfaces in the SE Tibetan Plateau are simply a consequence of mountain growth and do not require a special process to form. The propagating uplift forms an elongated river network geometry with broad high-elevation, low-relief headwaters and interfluves that persist for tens of millions of years, consistent with the observed geochronology. We suggest that the low-relief interfluves can be long-lived because of their unusually/unproportionally small drainage area in comparison with the large mainstem rivers. The propagating uplift also produces spatial and temporal exhumation patterns and river profile morphologies that match observations. Our modeling therefore reconciles geomorphic observations with geodynamic models of uplift of the SE Tibetan Plateau, and provides a simple mechanism to explain low-relief surfaces observed in several mountain belts on Earth.

How to cite: Yuan, X., Huppert, K., Braun, J., Shen, X., Liu-Zeng, J., Guerit, L., Wolf, S., Zhang, J., and Jolivet, M.: Propagating uplift controls on high-elevation, low-relief landscape formation in Southeast Tibetan Plateau, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11244, https://doi.org/10.5194/egusphere-egu22-11244, 2022.

EGU22-12510 | Presentations | GM9.1

Tectonic activity assessment using morphometric indices - Tokaj Mountain (Hungary) 

Seif Ammar and Gáspár Albert

The Tokaj Mountain in North eastern Hungary is part of the andesitic and dacitic volcanic arc of the inner Carpathians. The mountain is surrounded by first order strike-slip faults from the W and SE side respectively called as the Hernád Fault and Bodorg Fault. These faults are moderately active today, in the interior of the mountain range. However, there are few rock outcrops indicative of structural movement, but the morphology of the watercourses suggests that the area was more active in the recent past.

The present study aims to examine the link between the actual morphology of the mountain and the major tectonic factors affecting the region. In this regard, a morphometric analysis was performed adopting six indices in order to describ the relative active tectonism of the region based on the method of El Hamdouni et al.(2008)

The method consists of the analyis of drainage basins and includes the evaluation of the morphometric indices namely: the stream-gradient index (SL), the asymmetry factor (AF), the basin shape ratio (Bs), the hypsometric integral (HI), the ratio of valley floor width to valley height (Vf) and the mountain front sinuosity (Smf). The combination of these parameters could be used to generate the relative tectonic activity index (Iat). A pre-processed SRTM DEM 30m resolution has been used for the watershed delineation, calibrated with open source real stream data. 

The study area covers the entire catchment area of the Hernád River the Tokaj and the Cserehát Mountains devided into six drainage basins. The evaluation result shows a moderate relative tectonic activity, except the eastern side of the mountain, where  the activity is low (flat area). However, there was also a slight difference in activity between the western and eastern sides of the lower Hernád River, and also a remarquable morphological  contrast could be noticed on the bordering areas of Hernád drainage basin. The results are in line with the relatively quiet structural activity currently observed, but further detailed data (well logs, interferometry analysis) and high resolution DEM are needed to reveal the structural characteristics of the Tokaj Mountains.

From the part of G.A. financial support was provided from the NRDI Fund of Hungary, Thematic Excellence Programme no. TKP2020-NKA-06 (National Challenges Subprogramme) funding scheme.

Reference:

El Hamdouni et al (2008). Assessment of relative active tectonics, southwest border of the Sierra Nevada (southern Spain), Geomorphology, 96(1-2), 150-173.

 

How to cite: Ammar, S. and Albert, G.: Tectonic activity assessment using morphometric indices - Tokaj Mountain (Hungary), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12510, https://doi.org/10.5194/egusphere-egu22-12510, 2022.

EGU22-13098 | Presentations | GM9.1

Climate and sediment mobility modulate topography-tectonic link in the Andes 

Rebekah Harries and Felipe Aron

The strong gradients in climate and tectonics along the Chilean-Argentine Andes offer the perfect opportunity to study wider landscape controls on mountain topography.

Between 33 and 37oS we observe the largest variability in mountain elevation and erosion rates. For this region, we isolate the tectonic contribution to topography by modelling the mechanical dislocation of the crustal scale faults in response to plate convergence. We then use this spatially variable uplift field to determine to what extent the existing topography records this tectonic signal. While local relief and channel steepness do record responses to faulting on the Chilean side of the cordillera, the broader areas of highest uplift in Argentina have the lowest local relief and channel steepness. We therefore explore how this relationship between tectonics and topography may have been modified by the spatial variability in bedrock lithology, sediment cover and mean annual precipitation. We find that channel steepness does not vary significantly with bedrock lithology but does map onto trends in precipitation and sediment cover. The lowest local relief and channel steepness regions have low precipitation rates and widespread sediment cover, suggesting sediment mobility, modulated by climate, maybe an important control on bedrock incision rates in this high uplift zone. We therefore highlight the importance of climate in the recovery of post-glacial landscapes and the modulatory effect sediment cover can have in the evolution of large scale topography.

How to cite: Harries, R. and Aron, F.: Climate and sediment mobility modulate topography-tectonic link in the Andes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13098, https://doi.org/10.5194/egusphere-egu22-13098, 2022.

TS6 – Extensional tectonic settings

EGU22-1405 | Presentations | TS6.1

Structure and Morphology of the Mid-Ocean-Ridge in the Red Sea 

Antoine Delaunay, Abdulkader Alafifi, Guillaume Baby, Jakub Fedorik, Paul Tapponnier, and Jérôme Dyment

This presentation describes the structure and morphologies associated with seafloor spreading in the Red Sea inferred from bathymetric, gravity, magnetic and seismic data. We show that the orientation of the structures is consistent with an Arabia-Nubia Euler pole located within the 95% confidence of Ar-Rajehi et al, (2010) Euler pole and with the tectonic model initially proposed by Girdler (1984). At the Red Sea scale, our model shows that a spreading axis extends along its entire length, even though it is mostly covered by allochthonous Middle Miocene salt and Late Miocene minibasins flowing inward from the margins. In the northern Red Sea, oceanic basement is only exposed through small windows within the salt, forming a series of deeps. The seafloor segments symmetrically bisect the new ocean in the south. Right-stepping transform faults that cluster near Jeddah, Zabargad and Ikhwan Islands offset the ridge axis as spreading is getting more oblique towards the Euler Pole. The northern, central and southern Red Sea segments display a well-developed mid-ocean ridge flanked by landward-dipping volcanic basement, typical of slow spreading ridges. In the northern magma poor spreading segment, mantle exhumation is likely at the transition between continental and oceanic crust. Transpression and transtension along transform faults accounts for the exhumation of the mantle on Zabargad Island as well as the collapse of a pull-apart basin in the Conrad deep.

We propose a new structural model for the Red Sea constrained by the geodetic rules of tectonic plates movements on a sphere. Finally, we discuss the effect of the Danakil microplate on the ridge morphology and show that the Arabia-Nubia-Danakil triple junction is likely located further north than previously described, around 18±0.5°N, where we observe a shift in the ridge axis orientation as well as in the spreading orientation.

How to cite: Delaunay, A., Alafifi, A., Baby, G., Fedorik, J., Tapponnier, P., and Dyment, J.: Structure and Morphology of the Mid-Ocean-Ridge in the Red Sea, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1405, https://doi.org/10.5194/egusphere-egu22-1405, 2022.

EGU22-1696 | Presentations | TS6.1

Continental rifts and mantle convection: Insights from the East African Rift and a new model of the West European Rift System 

Laurent Jolivet, Cécile Allanic, Thorsten Becker, Nicolas Bellahsen, Justine Briais, Anne Davaille, Claudio Faccenna, Eric Lasseur, and Barbara Romanowicz

The origin of the Eocene-Oligocene European Cenozoic Rift System (ECRIS) is debated in terms of driving forces, far-field or near field, Alpine slab-pull or active plume. An analysis of residual (non-isostatic) topography over Africa and Europe reveals domains elongated parallel to the absolute motion of plates in a hot-spot reference frame. The East African Rift (EAR) and the ECRIS sit on top of such positive anomalies. A recent whole mantle tomographic model (French et al., 2013; French & Romanowicz, 2015; Davaille & Romanowicz, 2020) shows in addition that the low shear-wave velocity zones of the lower and upper mantle are organized with a bundle of vertical plumes and horizontal fingers pointing in the same direction parallel to the absolute motion of Africa and Eurasia, thus parallel to the main rifts. The case of the EAR and its magmatic extension toward the north across the Arabian Plate is particularly clear with several levels of such fingers. The northward migration of the first volcanism from Ethiopia to Armenia between the Eocene and the Late Miocene suggests that the asthenosphere moves faster than the plates and thus drives plate motion (Faccenna et al., 2013). We propose a simple model where plates are driven by basal drag, following an upwelling from the low-velocity anomalies below Africa and toward subduction zones. The EAR develops as lithospheric weak zones on top of the positive anomalies of residual topography due to the underlying low velocity anomalies elongated parallel to the absolute motion. This indicates an interplay between large-scale convection, a small-scale fingering instability, and lithospheric deformation. The development of the Eocene-Oligocene short-lived ECRIS and its interference with Mediterranean slab dynamics are then discussed in the framework of this simple model.

How to cite: Jolivet, L., Allanic, C., Becker, T., Bellahsen, N., Briais, J., Davaille, A., Faccenna, C., Lasseur, E., and Romanowicz, B.: Continental rifts and mantle convection: Insights from the East African Rift and a new model of the West European Rift System, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1696, https://doi.org/10.5194/egusphere-egu22-1696, 2022.

EGU22-1799 | Presentations | TS6.1

Punctuated propagation of a corrugated extensional detachment offshore West of Ireland 

Gaël Lymer, Conrad Childs, and John Walsh

Corrugated detachments are fundamental crustal structures found in many extensional systems and plate tectonic boundaries, including mid-oceanic ridges and rifted margins. Direct observations of the complete geometry of extensional detachments are rare and our understanding of detachment fault structures and the mechanisms of development of high-angle normal faults and their rotation to lower angles mainly relies on proxy observations, for example seismicity trends, and numerical modelling.

We present interpretations of a high-resolution 3D seismic reflection survey from the hyperextended domain of the Porcupine Basin, Offshore West of Ireland. The 3D data image a highly reflective corrugated surface, the P reflector, that we interpret as an extensional detachment preserved in its slip position that likely developed at the top mantle surface during Jurassic hyperextension of the basin. Within the 3D data, the P reflector covers an area 95 km long and 35 km wide and has a domal shape that is elongate in the N-S direction with a crest at ~6.3 s two way travel time. It is the first time to our knowledge that 3D seismic data has imaged a complete detachment in the hyperextended area of a rifted margin, including its domal shape, the breakaway structures, and the linkage between the steep and shallow segments of the detachment. The resolved texture and geometry of the detachment and its relationship with overlying faults provide a basis for refining current models of detachment formation accommodating extreme extension.

Steep west-dipping faults mark the western frontal margin of the detachment. The steep faults pass eastward into shallower, predominantly west-dipping faults that appear to merge downwards with the P reflector. The P reflector has pronounced E-W corrugations, interpreted to indicate the detachment slip vector. The reflector is also characterised by abrupt changes in dip across N-S transverse ridges. These ridges are spaced on average 10 km apart, they coincide with lines of intersection between the P reflector and large overlying faults, and they often mark the termination of detachment corrugations. We interpret these ridges as recording former locations of the western boundary of the detachment so that they indicate a step-wise westward propagation of the P reflector. While it is generally accepted that detachments develop by oceanward propagation, we suggest that the faceted nature of the detachment indicates that this process is a punctuated one and that the clearly imaged transverse ridges record the oceanward stepping of the detachment with the initiation of a new family of steep faults.

We propose a new concept for the growth of detachments that may be applicable to other detachments that accommodate extreme extension, for example at mid-oceanic slow and ultra-slow spreading ridges.

How to cite: Lymer, G., Childs, C., and Walsh, J.: Punctuated propagation of a corrugated extensional detachment offshore West of Ireland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1799, https://doi.org/10.5194/egusphere-egu22-1799, 2022.

EGU22-2208 | Presentations | TS6.1 | Highlight

New mapping of the Afar Depression: towards the better understanding of rift dynamics in a hotspot-influenced continental rift zone 

Valentin Rime, Anneleen Foubert, Balemwal Atnafu, and Tesfaye Kidane

The Afar Depression forms a triple junction between three rift systems: the Red Sea Rift, the Gulf of Aden Rift and the Main Ethiopian Rift. Rifting began in the Oligocene after the eruption of the Ethiopian Flood Basalts. It represents a unique modern example of hotspot-influenced continental breakup. Its emerged position allows detailed field and remote sensing investigations. Important mapping efforts in the area during the 60s and 70s provided very valuable input for the understanding of the local geology but also for the development of global tectonic, volcanological and sedimentary concepts in continental rift settings.

This study presents the compilation of a new geological map which covers the complete Afar depression and includes its Phanerozoic sedimentary and magmatic cover. The map is based on extensive literature research, remote sensing and fieldwork. The geological history of the Afar Depression has also been reviewed. The map evidences the complexity of the rift system with the interaction of distinct tectonic plates, blocks, rift segments, sedimentary basins and volcanic areas that evolve through time and space. This integrative geological map and review is used to reassess and discuss aspects of the style, evolution, kinematics and dynamics of this rift system. Studying this unique modern example of active rifting will help in the better comprehension of rift processes and passive margin development worldwide.

How to cite: Rime, V., Foubert, A., Atnafu, B., and Kidane, T.: New mapping of the Afar Depression: towards the better understanding of rift dynamics in a hotspot-influenced continental rift zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2208, https://doi.org/10.5194/egusphere-egu22-2208, 2022.

EGU22-2290 | Presentations | TS6.1

Petrological evidence for focussed mid-crustal magma intrusion in the Main Ethiopian Rift 

Kevin Wong, David Ferguson, Penny Wieser, Daniel Morgan, Marie Edmonds, Amdemichael Zafu Tadesse, and Gezahegn Yirgu

Rifting in Ethiopia is predominantly driven by magmatic intrusion into the rifting crust. Unravelling the dynamics of lithospheric melt migration and storage is paramount to understanding the late-stage development of continental rifts. In particular, extensive geophysical observations of the structure and composition of rifting crust must be supported by petrology to provide a complete picture of rift-related magmatism. We present major element, trace element, and volatile element compositional data for olivine-hosted melt inclusions from the Boku Volcanic Complex (BVC), a monogenetic cone field in the north Main Ethiopian Rift. Through combined CO2-density-calibrated Raman spectroscopy and secondary ion mass spectrometry we assess the total CO2 concentrations within the melt inclusions allowing us to estimate pressures of entrapment via CO2-H2O solubility models. Our results show that primitive BVC melts carry up to 0.58 wt% CO2 (mean ~0.2 wt%), with as much as half of the CO2 in the melt inclusion present within shrinkage bubbles. Volatile solubility models suggest that these melts are stored over a narrow range of depths (10-15 km), consistent with geophysical data and implying the existence of focussed zone of magma intrusion at mid-crustal depths. The expansive range of trace element concentrations in the inclusions illustrate that, at the time of entrapment, compositional heterogeneity remains extant, and melts must therefore be stored in discrete magmatic bodies with limited mixing. Our results have implications for understanding the interplay between magma intrusion and extensional tectonics during continental break-up, such as magmatic compensation of crustal thinning and the thermo-mechanical effects of melt emplacement into the rifting crust.

How to cite: Wong, K., Ferguson, D., Wieser, P., Morgan, D., Edmonds, M., Tadesse, A. Z., and Yirgu, G.: Petrological evidence for focussed mid-crustal magma intrusion in the Main Ethiopian Rift, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2290, https://doi.org/10.5194/egusphere-egu22-2290, 2022.

EGU22-3259 | Presentations | TS6.1

Triassic sedimentation on the Eastern Atlantic margin: two examples from Moroccan Meseta and Portugal 

Rachid Essamoud, Abdelkrim Afenzar, and Ahmed Belqadi

The continental deposits of the Triassic basins developed along the eastern margin of the Central and North Atlantic show a similar sedimentological evolution, as those of the western margin resulting from the interaction of various processes.

The examples chosen in this work are those of the Mohammedia-Benslimane-ElGara-Berrechid basin MBEB in the Moroccan meseta that we studied in detail in the field, and that we tried to compare with Portugal which is on the same East Atlantic margin.

At the begininig of the Mesozoic, the northwestern part of the African continent was affected by an initial fracturing associated with the early stages of the opening of the Central Atlantic (Atlantic rift) during which several Moroccan Triassic basins are open.

The Mohammedia-Benslimane-ElGara-Berrechid basin is part of the Moroccan western Triassic province, which corresponds to all the basins of the Moroccan Atlantic margin in direct relation with the Atlantic rift. In this basin, an asymmetric rift is set up on the old Hercynian structures during the Carnien-Norien, the paroxysm is reached at the Trias-Lias passage with the installation of basalts (CAMP: Central Atlantique Magmatic Province).

During rifting (syn-rift stage in the Upper Triassic), the MBEB basin experienced three major phases of sediment filling. The first phase is purely continental, the first deposits to arrive in the opening basin are of proximal fluvial origin. Subsequently, the decrease of the paleopente and the rise of the base level generated paleoenvironmental changes in the basin (2nd phase), and the deposition system evolved towards distal environments. During the third phase, the syn-rift sedimentary series recorded a marine incursion in the late Triassic with saliferous sedimentation. This marine intervention is deduced from the presence of a thick saliferous series with a large lateral extension and whose isotopic ratios of sulfur and bromine contents indicate their marine origin. These marine waters are probably of Tethysian origin and are also linked to the opening of the Proto-Atlantic.

In Portugal, the Upper Triassic is represented by two formations in the north of the Lusitanian basin (Palain, 1976): Silves Fm which is fluvial sandstone and Dagorda Fm which includes first dolomites and then evaporites. In this Portuguese basin, the proximal-distal fluvial transition took place at the Norien-Rhétien limit. This also rift-type basin was filled with continental fluvial and alluvial clastic rocks of the Silves Formation, largely derived from the adjacent Iberian highlands of the Meseta. Locally, black shales are present at the top of the Silves and may represent the first marine incursion into the basin.

The comparison between the two basins shows that they followed a similar evolution at the base and in the middle of the series but at the top the MBEB basin presented thick layers of evaporites while that of Portugal presented mainly dolomites attributed to paralic facies.

Palain, C., 1976. Une série détritique terrigene; 'les grès de silves'; Trias et Lias inférieur du Portugal. Mem. Serv. Geol. Portugal, p. 25 (377 pp.)

How to cite: Essamoud, R., Afenzar, A., and Belqadi, A.: Triassic sedimentation on the Eastern Atlantic margin: two examples from Moroccan Meseta and Portugal, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3259, https://doi.org/10.5194/egusphere-egu22-3259, 2022.

EGU22-4683 | Presentations | TS6.1

The Crust and Uppermost-Mantle Structure of the Turkana Depression: Insights from Surface-Wave Analysis 

Rita Kounoudis, Ian Bastow, Cynthia Ebinger, Christopher Ogden, Atalay Ayele, Rebecca Bendick, Nicholas Mariita, Gladys Kianji, Martin Musila, and Garrett Sullivan

Multiple geoscientific studies along the Main Ethiopian and Eastern rifts have revealed that extension via magma intrusion now prevails over plate stretching as the primary mechanism for strain accommodation throughout the crust and mantle lithosphere. However, problematic in this picture is where the Main Ethiopian and Eastern rifts meet, across the low-lying, broadly-rifted, and as-yet poorly-studied Turkana Depression which separates the elevated Ethiopian and East African plateaus. We have so far revealed through body-wave tomography (Kounoudis et al., 2021), that the Depression does not lack mantle dynamic support in comparison to the plateaus, suggesting a significantly thinned crust, resulting from superposed Mesozoic and Cenozoic rifting, most likely explains its low elevations. Slow uppermost-mantle wavespeeds imply the presence of either melt-intruded mantle lithosphere or ponded asthenospheric material below lithospheric thin-spots induced by the region’s multiple rifting phases. To better illuminate the Depression’s lithosphere-asthenosphere system, we conduct a surface-wave analysis to image crust and uppermost-mantle structure using data from the NSF-NERC funded Turkana Rift Arrays Investigating Lithospheric Structure (TRAILS) project broadband seismic network. In particular, we investigate the presence of melt, whether the lithosphere is melt-rich, melt-poor, and/or if ponded zones of asthenosphere exist below variably thinned lithosphere. Group velocity dispersion curves, measured using data from local and regional earthquakes, yield the first high resolution fundamental mode Rayleigh-wave group velocity maps for periods between 4 and 40s for the Turkana Depression. In collaboration with the ongoing TRAILS GPS project, we explore how these results relate to present-day versus past episodes of extension.

 

Kounoudis, R., Bastow, I.D., Ebinger, C.J., Ogden, C.S., Ayele, A., Bendick, R., Mariita, N., Kiangi, G., Wigham, G., Musila, M. & Kibret, B. (2021). Body-wave tomographic imaging of the Turkana Depression: Implications for rift development and plume-lithosphere interactions. G3, 22, doi:10.1029/2021GC009782.

How to cite: Kounoudis, R., Bastow, I., Ebinger, C., Ogden, C., Ayele, A., Bendick, R., Mariita, N., Kianji, G., Musila, M., and Sullivan, G.: The Crust and Uppermost-Mantle Structure of the Turkana Depression: Insights from Surface-Wave Analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4683, https://doi.org/10.5194/egusphere-egu22-4683, 2022.

EGU22-5758 | Presentations | TS6.1

Evolution of rift systems and their fault networks in response to surface processes 

Derek Neuharth, Sascha Brune, Thilo Wrona, Anne Glerum, Jean Braun, and Xiaoping Yuan

During the formation of rifted continental margins, a rift evolves through a number of stages that produce major sedimentary basins and distinct rifted margin domains. While these domains have been classified based on the resulting structures and crustal thickness seen in geophysical data, the evolution of the fault network that produces these domains is not as well understood. Further, margin architecture may be influenced by erosion and sedimentation. Previous studies have qualitatively examined how faults respond to sedimentation during rifting, but there has not been a quantitative study on how variable surface processes efficiency affects fault network properties and the effect this has on rift evolution.

In this study we use a two-way coupling between the geodynamic code ASPECT (Kronbichler et al., 2012) and the surface processes code FastScape (Braun and Willett, 2013) to run 12 high-resolution 2D rift models that represent asymmetric, symmetric, and wide rift types (Neuharth et al., in review). For each rift type, we vary the surface process efficiency by altering the bedrock erodibility (Kf) from no surface processes to low (Kf = 10-6 m0.2/yr), medium (10-5), and high efficiency (10-4). To analyze these models, we use a novel quantitative fault analysis toolbox that extracts discrete faults from our continuum models and correlates them through space and time (https://github.com/thilowrona/fatbox). This toolbox allows us to track faults and their properties such as the number of faults, their displacement, and cumulative length, to see how they evolve through time, as well as how these properties change given different rifting types and surface processes efficiency.

Based on the evolution of fault network properties, we find that rift fault networks evolve through 5 major phases: 1) distributed deformation and coalescence, 2) fault system growth, 3) fault system decline and basinward localization, 4) rift migration, and 5) continental breakup. Each of these phases can be correlated to the rifted margin domains defined from geophysical data (e.g., proximal, necking, hyperextended, and oceanic). We find that surface processes do not have a large impact on the overall evolution of a rift, but they do affect fault network properties by enhancing strain localization, increasing fault longevity, and reducing the total length of a fault system. Through these changes, they can prolong rift phases and delay continental breakup with increasing surface process efficiency. To summarize, we find that surface processes do not change the overall evolution of rifts, but they do affect fault growth and as a result the timing of rifting.

 

Braun, J., and Willett, S.D., 2013, A very efficient O(n), implicit and parallel method to solve the stream power equation governing fluvial incision and landscape evolution: Geomorphology, v. 180–181, p. 170–179, doi:10.1016/j.geomorph.2012.10.008.

Kronbichler, M., Heister, T., and Bangerth, W., 2012, High Accuracy Mantle Convection Simulation through Modern Numerical Methods.: Geophysical Journal International, v. 191, doi:doi:10.1111/j.1365-246x.2012.05609.x.

Neuharth, D., Brune, S., Wrona, T., Glerum, A., Braun, J., and Yuan, X.P., (in review at  Tectonics), Evolution of rift systems and their fault networks in response to surface processes, [preprint], doi: https://doi.org/10.31223/X5Q333

How to cite: Neuharth, D., Brune, S., Wrona, T., Glerum, A., Braun, J., and Yuan, X.: Evolution of rift systems and their fault networks in response to surface processes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5758, https://doi.org/10.5194/egusphere-egu22-5758, 2022.

EGU22-5938 | Presentations | TS6.1

Palaeobathymetric evolution of the Nova Scotia rifted margin during the Central Atlantic Ocean opening 

Julie Tugend, Nick Kusznir, Geoffroy Mohn, Mark Deptuck, Kris Kendell, Fraser Keppie, Natasha Morrison, and Russell Dmytriw

The palaeobathymetric evolution of rifted margins during continental breakup is complex. We investigate the subsidence of Late Triassic to Early Jurassic evaporitic sequences in the proximal and distal parts of the Scotian margin that formed during the opening of the Central Atlantic Ocean.

We use a 3D flexural backstripping technique, which incorporates decompaction and post-breakup reverse thermal subsidence modelling applied to key stratigraphic intervals through the Jurassic down to the Late Triassic base salt. The isostatic evolution of rifted margins depends on crustal thinning, lithosphere thermal perturbation and melt production during rifting and breakup. Quantitative analysis of seismic reflection and gravity anomaly data together with subsidence analysis have also been used to determine crustal thickness variations and ocean–continent transition structure, and to constrain the along strike variability in breakup related magmatism and crustal composition.

Reverse post-breakup subsidence modelling to the Late Triassic base salt restores this horizon at breakup time to near sea level in the proximal domains of the Scotian margin where the continental crust was only slightly thinned during rifting. In contrast, predicted palaeobathymetry of the base salt surface restored to breakup time is greater than 2 to 3 km in the distal parts of the margin where the continental crust was highly thinned (<10km) close to the ocean-continent-transition. One possible interpretation of this is that while the proximal salt underwent post-rift thermal subsidence only, the distal salt was deposited during the latest stage of rifting focused along the distal domains of the Scotian margin, where it underwent additional tectonic subsidence from crustal thinning. This observed difference between the subsidence of proximal and distal salt has been observed elsewhere on the South Atlantic margins (e.g., the Angolan Kwanza margin) and illustrates the complexity of the subsidence and palaeobathymetric evolution of distal rifted margins during breakup.

The deposition of Triassic evaporites occurred before and after the emplacement of the Central Atlantic Magmatic Province (CAMP). The impact of the CAMP on rifting, crustal structure and palaeobathymetric evolution of the Nova Scotia remains to be determined. We do not exclude an additional positive dynamic topography effect at breakup time related to the CAMP magmatic event.

How to cite: Tugend, J., Kusznir, N., Mohn, G., Deptuck, M., Kendell, K., Keppie, F., Morrison, N., and Dmytriw, R.: Palaeobathymetric evolution of the Nova Scotia rifted margin during the Central Atlantic Ocean opening, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5938, https://doi.org/10.5194/egusphere-egu22-5938, 2022.

EGU22-6172 | Presentations | TS6.1

Early Carboniferous rifting in the Southern Urals: New isotopic dating of plutonic and volcanic complexes 

Natalia Pravikova, Alexander Tevelev, Alexey Kazansky, Irina Kosheleva, Ivan Sobolev, Alexandra Borisenko, Egor Koptev, Petr Shestakov, and Jiří Žák

Early Carboniferous igneous rocks are widespread in the Southern Urals. We have obtained new stratigraphic and isotopic data on plutonic and volcanic complexes, allowing us to determine correlation of their age and to construct a new geodynamic model.

The prevailing tectonic setting in the Southern Urals during the Early Carboniferous was sinistral transtension. Volcanic and plutonic complexes in transtensional zones were synchronously formed along large submeridional orogen-parallel strike-slip faults, but are particularly abundant within two N–S-trending zones: Magnitogorsk and East Ural.

The upper Tournaisian–lower Visean sequence in the Magnitogorsk zone consists mainly of moderately alkaline volcanic rocks, basalt and rhyolite are predominant, but pyroclastic, volcano-sedimentary, terrigenous, and carbonate rocks are also widespread. The middle Visean sequence consists of moderately alkaline basalt, andesite, dacite including lavas, tuffs and tuffites. The thickness of the Lower Carboniferous volcanic group varies from 1200 to 5500 m. The age of the volcanic rocks has been proved by findings of foraminifera in limestone interbeds. The oldest volcanic rocks appear in upper Tournaisian, while the youngest are found in the middle upper Visean. New U–Pb zircon dating using SHRIMP is now in progress.

Volcanic rocks in the East Ural zone occur within a few tectonic sheets. The sequence consists of lavas and tuffs of basalt, basaltic andesite, andesite and rhyolite. The total thickness of the sequence varies from 800 to 1500 m. The age of the sequence is determined by findings of fossil plants as middle Visean.

We studied eight plutons in the Magnitogorsk and six in the East Ural zones. Most of them record several intrusive phases. The composition of the rocks varies from gabbro to granodiorites and granites from normal to moderately alkaline series. We combined our new isotopic data on zircons (SHRIMP) with published ages and came to the following conclusions.

  • Two main stages of Early Carboniferous plutonism can be distinguished in the Southern Ural. The first began simultaneously in both zones at the Devonian/Carboniferous boundary (ca. 356–357 Ma) and then changed to volcanic activity at around 346 Ma in the Magnitogosk zone and at around 340 Ma in the East Ural zone, respectively. The second stage began after the termination of volcanic activity and corresponds to 334–327 Ma interval in both zones. So, stages of active volcanism and plutonism alternate in time.
  • Early Carboniferous rifting began with intrusion of plutons, usually associated with transtensional zones under oblique collision. The subsequent volcanic stage corresponds to local extension. The next stage of plutonism began just after volcanism termination and marked a cessation of tectonic activity.

The reported study was funded by RFBR and Czech Science Foundation according to the research project № 19-55-26009. Centre of collective usage ‘Geoportal’, Lomonosov Moscow State University (MSU), provided access to remote sensing data.

How to cite: Pravikova, N., Tevelev, A., Kazansky, A., Kosheleva, I., Sobolev, I., Borisenko, A., Koptev, E., Shestakov, P., and Žák, J.: Early Carboniferous rifting in the Southern Urals: New isotopic dating of plutonic and volcanic complexes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6172, https://doi.org/10.5194/egusphere-egu22-6172, 2022.

EGU22-7155 | Presentations | TS6.1 | Highlight

Geodynamic Drivers of the East African Rift System 

Anne Glerum, Sascha Brune, and Walid Ben Mansour

The East African Rift System (EARS) is the largest active continental rift on Earth. Inherited lithospheric strength variations have played a large role in forming the system’s current geometry. The partly overlapping eastern and western EARS branches encompass the large Victoria continental microplate that rotates counter-clockwise with respect to Nubia, in striking contrast to its neighboring plates.

Both the forces driving rifting in the EARS as a whole and the rotation of Victoria in particular are debated. Whereas some studies largely ascribe the rifting to horizontal mantle tractions deriving from plume-induced flow patterns (e.g., Ghosh et al., 2013), or to more equal contributions of mantle tractions and gravitational potential energy (e.g., Kendall and Lithgow-Bertelloni, 2016), recent work by Rajaonarison et al. (2021) points to a dominant role for lithospheric buoyancy forces in the opening of the rift system. Similarly, other numerical modeling (Glerum et al., 2020) has shown that Victoria’s rotation can be induced through drag of the major plates along the edges of the microplate transmitted along stronger lithospheric zones, with weaker regions facilitating the rotation, without the need for plume-lithosphere interactions (e.g., Koptev et al., 2015; Calais et al., 2006).

With unprecedented data-driven, regional spherical geodynamic numerical models spanning the EARS and the upper 660 km of mantle, we aim to identify the individual contributions of lithosphere and mantle drivers of deformation in the EARS and of Victoria’s rotation. Observational data informs the model setup in terms of crustal and lithospheric thickness, sublithospheric mantle density structure and plate motions. Comparison to separate observations of the high-resolution model evolution of strain localization, melting conditions, horizontal stress directions, topography and horizontal plate motions allows us to identify the geodynamic drivers at play and quantify the contributions of large-scale upper mantle flow to the local deformation of the East African crust.

 

Calais et al. (2006). GSL Special Publications, 259(1), 9–22.

Ghosh et al. (2013). J. Geophys. Res. 118, 346–368.

Glerum et al. (2020). Nature Communications 11 (1), 2881.

Koptev et al. (2015). Nat. Geosci. 8, 388–392.

Rajaonarison et al. (2021). Geophys. Res. Letters, 48(6), 1–10.

How to cite: Glerum, A., Brune, S., and Ben Mansour, W.: Geodynamic Drivers of the East African Rift System, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7155, https://doi.org/10.5194/egusphere-egu22-7155, 2022.

EGU22-7186 | Presentations | TS6.1

Tectonic control on the reef evolution in the Red Sea syn-rift basin 

Tihana Pensa, Abdulkader Afifi, Antoine Delaunay, and Guillaume Baby

Fossil carbonate reefs are common along rifts and rifted passive margins. They provide valuable paleoecological and paleogeographical information. Moreover, porous reef buildups are targeted as potential oil and gas reservoirs and sites for gas storage.

The Red Sea and Gulf of Suez contain several generations of reef deposits: (1) syn-rift Early and Middle Miocene reefs that formed along the eroded footwalls of normal faults, and (2) post-rift Pliocene-Holocene coastal reefs that split apart, subsided, and aggraded to form carbonate platforms by salt-driven raft tectonics. The Late Miocene lacks reefs due to evaporitic conditions. This study focuses on the uplifted Early-Middle Miocene reef deposits, which outcrop sporadically along the Arabian and African margins of the Red Sea, particularly the northern half, over a distance of ~1000 km. They are exhumed along the coastal plain at elevations of 50-150 meters. We studied several reefs on the Arabian side and carried out age determination implementing a revised planktonic foraminifera zonation and paleoenvironmental interpretation. We also used satellite images to identify and map similar exhumed reefs on the African side.

The Miocene reefs are located along the eroded footwalls of normal fault scarps that form the first or second marginal half grabens, usually sitting unconformably over the basement. The flat reef and back-reef lagoonal facies are often removed by erosion, but the dipping thick fore-reef talus breccias are preserved. The breccias are an unsorted mix of coral reef and back reef debris and also contain basement clasts. The linear fore-reef talus deposits follow along the fault scarps, revealing paleo-valleys incised into the hanging wall. Placing the reef on the basin-scale helps us distinguish the tectonic influence, accompanied by climate and eustatic sea-level variation, on shallow marine carbonates during rifting.

Mapping all published, newly discovered, and inferred outcrops along the African and Arabian coast of the Red Sea allow us to develop a new tectono-sedimentary model for reef evolution in the syn-rift setting. The proposed model explains the absence of the reef outcrops in the southern areas of the Arabian Red Sea and predicts subsurface zones where reef growth possibly took place. Nature of the contact between reef carbonates and the underlying Precambrian basement in conjunction with the consistently preserved fore-reef zone disclose the uplift history and erosion events prior and post reef growth. In addition, following the reef distribution, we developed a syn-rift paleogeographic model of the Red Sea.

How to cite: Pensa, T., Afifi, A., Delaunay, A., and Baby, G.: Tectonic control on the reef evolution in the Red Sea syn-rift basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7186, https://doi.org/10.5194/egusphere-egu22-7186, 2022.

EGU22-8003 | Presentations | TS6.1

Evolution of detachment fault systems within necking domains: insights from the Frøya and Gossa Highs, mid-Norwegian margin 

Julie Linnéa Sehested Gresseth, Per Terje Osmundsen, and Gwenn Péron-Pinvidic

Within rifted margins, the necking domain corresponds to the area where drastic reduction in basement thickness leads the crust to attain a wedge-shape. The crustal thinning occurs along detachment fault systems typically recording displacements in the order of 10s of kilometers. These systems commonly shape the crustal taper and eventually the taper break, where crustal thickness is thinned to 10 km or less. In recent years, it has become clear that evolutionary models for detachment fault systems remain unsatisfactory as the well-known principles for smaller magnitude fault systems are not fully applicable to these large-magnitude systems. Consequently, the detailed responses in the foot- and hanging walls and associated basin sedimentation within detachment fault systems and necking domains remain poorly understood compared to those observed in extensional half-graben basins.

We use interpretation of 3D- and 2D seismic reflection data from the Mid-Norwegian rifted margin to discuss the effects of lateral interaction and linkage of extensional detachment faults on the necking domain configuration. We investigate how the structural evolution of these detachment faults interact with the effects of isostatic rollback to produce complex 3D geometries and control the configuration of the associated supradetachment basins. The study area demonstrates how successive incision may induce a complex structural relief in response to faulting and folding. In the proximal parts of the south Vøring and northeastern Møre basins, the Klakk and Main Møre Fault Complexes form the outer necking breakaway complex and the western boundary of the Frøya High. We interpret the previously identified metamorphic core complex within the central Frøya High as an extension-parallel turtleback-structure. The now eroded turtleback is flanked by a supradetachment basin with two synclinal depocenters resting at the foot of the necking domain above the taper break. We attribute footwall and turtleback exhumation to Jurassic-Early Cretaceous detachment faulting along the Klakk and Main Møre Fault Complexes. The study area further demonstrates how detachment fault evolution may lead to the formation of younger, successively incising fault splays locally. Consequently, displacement may occur along laterally linked fault segments generated at different stages in time. Implicitly, the detachment fault system may continue to change configuration and therefore re-iterate itself and its geometry during its evolution.

How to cite: Gresseth, J. L. S., Osmundsen, P. T., and Péron-Pinvidic, G.: Evolution of detachment fault systems within necking domains: insights from the Frøya and Gossa Highs, mid-Norwegian margin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8003, https://doi.org/10.5194/egusphere-egu22-8003, 2022.

EGU22-8663 | Presentations | TS6.1 | Highlight

Spatio-temporal evolution of rift volcanism driven by progressive crustal unloading 

Gaetano Ferrante, Eleonora Rivalta, and Francesco Maccaferri

Continental rifting can be accompanied by a large amount of volcanism, which is often observed to shift from the inside of the rift basin to its flanks and conversely, but the controls on this variability are still unclear. Maccaferri et al. (2014) proposed that elastic stresses under rifts are dominated by gravitational unloading due to the excavation of the graben. According to this model, off-rift volcanism follows the creation of a stress barrier below the rift that drives dikes diagonally away from the rift axis, or stops their ascent altogether so that they get stuck as lower crustal sills. The Maccaferri et al. (2014) model is however based on simplyfied assumptions that need to be relaxed to further test its validity. In particular, the model neglects the effect of the accumulating crustal intrusions on ascending dikes. Here we build on this model to explain the spatio-temporal evolution of rift volcanism in terms of the reorientation of principal stresses in the crust due to the progressive unloading of a rift basin with time. To do so, we extend the dike propagation boundary element code used by Maccaferri et al. (2014) to account for the stresses generated by previously ascended dikes. We find that volcanism in rift zones starts inside the rift depression for small values of basin depth. The deepening of the rift is accompanied by the development of a stress barrier under the basin which deflects ascending dikes, causing a shift of surface volcanism from the inside to the flanks. The intensification of the barrier due to further deepening of the basin promotes the formation of lower crustal sill-like structures that pile up under the rift, shallowing the depth at which magma is injected. This eventually leads to dikes being injected from above the stress barrier, moving surface volcanism back to the axial part of the rift. We compare the results of our model to observations of evolving volcanism and crustal structure for rifts of different graben width and depth.

How to cite: Ferrante, G., Rivalta, E., and Maccaferri, F.: Spatio-temporal evolution of rift volcanism driven by progressive crustal unloading, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8663, https://doi.org/10.5194/egusphere-egu22-8663, 2022.

EGU22-8715 | Presentations | TS6.1

Continental breakup style of Marginal Seas 

Geoffroy Mohn, Jean-Claude Ringenbach, Michael Nirrengarten, Julie Tugend, Anders McCarthy, and Chao Lei

Marginal Seas are extensional basins formed in a convergent setting near active subduction zones. They are characterized by a short life (<25 Ma), as well as unstable and changing directions of seafloor spreading. However, the underlying processes involved in their formation from rifting to seafloor spreading initiation are still debated (supra-subduction convection/extension, slab-pull). This problem is further compounded by the fact that our understanding of continental breakup is primarily derived from the evolution of magma-poor and magma-rich Continent-Ocean Transitions (COT) of the Atlantic margins.

In this contribution, we characterize the tectono-magmatic processes acting during continental breakup by investigating the COT structures of three main Marginal Seas located in the Western Pacific, namely the South China Sea, the Coral Sea and the Woodlark Basin. All three examples formed under rapid extension rates and propagation of seafloor spreading. Although each marginal basin has its uniqueness, we show that these three marginal basins are characterized by a narrow COT (typically <~20 km), documenting the sharp juxtaposition of continental crust against igneous oceanic crust. The COT of the three basins shows that final extension is accommodated by the activity of one major low-angle normal fault. This extension is contemporaneous with important magmatic activity expressed by volcanic edifices, dykes and sills emplaced in the distalmost part of these margins. Such narrow COT suggests that a rapid shift from rifting to spreading.

The rapid localization of extensional deformation in a narrow area has major implications for partial melting generation. The evolution of extensional structures is controlled by the interplay of lithospheric thinning, asthenosphere upwelling and decompression melting. High extension rate prevents conductive cooling and lead to focus volcanic activity in a narrow area evolving rapidly in space and time to magmatic accretion. Causes for the fast extensions rates of Marginal Sea rifting are likely controlled by kinematic boundary conditions directly or indirectly controlled by nearby subduction zones. Such mode of breakup is probably not limited to marginal Seas but only enhanced in such settings.

How to cite: Mohn, G., Ringenbach, J.-C., Nirrengarten, M., Tugend, J., McCarthy, A., and Lei, C.: Continental breakup style of Marginal Seas, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8715, https://doi.org/10.5194/egusphere-egu22-8715, 2022.

Breakup volcanism along rifted passive margins is highly variable in time and space. The factors controlling magmatic activity during continental rifting and breakup are not resolved and controversial. Here we use numerical models to investigate melt generation at rifted margins with contrasting rifting styles corresponding to those observed in natural systems. Our results demonstrate a surprising correlation of enhanced magmatism with margin width. This relationship is explained by depth-dependent extension, during which the lithospheric mantle ruptures earlier than the crust, and is confirmed by a semi-analytical prediction of melt volume over margin width. The results presented here show that the effect of increased mantle temperature at wide volcanic margins is likely over-estimated, and demonstrate that the large volumes of magmatism at volcanic rifted margin can be explained by depth-dependent extension and very moderate excess mantle potential temperature in the order of 50-80 °C, significantly smaller than previously suggested.

How to cite: Lu, G. and Huismans, R.: Melt volume at Atlantic volcanic rifted margins controlled by depth-dependent extension and mantle temperature, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9420, https://doi.org/10.5194/egusphere-egu22-9420, 2022.

EGU22-9480 | Presentations | TS6.1

Permian-Triassic rifts of the West Siberian basin: evidence of voluminous felsic volcanic activity 

Maria Smirnova, Anton Latyshev, Ivan Panchenko, Petr Kulikov, Alexey Khotylev, and Rustam Garipov

Permian-Triassic rifts of the West Siberian basin compose one of the largest continental rift systems in the world. The Koltogor-Urengoy and Khudosey rifts of meridional strike are the main structures in the eastern part of the basin and are filled mainly by basaltic lavas with clastic sediments. However, in the central part of the West Siberian plate felsic lavas are widespread along with mafic volcanics. Here we present the detailed data on composition of lavas, whole-rock geochemistry, geophysical features and U-Pb ages from the Frolov-Krasnoleninsky region in the central part of the West Siberian basin.

Within the studied region, Permian-Triassic rifts of NW and NE strike are predominant. The main structure is Rogozhnikov-Nazym graben of NW strike, composed of rhyolite-dacitic lavas.  According to the seismic data, this volcanic area comprises multiple local eruptive centers (1-5 km in diameter). Lavas constitute the major part of the volcanic pile, while tuffs are subordinate (up to 15%). Deep boreholes did not reach the base of volcanic sequence, but its thickness exceed 0.5 km.

The main geochemical features of the Rogozhnikov-Nazym volcanics are: 1) acidic composition and increased alkali content; 2) signs of supra-subduction setting: Ta-Nb and Pb anomalies; 3) high ratios of all incompatible trace elements. According to these features, volcanic rocks of the Rogozhnikov-Nazym graben were formed in the setting of post-collisional extension. Furthermore, coeval felsic lavas are widespread in smaller structures of the Frolov-Krasnoleninskiy region and demonstrate similar geochemical characteristics.

We obtained 9 U-Pb (SHRIMP) ages from felsic lavas of the Rogozhnikov-Nazym graben and other rift structures. All samples yielded ages in the range from 254±2 to 248.2±1.3 Ma (Late Permian – Early Triassic). Thus, volcanic activity in the Frolov-Krasnoleninsky region was nearly synchronous to the main phase of Siberian Traps magmatism in the Siberian platform.

Volcanic rocks of the Frolov-Krasnoleninsky region constitute rifts of NW strike (mainly felsic lavas, including the Rogozhnikov-Nazym graben) and NE strike (mainly mafic lavas, geochemically similar to the Siberian Traps basalts). We suggest that orientation of rifts inherits two conjugate strike-slip fault systems, which mark the W-E compression during the preceding collisional event in the Early-Middle Permian, and the mechanism of extension is similar to pull-apart model. The contrasting composition of volcanics can be caused by different-depth zones of magma generation.

The Permian-Triassic volcanics are overlain by continental coal-bearing coarse-grained volcanoclastic sediments of the Chelyabinsk Group (Middle Triassic – Early Jurassic). These deposits fill the local depressions in the paleotopography. The Middle Jurassic clastic Tyumen Formation overlays both volcanic rocks and Chelyabinsk Group, covers almost the entire territory of the Frolov-Krasnoleninsky region and marks the initiation of post-rift subsidence in the West Siberian basin.

How to cite: Smirnova, M., Latyshev, A., Panchenko, I., Kulikov, P., Khotylev, A., and Garipov, R.: Permian-Triassic rifts of the West Siberian basin: evidence of voluminous felsic volcanic activity, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9480, https://doi.org/10.5194/egusphere-egu22-9480, 2022.

EGU22-9962 | Presentations | TS6.1

Crustal architecture under the NE Brazil syn-rift basins from receiver functions: Evidence of deep magmatic processes. 

Jordi Julià, Miro Döring, and Thabita Barbosa

NE Brazil is scarred by a number of aborted rift basins that developed from the same extensional stresses that lead to the opening of the South Atlantic. Extension started in Late Jurassic times, with the formation of an AfroBrazilian Depression south of the Patos Lineament, and continued through the Early Berriasian along two NS trending axes of deformation: Recôncavo-Tucano-Jatobá (RTJ) and Gabon-Sergipe-Alagoas (GSA). In the Late Berriasian - Early Barremian, rifting jumped North of the Pernambuco Lineament to progress along the NE-SW trending Cariri-Potiguar (CP) axis. In the Late Barremian, approximately coinciding with the opening of the Equatorial Atlantic, rifting aborted along the RTJ and CP axes and continued along the GBA trend eventually resulting in continental break-up. Extension-related magmatic activity seems to have been restricted to break-up along the marginal basins, although dyke swarms bordering the Potiguar basin (Rio Ceará-Mirim) seem to be associated to early extension stages in NE Brazil and three subparallel dolerite dykes, with K-Ar dates of 105±9 Ma, were inferred indirectly from aeromagnetic and outcrop data East of the RTJ axis. Aiming at better understanding the structure and evolution of the syn-rift basins of NE Brazil, a total of 20 seismic stations were deployed between October 2018 and January 2021 along the CP and RTJ trends. The deployment, funded by the national oil company Petrobras, included both broadband and short-period stations borrowed from the Pool de Equipamentos Geofísicos do Brasil. These stations complemented a number of permanent broadband stations belonging to the Rede Sismográfica do Brasil. Receiver functions were obtained for each of the seismic stations from teleseismic P-wave recordings and S-wave velocity models were developed from their joint inversion with dispersion velocities from an independent tomographic study. In the RTJ basins, our results show that the crust is about 41 km thick and displays a thick (5-8 km) layer of fast-velocity material (> 4.0 km/s) at its bottom; in the Potiguar basin, our results show a thinner crust of about 30-35 km underlain by an anomalously slow (4.3-4.4 km/s) uppermost mantle. We argue that those anomalous layers are the result of syn-rift and/or post-rift magmatic intrusions, which would have had the effect of increasing velocity at lower crustal levels under the RTJ basins and decreasing velocity at uppermost mantle depths under the Potiguar basin. If correct, ou interpretation would imply that, in spite of an overall lack of evidence at shallow levels, deep magmatic processes have played a role in the formation and evolution of the syn-rift basins of NE Brazil.

How to cite: Julià, J., Döring, M., and Barbosa, T.: Crustal architecture under the NE Brazil syn-rift basins from receiver functions: Evidence of deep magmatic processes., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9962, https://doi.org/10.5194/egusphere-egu22-9962, 2022.

EGU22-10866 | Presentations | TS6.1

Backarc rifting as a response to a crustal collapse at the western Gondwana margin: The Triassic tectonic setting of the Sierra Nevada de Santa Marta, Northern Andes of Colombia 

Michael Andrés Avila Paez, Andreas Kammer, Camilo Andres Conde Carvajal, Alejandro Piraquive Bermudez, and Cristhian Nicolas Gomez Plata

Since the middle Triassic the long-lived convergent margin of western Gondwana evolved from a relatively steeply inclined into a flat lying slab setting that combined an extensional regime on the backarc side with the telescoping of crustal slices at the continental margin. In the Northern Andes the opening of Late Triassic basins is practically contemporaneous with the outwedging of lower crustal slices, that often alternate with intrusive sheets of S-type granites and mark the limit to a  non-metamorphic roof. A tectonic coupling between backarc collapse and the escape of lower crustal slices can be examined in detail in the northwestern flank of the Sierra Nevada de Santa Marta, a northern-most outlier of the North Andean basement. Remnants of a Late Triassic graben fill attest here to a block tilted toward the hinterland. Its tri-partite sedimentary sequence recycled material sourced from external parts of the continental margin. The basement of a more foreland-oriented block of the Sevilla belt is affected by outward-verging folds, which have formed under greenschist facies conditions in its upper and lower amphibolite conditions in its lower part. The succeeding Inner Santa Marta Metamorphic Belt consists of a stack of high-grade metamorphic basement slices separated by siliciclastic wedges metamorphosed under lower amphibolite conditions. The soles of the basement slices consist of migmatites with remobilized granitic pods and resulting folds oriented in a dip-slip direction. These structures are overprinted by a flattening and a second migmatitic event, which records peak P-T conditions of a lowest crustal level. Accordingly, they contain inclusions of ultramafic rocks. The time-equivalent correspondence between a supracrustal  backarc extension and a foreland-directed stacking of crustal slices suggests some similarity to the model  of a low-viscosity channel of a thickened orogenic crust. An important difference of this flat-slab setting resides, however, in a wholesale mobility of a strongly heated crust that constitutes the backarc and frontal position of this active margin.

How to cite: Avila Paez, M. A., Kammer, A., Conde Carvajal, C. A., Piraquive Bermudez, A., and Gomez Plata, C. N.: Backarc rifting as a response to a crustal collapse at the western Gondwana margin: The Triassic tectonic setting of the Sierra Nevada de Santa Marta, Northern Andes of Colombia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10866, https://doi.org/10.5194/egusphere-egu22-10866, 2022.

EGU22-11260 | Presentations | TS6.1

Rifted margins classification and forcing parameters 

Francois Sapin

Rifted margins are the result of the successful process of thinning and breakup of continents leading to the formation of new oceanic lithosphere. Observations on rifted margins are now integrating an increasing amount of multi-channel seismic data and drilling of several Continent-Ocean Transitions. Based on large scale geometries and domains observed on high-quality long-offset seismic lines, we illustrate a simple classification based on mechanical behavior and magmatic production. Therefore, rifted margins are not divided into opposing types, but described as a combination and continuum that can evolve through time and space from ductile to brittle mechanical behavior on one hand and from magma-poor to magma-rich on the other hand.

For instance, margins such as the Mauritania-Senegal Basin evolve north to south from a magma-poor to a magma-rich margin. Margins such as the Vøring one suffered different rifting episodes evolving from ductile deformation in the Devonian to more brittle and magma-poor rifting in the Cretaceous prior to a final magma-rich breakup in the Paleogene.

Thanks to these examples and to some others, we show the variability of the rifted margins worldwide but also along strike of a single segment and through time along a single margin in order to explore and illustrate some of the forcing parameters that can control the initial rifting conditions but also their evolution through time.

How to cite: Sapin, F.: Rifted margins classification and forcing parameters, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11260, https://doi.org/10.5194/egusphere-egu22-11260, 2022.

The breakup of Pangaea in Early Mesozoic times initiated first in the Central Atlantic region, where Triassic to Early Jurassic lithosphere extension led to continental breakup and oceanic accretion. The Central Atlantic rifted margins of NW Africa and eastern North America exhibit complex along-strike variations in structural configuration, crustal geometries, and magmatic budget at breakup. Quantifying these lateral changes is essential to understand the tectonic and geodynamic processes that dominated rifting and continental breakup. The existing seismic refraction lines along the African side and its American conjugate provide good constraints on the 2D crustal architecture of several Central Atlantic margins. However, they are insufficient to quantify the ambiguous lateral variations.

This work examines the central segment of the Moroccan Atlantic margin, which is named here the Sidi Ifni-Tan Tan margin. Using 2D seismic reflection and well data, we quantify the stratigraphic and structural architecture of the margin. We then use this to constrain 2D and 3D gravity models, to predict crustal thickness and types. Ultimately, our results are integrated with previous findings from the conjugate Nova Scotia margin, on the Canadian side, to propose a rift to drift model for this segment of the Central Atlantic and discuss the tectonic processes that dominated rifting and decided the fate of continental breakup.

How to cite: Gouiza, M.: Rift to drift evolution and crustal structure of the Central Atlantic: the Sidi Ifni-Nova Scotia conjugate margins, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11336, https://doi.org/10.5194/egusphere-egu22-11336, 2022.

EGU22-11973 | Presentations | TS6.1

Spatial and temporal variation of magmatism in the East African Rift System: influence of tectonics and different mantle domains 

Eleonora Braschi, Simone Tommasini, Giacomo Corti, and Andrea Orlando

The East African Rift System (EARS) is the classic example of an active continental rift associated with extension, deformation, lithosphere thinning, and generation of magmas from different mantle domains and depths. Magmatism and tectonics have always been closely linked and their mutual relationships concern many processes such as the kinematics and rates of extension, the passive versus active role of mantle upwelling and magma genesis. In addition, the spatial and temporal variations of the geochemical signature of magmas varies in response to different mantle domains contributing to their genesis (subcontinental lithosphere, asthenosphere and deeper mantle sources).

In this study we carefully screened an exhaustive geochemical database of basalts (including authors’ unpublished data) emplaced in the EARS to decipher the possible connection between different mantle domains, and the evolution and tectonic characteristics of the EARS. The geochemical data were subdivided according to spatial and temporal criteria: from a spatial point of view, the samples were ascribed to five groups, namely Afar, Ethiopia, Turkana depression, Kenya and Tanzania. From a temporal point of view, the magmatic activity of the EARS was subdivided into three main temporal sequences: 45-25 Ma, 25-10 Ma and 10-0 Ma.

The geochemical signature and radiogenic isotopes (Sr, Nd, Pb) of the selected basalts reveal significant spatial and temporal variations and permits to place important constraints on the contribution of subcontinental lithosphere, asthenosphere, and lower mantle in magma genesis

How to cite: Braschi, E., Tommasini, S., Corti, G., and Orlando, A.: Spatial and temporal variation of magmatism in the East African Rift System: influence of tectonics and different mantle domains, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11973, https://doi.org/10.5194/egusphere-egu22-11973, 2022.

EGU22-12619 | Presentations | TS6.1

Passive margin asymmetry and its polarity in the presence of a craton 

Raghu Gudipati, Marta Pérez-Gussinyé, Miguel Andres-Martinez, Mario Neto-Araujo, and Jason Phipps Morgan

When continental lithosphere is extended to break-up it forms two conjugate passive margins. In many instances, these margins are asymmetric: while one is wide and extensively faulted, the conjugate thins more abruptly and exhibits little faulting. Recent studies have suggested that this asymmetry results from the formation of an oceanward-dipping sequential normal fault array and rift migration leading to the observed geometry of asymmetric margins. Numerical models have shown that fault sequentiality arises as a result of asymmetric uplift of the hot mantle towards the hanging wall of the active fault. The preferential localization of strain reinforced by strain weakening effects is random and can happen on either conjugate. However, along the long stretch of the South Atlantic margins, from the Camamu-Gabon to the North Santos-South Kwanza conjugates, the polarity can be very well correlated with the distance of the rift to nearby cratonic lithosphere. Here, we use numerical experiments to show that the presence of a thick cratonic root inhibits asthenospheric flow from underneath the craton towards the adjacent fold belt, while flow from underneath the fold belt towards the craton is favoured. This enhances and promotes sequential faulting and rift migration towards the craton and resulting in a wide faulted margin on the fold belt and a narrow conjugate margin on the craton side, thereby determining the polarity of asymmetry, as observed in nature.

How to cite: Gudipati, R., Pérez-Gussinyé, M., Andres-Martinez, M., Neto-Araujo, M., and Phipps Morgan, J.: Passive margin asymmetry and its polarity in the presence of a craton, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12619, https://doi.org/10.5194/egusphere-egu22-12619, 2022.

EGU22-12955 | Presentations | TS6.1

Relative continent/mid-ocean ridge elevation: a reference case for isostasy in geodynamics 

Thomas Theunissen, Ritske S. Huismans, Gang Lu, and Nicolas Riel

The choice of crustal and mantle densities in numerical geodynamic models is usually based on convention. The isostatic component of the topography is, however, in most if not all cases not calibrated to fit observations resulting in not very well constrained elevations. The density distribution on Earth is not easy to constrain because it involves multiple variables (temperature, pressure, composition, and deformation). We provide a review and global analysis of the topography of the Earth showing that elevation of stable continents and active mid-ocean ridges far from hotspots on average is +400 m and -2750 m respectively. We show that density values for the crust and mantle, commonly used for isostatic modeling result in highly inaccurate prediction of topography. We use thermodynamic calculations to constrain the density distribution of the continental lithospheric mantle, sub-lithospheric mantle, the mid-ocean ridge mantle, and review data on crustal density. We couple the thermo-dynamic consistent density calculations with 2-D forward geodynamic modelling including melt prediction and calibrate crustal and mantle densities that match the observed elevation difference. Our results can be used as a reference case for geodynamic modeling that accurately fits the relative elevation between continents and mid-ocean ridges consistent with geophysical observations and thermodynamic calculations. 

How to cite: Theunissen, T., Huismans, R. S., Lu, G., and Riel, N.: Relative continent/mid-ocean ridge elevation: a reference case for isostasy in geodynamics, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12955, https://doi.org/10.5194/egusphere-egu22-12955, 2022.

EGU22-13043 | Presentations | TS6.1

Characterizing mantle deformation processes during the rift-to-drift transition at magma-poor margins 

Nicholas Montiel, Emmanuel Massini, Luc Lavier, and Othmar Müntener

A holistic understanding of rift initiation, evolution, and variation is made complicated by the difficulties of deep seismic imaging, limited modern examples of continental rifting, and few accessible outcrops of fossil rifted margins. In particular, The temporal structural and rheological evolution of the mantle lithosphere during riftingis poorly constrained. The mantle lithosphere rheology controls lithospheric strength at initiation, but how deformation is partitioned between the crust and mantle,  and how the paths for melt migration from the asthenosphere to the rift surface evolve during rifting is fundamental for our understanding of the rift-to-drift evolution .
Here, we use elastoplastic-viscoelastoplastic modeling in concert with published deep seismic profiles of Atlantic rifted margins and geological insights from the Lanzo peridotite outcrops in the Alps to propose a new mode of extensional tectonics in the subcontinental mantle. We run a series of dynamic models varying initial conditions and mechanisms of deformation localization in the mantle lithosphere consistent with mechanisms of ductile shear zone formation observed at slow spreading centers. Models and geophysical surveys show homologous, sigmoidal reflectors in the mantle, a reversal of fault vergence as seafloor spreading develops, exhumation of the mantle, and increasing magmatic accretion. Geological evidence, along with the coincidence of magmatic accretion and extensional structures in the mantle, suggests that faults in the mantle may serve as conduits for melt, resulting in bright reflectors on seismic profiles.

How to cite: Montiel, N., Massini, E., Lavier, L., and Müntener, O.: Characterizing mantle deformation processes during the rift-to-drift transition at magma-poor margins, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13043, https://doi.org/10.5194/egusphere-egu22-13043, 2022.

EGU22-123 | Presentations | TS6.2

Geodetic evidence of anomalous WSW displacement and salt tectonic evolution of the Essaouira Onshore, Atlantic High Atlas (Morocco) 

Khalid Lakhouidsi, Abdelali Fadil, and Abderrahmane Soulaimani

The Geodetic observations derived from eight years (2010-2018) of the Essaouira continuous GPS station have revealed a WSW horizontal displacement of 3mm/year and an active uplift of 1mm/year relative to the Nubian Plate, which characterizes this basin than the other Moroccan coastal region. Even if this basin's vertical movements (subsidence) have been geologically described, the GPS data analysis method made it possible to calculate the vertical movement velocity with high accuracy. At the same time, the horizontal movement has never been described in the literature. Combining geophysical and geological data allows us to identify and explain the main probable factors behind these abnormal movements. Even this movement may result from the reactivation of pre-existing faults as part of the post-breakup evolution of the Atlantic passive margin, or it could be the result of a local process such as salt tectonics.

Keywords; GPS, Atlantic margin, Essaouira, uplift, WSW displacement, Salt tectonics

How to cite: Lakhouidsi, K., Fadil, A., and Soulaimani, A.: Geodetic evidence of anomalous WSW displacement and salt tectonic evolution of the Essaouira Onshore, Atlantic High Atlas (Morocco), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-123, https://doi.org/10.5194/egusphere-egu22-123, 2022.

The Luconia-Balingan Provinces are sedimentary basins in Sarawak, Malaysia that presently extends from offshore to onshore, along major NW-SE faults on both sides of the basins. It was formed by several rifting episodes of the Southern China Block, followed by spreading since Eocene. The rifting coeval with the closure of an ancient oceanic crust that induced compression and major uplift in the southern part of the basins. The basins are filled by up to more than 10 km of Cenozoic sediments overlying the Cathaysian derived crystalline basement. Since the Upper Eocene-Oligocene to Upper Miocene, warm-water to tropical carbonate sedimentation has been dominating the stratigraphy mainly in Luconia. To understand the sediment and tectonic subsidence evolution of the Luconia-Balingian Provinces this study analysed data from exploration wells using a Matlab-based open-source tool, the BasinVis 2.0. Updated compaction trend from three different wells to represent the southern-central-north regions of the provinces are adopted. The subsidence history for Luconia-Balingian provinces can be divided into five stages; (i) 37 to 23 Ma: Steadily increase in subsidence is recorded with higher tectonic subsidence rate in the central and west of Luconia-Balingian and moderate tectonic subsidence in the north and south. (ii) 23-18 Ma: Increase in tectonic subsidence for most parts of Luconia-Balingian with slight decrease in total tectonic subsidence recorded in some of the wells. (iii) 18 to 15.5 Ma: Delayed subsidence within the central and northern parts of Luconia-Balingian, coincide with the diachronous timing of Middle Miocene Unconformity. There was minor uplift in the northern section. However, the southern part experienced increased in the total and tectonic subsidence rates. (iv) 15.5 to 11.8 Ma: Overall decrease in tectonic subsidence rate, coinciding with the prolific growth of Middle to Upper Miocene carbonate build-ups. (v) 11.8 to 0 Ma: Increase in tectonic subsidence rate particularly in the wells within the southern part of Luconia-Balingian. Stretching factors ranges between 1.3 to 1.95 are recorded, indicative for foreland basin setting with a very strong influence from the syn- and post-rift phases. It directly related to the effect of extensional tectonics during the South China Sea opening and compressional tectonics during the closure of the proto-South China Sea during the Cretaceous-Eocene, until Middle Miocene. Through this study, accurate subsidence rates are deduced and allows specific characterization of tectonic influences in different parts of Luconia-Balingian at different stages of basin development.

How to cite: Jamaludin, S. N. F., Pubellier, M., and Madon, M.: Variation in Cenozoic tectonic subsidence in Luconia-Balingian provinces, Sarawak Basin, Malaysia: influence of extensional and compressional tectonics, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-783, https://doi.org/10.5194/egusphere-egu22-783, 2022.

As the most important hydrocarbon-rich area of Wenchang A sag of Pearl River Mouth Basin, the Wenchang 9/8 area has attracted more scientific attention in fault-related hydrocarbon reservoirs. Here, we employ 2D and 3D seismic data and syn-rifting fault maps to analyze the fault characteristics and evolution of Wenchang 9/8 area, and its response to clockwise rotation of regional extension stress in northern margin of South China Sea. The results demonstrate that three NE- and NW-striking fault belts developed in Wenchang 9/8 area during Cenozoic, respectively. The pre-existing NE- and NW-striking basement faults and clockwise rotation of regional extension stress influenced the evolution of fault system in this area. During Paleocene to Eocene, the NE-striking sag-controlling faults activate intensively, under the control of NW-SE-directed extension. The extension was derived from the NW-direction subduction retreat of Pacific Plate, and the extension direction is perpendicular to pre-existing NE-striking faults, which resulted in the reactivation of the pre-existing NE-striking faults and the formation of the new NE-striking secondary normal faults. During Oligocene to early Miocene, the fault activity of the NE-striking sag-controlling faults weaken rapidly, resulting in segment activate and generate three NE-striking fault belts. These NE-striking fault belts were consisted of a series of new E-W-striking secondary transtensional faults. And the three NW-striking fault belts were started to reactivate in the form of abundant E-W-striking secondary transtensional faults, which were influenced by oblique extension. The characteristics of fault system indicated that N-S-directed extension worked on the study area, and the extension stress shifted clockwise from NW-SE to N-S during this stage. The clockwise rotation of the extension was believed related with the India-Eurasian collision and southern ward subduction of the Proto-South China Sea block. During middle Miocene to present, the NE-striking fault belts stopped. While the NW-striking fault belts activate continually, and each fault belts were consisted of a series of newly-formed NWW-striking secondary transtensional faults distributed in en-echelon. The NWW-striking secondary transtensional faults were formed under the control of NNE-SSW-directed extension, which influenced by regional extension stress further clockwise rotate to NNE-SSW direction. This extension was derived from the Philippine Sea Plate NWW-direction obduction, which leading to arc-continent collision at Taiwan Island, while giving rise to the NNE-SSW-directed extension at Pearl River Mouth Basin. Cenozoic evolution of fault system in Wenchang 9/8 area, Pearl River Mouth Basin revealed by this study not only provides guidance for petroleum exploration, but also affords implication for the research on tectonic stress field in northern margin of South China Sea.

How to cite: Xu, B., Wu, Z., Cheng, Y., Xu, L., and Sun, W.: Cenozoic faults evolution of Wenchang 9/8 area in Pearl River Mouth Basin, and the response to clockwise rotation of regional extension stress in northern margin of South China Sea, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3305, https://doi.org/10.5194/egusphere-egu22-3305, 2022.

EGU22-3488 | Presentations | TS6.2

The effect of inheritance, rheology, and stress orientation on the 4-D evolution of rift systems 

Mohamed Gouiza, Athanasia Vasileiou, and John Naliboff

Continental rifts often show a complex spatial and temporal evolution, controlled by the intricate interaction of several ingredients. Inheritance, plate rheology, and stress orientation are amongst the main factors that shape rifts and dictate their fate. In this contribution, we use observations from two rift systems – i.e., the Labrador Sea and the Atlas System – to constrain 3D geodynamic models and assess the role of inherited structures, rheological heterogeneities, stress field (re-) orientation and obliquity on rift evolution.

The Labrador Sea formed as a branch of the North Atlantic Ocean, which propagated across major Precambrian suture zones. The subsequent rifted margins show striking lateral changes in the structural architecture, the crustal geometry, and the magmatic budget during breakup. Our geophysical data analysis and 3D geodynamic models suggest that pre-rift rheological changes in the lithosphere (i.e., composition, thickness, and thermal structure) dominated the rifting process and the ensuing continental breakup.   

The Atlas fold and thrust belt is a failed rift system that evolved in Mesozoic times and was inverted in the Cenozoic. The rifting phase was driven by two concurrent extensional stress fields linked to the coeval opening of two highly oblique oceans: the Central Atlantic and the Tethys. Here, our 3D geodynamic models constrained by field observations highlights the importance of the pre-rift structural template in dictating the strain distribution/localization, the lithospheric extension mode (i.e., orthogonal rifting vs. transtension), and the location of magmatism.

How to cite: Gouiza, M., Vasileiou, A., and Naliboff, J.: The effect of inheritance, rheology, and stress orientation on the 4-D evolution of rift systems, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3488, https://doi.org/10.5194/egusphere-egu22-3488, 2022.

Abstract: The superimposition relationship of the multi-stage tectonic evolution of the Mesozoic and Cenozoic controls the development process and formation mechanism of buried hills. The formation of Yidong buried hill includes two stages: the hill-forming period and the burial period. The hill-forming period was mainly controlled by three groups of faults in the NW-, NE- and NEE-striking, and the burial period was mainly controlled by the regional geological background of the NNW-SSE extension since the Cenozoic. According to the method of equilibrium profile and active fault analysis, the matching relationship between different buried hills in Yidong area is determined, and then the buried hills in Yidong area are divided into four categories: (1) Yigu 271 buried hill, its formation went through the NW-striking fault-controlled hill in the Mesozoic hill-forming period, the NE-striking fault-controlled hill in the Paleogene hill-forming period, and the Neogene-Quaternary buried period. (2) Yigu 103 buried hill, its formation was controlled by NW-striking faults in the Mesozoic hill-forming period, NE-striking faults in the Kongdian Formation- the third member of Shahejie Formation hill-forming period, and NW-striking and NE-striking faults in the first member of Shahejie Formation-Dongying Formation period. Controlled together into hills, and the Neogene-Quaternary buried period. (3) Yigu 20 buried hill, its formation was controlled by NW-striking faults in the Mesozoic hill-forming period, the Kongdian Formation-Essential Formation NW-striking and NE-striking faults in the hill-forming period jointly controlled the hills, and the third member of Shahejie Formation-Dongying Formation was NE-striking in the hill period The fault is controlled into a hill, and the Neogene-Quaternary buried period. (4) Shaogu 3 buried hill, it was formed in the Paleogene hill-forming period, NE-striking and NEE-striking faults jointly controlled the hill, and the Neogene-Quaternary buried period. The research on the development and superimposition process of Yidong buried hill provides important support for the study of tectonic evolution in Yidong area.

How to cite: Miao, Y., Wu, Z., and Zhang, M.: The control of the superimposition effect of the original tectonic framework in different tectonic evolution stages on the development and transformation of buried hills- Taking Yidong Buried Hill in Jiyang Depression as an Example, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4073, https://doi.org/10.5194/egusphere-egu22-4073, 2022.

EGU22-4514 | Presentations | TS6.2

Granitic batholith emplacement mechanism in a transtensional setting: petromagnetic evidence from the Southern Urals 

Egor Koptev, Alexey Kazansky, Alexander Tevelev, Alexandra Borisenko, Natalia Pravikova, and Jirí Zák

Introduction. The Nepluyevka pluton is the Early Carboniferous polyphase batholith situated in the East Ural zone. The batholith is subdivided into 4 phases ranging from basic to felsic in composition. The pluton formed during the Early Sudetian orogenic phase of the East Ural zone, which was characterized by a complex alternation of pure and sub-simple shear kinematic settings over its’ duration. Evidently, this alternation was connected with changes in the kinematics of the subduction zones preceding the Late Visean collision of Laurussia and Kazakhstania. These transformations had defined the characteristic features of the tectono-magmatic evolution of the southern part of the East Ural zone. Thus, their investigation is crucial for improving our understanding of the geological history of the Southern Urals.

Methods and materials. We have investigated anisotropy of magnetic susceptibility (AMS) and magnetic mineralogy of the rocks of the Nepluyevka batholith to gain insights into the circumstances of its’ formation and its’ deformation history. Totally 186 oriented specimens from 16 sites spread over all the phases of the pluton were collected. MFK-1A kappa-bridge was used to measure MS and AMS, temperature dependencies of induced magnetization were studied with Curie balance, magnetic hysteresis loops were obtained on J_meter coercivity spectrometer.

Results. The specimen appeared to contain PSD high-Ti magnetite (magmatic), MD low-Ti magnetite (hydrothermal), as well as the minerals of goethite and maghemite-hematite series.

The AMS data tells the history of the formation and structural evolution of the batholith. Gabbro (1st phase) and granodiorites (2nd phase) in the center of the pluton are characterized by prolate magnetic fabrics. Lineation there is steep to sub-vertical and marks the flow direction near the feeder shared by both phases. Granodiorites (2nd phase) in the north and adamellites (3rd phase) in the north and the south of the pluton are characterized by predominantly oblate, flat-dipping fabrics, corresponding to lateral spreading of the melt. The magnetic fabrics of the adamellites (3rd phase) near the pluton’s southern boundary are oblate and dip steeply in the SW direction, marking the melt flowing parallel to the contact. The magnetic fabrics of the adamellites in the NE part of the batholith are similarly oblate and subparallel to the contact.

Discussion. We propose the model of “magmatic duplex” for the formation of the pluton. The upper-crust transtensional structure associated with a sinistral strike-slip fault was draining the lower-crust magma chamber. Due to the fractionation and assimilation of the chamber’s wall material, it was supplying increasingly felsic melt. Formation of the first two phases was controlled mainly by the central feeder. The 3rd phase adamellites intruded two weakened contact zones of the pluton as the transtensional structure continued to grow sub-longitudinally. The pluton has experienced secondary heating and some metasomatic alteration, but no significant deformations occurred.

Financial support. The research has been funded by RFBR and CNF as a part of the research project № 19-55-26009 with the use of materials of the "Geoportal" Center of the Lomonosov Moscow State University.

How to cite: Koptev, E., Kazansky, A., Tevelev, A., Borisenko, A., Pravikova, N., and Zák, J.: Granitic batholith emplacement mechanism in a transtensional setting: petromagnetic evidence from the Southern Urals, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4514, https://doi.org/10.5194/egusphere-egu22-4514, 2022.

Abstract: To clarify the relationship between the complexity of the fault network systems and hydrocarbon migration in petroleum basin, 3D seismic data and hydrocarbon migration data from T50, T60 and T70 horizon in Wenchang 9/8 area were analyzed. The complexity and connectivity of the fault network system at different horizons in Wenchang 9/8 area are quantitatively characterized based on the topology and fractal theory. The relationship between the distribution characteristics of the complexity of the fault network system and hydrocarbon migration at different horizons in Wenchang 9/8 area was revealed combined with hydrocarbon migration data in typical zones. It indicates that the fractal dimension high value areas, and the topological high value areas and hydrocarbon migration area shave a good coupling relationship in the fault network system. The results showed that: there has a good coupling relationship among the fault interaction zone (fracture tip, structural transition zone, etc.), the fractal dimension high value areas and the topological high value areas. The peak values of the number of nodes (Nc) in T50, T60 and T70 horizons are in the range of 1-2, 6-8 and 5-7, respectively. The peak values of the fractal dimension (D) in T50, T60 and T70 horizon are among 1.4-1.6, 1.6-1.8 and 1.5-1.8, respectively. There is a good coupling relationship between fault interaction zone and hydrocarbon migration zone. Comparing with other structural area, the fault interaction zone has higher topological value and fractal dimension value. The topological high value area has good connectivity, and the fractal high value area has more faults, which is conducive to the formation of fault traps. Therefore, the overlapping zone with high topological value and high fractal dimension value are the dominant channels for oil and gas migration, which are favorable for the formation of favorable oil and gas reservoirs.

How to cite: Ma, S., Wu, Z., and Wang, D.: Topological structure, fractal characteristic of fault network system and their relationship with hydrocarbon migration:Taking Wenchang 9/8 area in the Pearl River Mouth Basin as an example, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4708, https://doi.org/10.5194/egusphere-egu22-4708, 2022.

EGU22-5019 | Presentations | TS6.2

Correlating deformation events onshore and offshore in superimposed rift basins: the Lossiemouth Fault Zone, Inner Moray Firth Basin, Scotland 

Alexandra Tamas, Robert E. Holdsworth, John R. Underhill, Dan M. Tamas, Edward D. Dempsey, Dave McCarthy, Ken J.W. McCaffrey, and David Selby

The separation and characterisation of different deformation events in superimposed basins can be challenging due to the effects of overprinting and/or fault reactivation, combined with a lack of detailed geological or geophysical data. This study shows how an onshore study can be enhanced using a targeted interpretation of contiguous structures offshore imaged by seismic reflection data.

Two deformation events, including unambiguous evidence of fault reactivation, are recognised in the onshore part of the Lossiemouth Fault Zone (LFZ), southern-central Inner Moray Firth Basin. The basin is thought to record a history of (possibly) Permian to Cenozoic deformation, but it is commonly difficult to conclusively define the age of faulting and fault reactivation. However, structures in Permo-Triassic strata onshore outcrops show no evidence of growth geometries and new interpretation of seismic reflection profiles offshore reveals that Permo-Triassic fills are widely characterised by subsidence and passive infill of post-Variscan palaeotopography. We propose that sequences of reactivated faulting observed onshore and offshore can be correlated and can be shown in the latter domain to be early Jurassic-late Cretaceous, followed by localised Cenozoic reactivation. The workflow used here can be adapted to characterise deformation events in other superimposed rift basins with contiguous onshore surface-offshore subsurface expressions.

How to cite: Tamas, A., Holdsworth, R. E., Underhill, J. R., Tamas, D. M., Dempsey, E. D., McCarthy, D., McCaffrey, K. J. W., and Selby, D.: Correlating deformation events onshore and offshore in superimposed rift basins: the Lossiemouth Fault Zone, Inner Moray Firth Basin, Scotland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5019, https://doi.org/10.5194/egusphere-egu22-5019, 2022.

EGU22-5134 | Presentations | TS6.2

Structural development and heat storage potentials in the east-central Upper Rhine Graben (SW Germany): Constraints from 3D-seismic and borehole data 

Florian Bauer, Jens Carsten Grimmer, Ulrich Steiner, Dominik Gudelius, Lars Houpt, Thomas Hertweck, and Eva Schill

The Upper Rhine Graben (URG) has shown multiple geopotentials during the past century: hydrocarbons have been produced mainly from porous, but also from fractured Cenozoic-Mesozoic reservoirs. Fractured Mesozoic and Paleozoic rocks comprise important geothermal reservoirs that are currently exploited in the URG. Heat storage is a new geopotential under consideration for the KIT Campus North, approximately 10 km north of the city of Karlsruhe, south-west Germany. For spatio-temporal structural analysis, volume calculation, well-path planning and thermo-hydraulic modelling the 3D-structure of the subsurface down to a depth of about 4 km is crucial. We used available 3D-seismic and borehole data for structural analysis, quantification of formation thicknesses and the geometry of sedimentary successions. Significant fault shadows occur at depths greater than 1.5 km in the footwall of major faults and reduce the reliability of their location but still give a good image of faults and their respective displacements.

Sandstone-bearing Cenozoic graben-filling sedimentary successions that previously were exploited for hydrocarbons are currently investigated for their heat storage potential of excess heat. Additionally, fractured Mesozoic and Paleozoic rocks are considered for deep geothermal heat supply. Cenozoic reservoir rocks dip approximately 5° to the East. The studied area is dominated by the two major (N)NE-(S)SW-striking Leopoldshafen and Stutensee growth faults showing displacements of several hundred meters. Major syndepositional normal faulting along the Leopoldshafen fault occurred during early Miocene (Hydrobia beds, Landau Formation). Increase of syn-tectonic sedimentary thicknesses from East to West indicate graben-interior migration of fault activity with time. In the hanging wall of the Stutensee fault shallow-rooted, ENE-dipping en-echelon normal faults, linked by relay ramps, and small NNW-striking graben structures displace Cenozoic strata by several tens of meters, but apparently do not cut the respective major fault, indicating that both minor and major faults were either concomitantly active or that major faults postdate minor fault activity. While the minor faults root in older Tertiary successions, both the Stutensee and the Leopoldshafen Fault are rooting in the crystalline basement of yet unknown petrographic composition. A slip and dilatation tendency analysis was performed to reduce the risk of induced seismicity for well-path planning on basis of published stress models, drilling induced tensile fracture analysis, and borehole breakouts of deep borehole data comprising Mesozoic strata and on borehole breakouts in the Cenozoic successions. The maximum horizontal stress direction (SH) trends N-S, resulting in a relatively high potential for both (oblique) normal fault slip and dilation and hence for relatively high geothermal potentials in the deep subsurface.

How to cite: Bauer, F., Grimmer, J. C., Steiner, U., Gudelius, D., Houpt, L., Hertweck, T., and Schill, E.: Structural development and heat storage potentials in the east-central Upper Rhine Graben (SW Germany): Constraints from 3D-seismic and borehole data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5134, https://doi.org/10.5194/egusphere-egu22-5134, 2022.

EGU22-5946 | Presentations | TS6.2

Formation history of the Cheka pluton of alkaline granitoids (Southern Urals): fracture analysis 

Petr Shestakov, Alexandr Tevelev, Natalia Pravikova, Ekaterina Volodina, Alexandra Borisenko, Alexei Kazansky, and Egor Koptev

Introduction. Fracture analysis of rock formations allows us to reconstruct formation history and structural development of magmatic blocks. This study investigates the Cheka block of alkaline granitoids (Southern Urals, Chelyabinsk Oblast). The objective of this study was to evaluate the main deformation characteristics of the sincollisional Cheka block (pluton). For this purpose, stress fields were reconstructed.

The Cheka pluton is composed of the Cheka Mountain and has a meridional strike and dimensions of 6.5 km long and 1-2 km wide. The pluton is composed of alkaline rocks of three intrusion phases: first – monzodiorites, second – alkaline syenites, third – alkaline granites and granosyenites. The pluton is Triassic and intrudes Carboniferous volcanics. The western contact of the Cheka pluton is limited by a dextral fault. The pluton is situated in the Magnitogorsk zone.

During the formation of the pluton, extension changed to compression. This led to formation of a right-lateral transpression setting with a system of meridional strike-slip and near-slip extension zones.

Materials and methods. Space images show several fracture systems with approximate strike lengths: -20° and 310°. During the field work more than 180 fracture orientations were measured Samples were taken for petro- and paleomagnetic, geochemical investigations, and isotope dating at five locations.

The Stereonet v.11.3.0 software was used to analyse the fractures. Schematics (Mohr circles) with fracture poles were created for each location. From these, five swarms of poles with Kamb contours were extracted, showing the statistical concentration of the poles. At locations 701 and 702, three swarms of sub-perpendicular poles were most clearly observed and interpreted as a system of tectonic fractures. The S, Q, and L fractures were identified among the prototectonic fractures based on the relation to linearity and pluton contacts. All the poles that fell within these three swarms were treated as prototectonic, while remaining locations outside these zones were treated as a system of fractures of tectonic origin. Numerous fractures, which are not part of the described systems, are most likely random and require more detailed research.

Results and discussion. A series of vertical fractures, arranged in a pattern relative to each other, were considered. Based on these swarms, a deformation model was built, and the directions of tension and compression were determined. Sub-horizontal compression was oriented northeastward, resulting in the formation of sub-meridional right-lateral shear and a general right-lateral transpression setting. The predominant fractures were synthetic P (according to Riedel), and they are also the most pronounced geomorphologically and on satellite images. Less pronounced are synthetic R and antithetic R' fractures.

This study of the Cheka pluton made it has possible to separate two fracture systems. These systems point to right-lateral transpression, which confirms the model of the massif formation as a shear magmatic duplex.

Financial support. The reported study was funded by RFBR and Czech Science Foundation according to the research project № 19-55-26009. Centre of collective usage ‘Geoportal’, Lomonosov Moscow State University (MSU), provided access to remote sensing data.

How to cite: Shestakov, P., Tevelev, A., Pravikova, N., Volodina, E., Borisenko, A., Kazansky, A., and Koptev, E.: Formation history of the Cheka pluton of alkaline granitoids (Southern Urals): fracture analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5946, https://doi.org/10.5194/egusphere-egu22-5946, 2022.

EGU22-9494 | Presentations | TS6.2

Rifting in the Red Sea – insights into the rift architecture from geophysical data 

Ran Issachar, Jörg Ebbing, Yixiati Dilixiati, and Ángela María Gómez-García

Conjugate margins along mature oceans indicate two end-member types of rifted margins, distinguished by their crustal architecture, e.g. the Iberia-Newfoundland and Central South Atlantic. Numerical simulations and analogue models show that these types could be explained by rheology, state of stress (depth depended) and role of magmatism (magma assisted). The Red Sea is a young rift, offering the opportunity to study early break-up conditions and to relate them to the architecture and the type of passive margins. The morphology of the Red Sea indicates variability and dissimilarities between its southern and northern regions, nevertheless, the lithospheric structure of the rift remains elusive, mainly due to lack of high-resolution direct geophysical measurements, e.g. seismic profiles.

In this study, we explore the deep architecture of the Red Sea rift using geophysical data, in particular gravity and magnetic data, and constraints from seismic interpretations, receiver functions and tomographic models. We present a 3D structural and density model for the Red Sea, including the African and Arabian shoulders down to 120 km depth. The model includes four main sections: sediments, crystalline crust (continental and oceanic), lithospheric mantle (including a thermal gradient) and a uniform asthenosphere. In order to test different scenarios, we evaluate combinations of (1) exhumed continental mantle lithosphere (Type I margin) versus wide/ultrawide continental crust (Type II margin), and, (2) limited versus extended distribution of oceanic crust. The 3D gravity model favors Type II architecture and limited oceanic crust in the southern-central parts of the Red Sea rift. In the northern parts, the model cannot distinguish between the pre and post break-up stages.

How to cite: Issachar, R., Ebbing, J., Dilixiati, Y., and Gómez-García, Á. M.: Rifting in the Red Sea – insights into the rift architecture from geophysical data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9494, https://doi.org/10.5194/egusphere-egu22-9494, 2022.

The Qinling Orogenic Belt (QOB) has been well documented that it was formed by multiple steps of convergence and subsequent collision between the North China Block (NCB) and South China Block (SCB) during the Paleozoic and Late Triassic. Following the collision in the Late Triassic, the whole QOB evolved into an intracontinental orogeny. Large-scale N-S compressional and thrusting deformation tectonics along the previous major boundary faults were developed. Meanwhile, several extension-related tectonics were also developed in the QOB during or slightly later than the compression. However, the expiry date of the Late Mesozoic intracontinental compression orogeny and the tectonic transformation of the QOB remains unclear.

The extensional shear zone developed in the West QOB provides a crucial clue for revealing the orogenic belt's tectonic transformation and uplift and exhumation process. This paper focuses on kinematics, geochronology, and deformation temperature of the Taibai shear zone in the west QOB (TBSZ) to understand the intracontinental orogenic evolutionary process of the QOB.

The Taibai shear zone was developed at the northwestern margin of the Taibai pluton. It cuts across the QOB and separates the Taibai pluton in the east from the Baoji pluton in the west. The NE–NEE-striking and NW–NNW-dipping TBSZ is an extensional shear zone showing a top-to-the-NW sinistral shear sense. Mineral deformation characteristics and two-feldspar geothermometers constrain that the TBSZ was formed under the high greenschist–low amphibolite facies conditions (300-550 ℃) in the middle-upper crust (8-15 km). Zircon U-Pb dating and biotites and muscovites 40Ar-39Ar dating analysis suggest that the TBSZ was formed and uplifted rapidly during 120-113 Ma.

Combined with the regional geological data, the TBSZ records the extensional collapse of the Late Mesozoic intracontinental orogenic belt during the 120–113 Ma. The TBSZ also led to the rapid uplift and exhumation of the Taibai pluton and the North Qinling Belt in the east.

How to cite: Zhang, L. and Li, W.: Structural and geochronological constraints on a Late Mesozoic extension event in the West Qinling Orogenic Belt, China, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11808, https://doi.org/10.5194/egusphere-egu22-11808, 2022.

EGU22-13226 | Presentations | TS6.2

Fractal dimension of fault systems and its constranits on the formation of gold deposit in Kalamaili area, Eastern Junggar 

Wenjie Sun, Zhiping Wu, Yanliang Jiang, and Yanjun Cheng

Kalamaili area is located in the northeastern margin of Junggar Basin, which recognized as the richest gold deposit area of China. The fault systems and the fractal dimension of the area are complex and play a significant control on the deposits of the gold mine. However, the fractal dimension of the study area has not been carried out, and the previous studies lack of the analysis on the relationship between the fractal dimension of fault systems and the distribution of the gold deposit. Therefore, further studies on the fractal dimension of fault systems and its constranits on the formation of gold deposit in Kalamaili area are needed. In our study, we used the box-counting method to analyze the fractal dimension of fault systems, and correlate the relationship between the fractal dimension of fault systems and the formation of gold deposit. The results show that: (1) The fractal dimension of all faults is 1.421, and faults with different strike have various fractal dimension. In detail, the fractal dimension of NW-striking faults is 1.382, fractal dimension of NWW-striking faults is 1.223, fractal dimension of the EW-striking faults is 0.998, and the fractal dimension of the NE-striking faults is 0.960. The fractal dimension values of NW-striking faults are greater than the standard value of fractal dimension (1.22-1.38). (2) Based on the fractal dimension analysis of the fault systems, the geological bodies distributed along the NW-striking faults should have good connectivity, which improve the migration and accumulation of the gold mineralization hydrothermal fluid. The supposed relationship between the NW-striking faults and the gold deposit distribution of our study is coincided with the nature examples of the study area. Based on the exploration of the gold deposit in the study area, most of the gold deposit is distributed along the NW-striking Kalamaili fault, Qingshui-Sujiquan fault, and the associated secondary faults of the two faults.

How to cite: Sun, W., Wu, Z., Jiang, Y., and Cheng, Y.: Fractal dimension of fault systems and its constranits on the formation of gold deposit in Kalamaili area, Eastern Junggar, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13226, https://doi.org/10.5194/egusphere-egu22-13226, 2022.

EGU22-542 | Presentations | TS6.3 | Highlight

Structural inversion of sedimentary basins: insights from 3D coupled thermo-mechanical and surface processes models and observations from the Mediterranean 

Éva Oravecz, Attila Balázs, Taras Gerya, Dave May, and László Fodor

A common observation in plate tectonics is the successive stages of rifting and associated crustal and lithospheric thinning, and subsequent convergence and inversion of sedimentary basins. Rates and style of inversion often vary across the sedimentary basins, influenced by changing stress and thermal fields, different convergence directions, and also controlled by inherited structures, all of which determine the localization and style of the resulting deformation. However, the dynamic feedbacks between lithospheric tectonics and surface processes, and their 3D expressions have not been studied in details by previous models, even though erosion and sediment distribution exerts a significant control on differential vertical movements and thermal evolution.

In this study, we investigate strain partitioning during extension and subsequent structural inversion, and tackle the coupling between tectonics, mantle melting and surface processes. To do so, we apply the 3D thermo-mechanical code I3ELVIS (Gerya 2015; Munch et al. 2020), which is based on staggered finite differences and marker-in-cell techniques to solve the mass, momentum and energy conservation equations for incompressible media. The models also take into account simplified melting processes, as well as erosion and sedimentation by diffusion.

We compare the modeling results with seismic and well data from the Mediterranean back-arc basins, such as the Alboran, Tyrrhenian and Pannonian Basins. The temporal variation of different plate convergence and slab retreat velocities lead to the extensional formation, recent structural inversion and related differential vertical motions of these basins. In fossil extensional basins, plate convergence has ultimately overprinted the former basin structure, and lead to the rise of young orogens, i.e. the Pyrenees or Great Caucasus.

How to cite: Oravecz, É., Balázs, A., Gerya, T., May, D., and Fodor, L.: Structural inversion of sedimentary basins: insights from 3D coupled thermo-mechanical and surface processes models and observations from the Mediterranean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-542, https://doi.org/10.5194/egusphere-egu22-542, 2022.

EGU22-957 | Presentations | TS6.3

Anatomy of a dying spreading ridge: paleomagnetic evidence for horizontal axis rotations in the Troodos Ophiolite, Cyprus 

Eldert Advokaat, Marco Maffione, Alex Burton-Johnson, and Mark Dekkers

The Troodos ophiolite of Cyprus hosts a fossil spreading ridge at the Solea graben, whose last magmatic activity has been previously dated to 94.3±0.5 Ma. To study the evolution of a dying ridge, we collected structural geologic data and oriented specimens from the mantle section (serpentinized peridotites, pegmatitic dykes, pyroxenite and wehrlite intrusions) and lower crust (layered gabbros and massive gabbros) for paleomagnetic and rock magnetic analyses. Our results revealed a systematic pattern of horizontal axis rotations (i.e., tilt) in the region to the west of the Solea spreading axis, involving upper crust, lower crust, and upper mantle. Horizontal axis rotations vary in magnitude between ~20° to ~90° within the studied area, with the largest tilts observed to the west of the exposed mantle section at Mt. Olympus, and the smallest tilts observed near the NNW-SSE trending Troodos Forest-Amiandos fault system. This rotation pattern conflicts with previous interpretations considering the Troodos Forest-Amiandos fault as an oceanic detachment, and rather indicates the existence of deep-rooted listric faults that dismembered the Solea spreading ridge after the final phase of spreading.

 

Paleomagnetic directions from serpentinized peridotites indicate that serpentinization occurred both before and during dismemberment of the ridge by listric faulting. As these directions also record a well-studied regional 90° counter-clock-wise rotation of the Troodos ophiolite, we constrained the timing of ridge dismemberment and associated serpentinization between ~94 Ma and the beginning of the regional microplate rotation in the Turonian, hence encompassing a relatively short period of time of 2-4 Myr that well coincides with hydrothermal alteration in nearby plagiogranites dated at ~92–90 Ma.

How to cite: Advokaat, E., Maffione, M., Burton-Johnson, A., and Dekkers, M.: Anatomy of a dying spreading ridge: paleomagnetic evidence for horizontal axis rotations in the Troodos Ophiolite, Cyprus, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-957, https://doi.org/10.5194/egusphere-egu22-957, 2022.

Continental extension at mature rifts systems focuses along spreading segments where dominant magmatic activity, diking and minor faulting assist plate divergence. Such processes make adjacent spreading segments grow but also interact at zones where the spreading is transferred from one segment to another. A great variety of tectonic structures has been observed at transfer zones, encompassing parallel strike-slip faults (bookshelf faulting) or conjugate systems of en-echelon oblique faults. Transfer zones can also become transform plate boundaries once continental breakup occurs. However, the role of magma in influencing the deformation at rift-rift transfer zones is unclear as direct observations are rare. In this study, we address this open question by exploiting high-resolution Pléiades-1 tri-stereo imagery to produce the first 1 m DEM of the Afrera Plain transfer zone, between the Erta Ale and Tat Ali spreading segments in Northern Afar. This dataset has been used to conduct a detailed structural analysis of both tectonic and magmatic features and explore their geometrical and spatial relationships. We observed different trends and kinematics: Dikes opens with an extension oriented ~N65°E, consistent with the regional extension; tectonic features have instead an extensional component with direction varying between ~N46°E and ~N68°E. Riedel shears and measurements of fractures opening directions indicate that tectonic deformation occurs along two families of NW-SE- and NS-striking oblique faults having right-lateral and left-lateral components, respectively. At the same time, spatial relationships between faults and lava flows also indicate that magmatic and tectonic activity co-exist in the transfer zone. We explain these observations by two different strain fields acting in the Afrera Plain during magmatic and amagmatic phases. During magmatic phases, dikes open orthogonal to the spreading direction responding to the regional extension. Conversely, during amagmatic phases, the transfer zone is dominated by the interaction between the two spreading segments with counterclockwise rotations of the strain field and shear motions accommodated by conjugate fault systems.

How to cite: La Rosa, A., Pagli, C., Hurman, G., and Keir, D.: Analysis of high-resolution Digital Elevation Model (DEM) of the Afrera Plain (Afar) reveals relationship between magmatism and tectonics in a rift transfer zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1175, https://doi.org/10.5194/egusphere-egu22-1175, 2022.

        The tectonic evolution of the North Atlantic Ocean has been extensively studied using a variety of geological, geophysical, and plate reconstruction techniques. Recently, deformable plate tectonic reconstructions, built using the GPlates software, have become an increasingly used method for studying the plate kinematics, deformation, and subsequent crustal thickness evolution of tectonic regimes. For the North Atlantic Ocean in particular, deformable plate models have proven to be useful for studying the kinematic evolution of continental blocks (e.g. Flemish Cap and Galicia Bank) and the partitioning of strain within sedimentary basins (e.g. Orphan Basin). However, despite these advancements, previously published deformable plate models have included limitations that can be geologically unsatisfying. Some notable examples include, but are not limited to, uniform crustal thickness assumptions at model start times, and the rigid nature of continental blocks and model boundaries that define the limits of where deformation takes place.  

        Using the interplay of GPlates and its python programming module, pyGPlates, we present a new deformable plate modelling strategy and application within the North Atlantic Ocean. In contrast to previous studies, this approach considers deformation within continental blocks and the reconstruction of present day crustal thickness estimates calculated via gravity inversion. In addition, we also demonstrate the minimized impact of rigid landward model boundaries using this approach and the resultant ability to reconstruct rift domain boundaries a priori. The results of this study provide insight into the pre-rift (200 Ma) crustal thickness template of the North Atlantic and the evolution of relevant continental blocks during rift-related deformation. Furthermore, this work also highlights the potential impact of Appalachian and Caledonian terrane boundaries on the distribution and extent of rifting experienced along the Newfoundland, Ireland, and West Iberian offshore rifted margins.  

How to cite: King, M. and Welford, J. K.: Reconstructing deformable continental blocks and crustal thicknesses back through time within the North Atlantic Ocean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1310, https://doi.org/10.5194/egusphere-egu22-1310, 2022.

With increased geophysical scrutiny of the NE Newfoundland-Irish margin pair (North Atlantic), the previously assumed conjugate relationship and rift-perpendicular extension between the Flemish Cap and Goban Spur are increasingly questioned. We present multichannel reflection profiles along the Flemish Cap, the Porcupine Bank, and the Goban Spur, along which structural domains (proximal, necking, hyperextended, and/or exhumed mantle domains included) are defined. Features of each structural domain along these profiles on the Flemish Cap and the Goban Spur are strikingly different, whereas similar structural features are observed in the necking domains along seismic profiles on the Porcupine Bank and the Flemish Cap. The variability in basement features suggests oblique rifting between the Flemish Cap and the Goban Spur-Porcupine Bank region, as well as a connection between the Porcupine Bank and the Flemish Cap during Early Jurassic rifting. This understanding is consistent with crustal thickness evolution calculated from a deformable plate reconstruction model that is locally updated based on seismic interpretation constraints and previously published plate reconstructions. The updated deformable plate model shows varying extension obliquity between the Porcupine Bank, Goban Spur, and Flemish Cap, which are strongly influenced by inherited Caledonian and Variscan structures, resulting in the conclusion that the Flemish Cap and the Goban Spur were not conjugate margins prior to the opening of the modern North Atlantic Ocean.

How to cite: Yang, P. and Welford, J. K.: Conjugate no more: redefining the pre-rift relationship between the Flemish Cap and the Goban Spur prior to the North Atlantic opening, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2780, https://doi.org/10.5194/egusphere-egu22-2780, 2022.

EGU22-3220 | Presentations | TS6.3

The influence of accretionary orogenesis on rift dynamics 

Zoltán Erdős, Susanne Buiter, and Joya Tetreault

The Wilson Cycle of closing and opening of oceans is often schematically portrayed with ‘empty’ oceanic basins. However, bathymetric and geophysical observations outline anomalous topographic features, such as microcontinents and oceanic plateaus, that can be accreted when oceans close in subduction. This implies that numerous rifted margins have formed in regions characterized by the presence of previously accreted continental terranes. The main factors controlling where and how such continental rifts localize in relation to the inherited compressional structures is yet to be explored properly. Potential factors that can influence the evolution and structural style of a rift in such a tectonic setting include the thermo-tectonic age of the accretionary orogen, the number and type (size, rheology) of accreted terranes, the nature of terrane boundaries, as well as the velocity of rifting.

We use 2D finite-element thermo-mechanical models to investigate how the number and size of accreted terranes as well as the duration of tectonic quiescence between orogenesis and extension (i.e., the amount of time available for the thermal re-equilibration of the thickened lithosphere) affect the style of continental rifting. Our results can further understanding of how rifted margins formed after accretionary orogenesis are influenced by the compressional stage such as the Norwegian rifted margin, where the late-Paleozoic to Mesozoic rifting occurred after the early Paleozoic Caledonian orogeny.

We test two hypotheses. According to our first hypothesis, the location of the rift is dependent on the age of the accretion. If extension directly follows accretion, we expect the thick lithosphere of the orogen to be strong in a brittle sense, causing extension to localise adjacent to the orogen. In contrast, if the onset of extension happens after a period of tectonic quiescence, the accretionary orogen has time to heat up and viscously weaken, allowing it to localize deformation more efficiently. We test this hypothesis by varying the amount of time available for thermal re-equilibration.

Secondly, we hypothesize that the degree to which the compressional structures such as terrane boundaries in the accretionary stack reactivate depends on the size and complexity of the accreted assembly (through the number and size of the accreted terrains) as well as the strength of shear zones. We test this hypothesis by varying the number of terranes accreted prior to rifting.

Our preliminary results show that the subduction interface is reactivated in an extensional regime, but without a period of quiescence the reactivation is temporary and rifting occurs in the unthickened foreland basin area.

How to cite: Erdős, Z., Buiter, S., and Tetreault, J.: The influence of accretionary orogenesis on rift dynamics, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3220, https://doi.org/10.5194/egusphere-egu22-3220, 2022.

EGU22-3597 | Presentations | TS6.3

Analysis of strike-slip tectonics in extensional systems: the case of the Moroccan Atlas system 

Athanasia Vasileiou, Mohamed Gouiza, Estelle Mortimer, and Richard Coliier

The intracontinental belt of the High Atlas is an aborted rift system along NW Africa, which formed during the Mesozoic break-up of Pangaea and was inverted during the Alpine Orogeny. Although the inversion and orogeny build-up have been extensively studied, the Triassic to Jurassic rifting, synchronous to the opening of the Atlantic and the Tethys, is still poorly understood. True orthogonal rifting is proposed to occur in the Triassic to Early Jurassic, while the end of rifting is controversial and believed to be controlled by oblique extension. Restoration of the Atlantic-Tethys triple junction suggests sinistral motion between Iberia and Africa being active during the Middle Jurassic, which reactivated pre-existing NE-SW trending Hercynian weaknesses in transtension mode. This led to the formation of a series of pull-apart basins involving the basement and localised volcanic activity.

The Atlas system is an excellent field analogue to analyse the role of strike-slip tectonics in extensional systems, especially in the early stages of rifting. Despite the late Cenozoic (Alpine) inversion, the well-exposed syn-rift structures and sediments have been weakly affected by the broad contractional event.

Our study aims to investigate the kinematic and geometry of the oblique rifting phase, the strain variation lengthwise in the Atlas rift system, the relationship between the orthogonal rift structures, the strike-slip structures, and the synchronous volcanism. In this contribution, we will highlight the fieldwork results, which we used to constrain the restoration of the rift sytem, quantify extension vs. transtension, and produce a conceptual model of how strike-slip tectonics can influence the early stages of a rift system.

How to cite: Vasileiou, A., Gouiza, M., Mortimer, E., and Coliier, R.: Analysis of strike-slip tectonics in extensional systems: the case of the Moroccan Atlas system, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3597, https://doi.org/10.5194/egusphere-egu22-3597, 2022.

EGU22-6294 | Presentations | TS6.3

Life and Death of Normal Faults: Quantitative Analysis of Fault Network Evolution in 3D Rift Models 

Sascha Brune, Thilo Wrona, Derek Neuharth, Anne Glerum, and John Naliboff

Quantifying the spatial and temporal evolution of fault systems is crucial in understanding plate boundary deformation and the associated seismic hazard, as well as to help georesources exploration in sedimentary basins. During the last decade, 3D lithospheric-scale geodynamic models have become capable of simulating the evolution of complex fault systems, from the onset of rifting to sea-floor spreading. But since these models describe faults as finite-width shear zones within a deforming continuum, additional efforts are needed to isolate and analyse individual faults, so we can understand the entire life span of normal fault networks.

Here we present 3D numerical forward models using the open-source community software ASPECT. Our thermo-mechanical models include visco-plastic rheology, strain softening as well as lithospheric and asthenospheric layers to capture rift evolution from inception to continental break-up. We quantify normal fault evolution at the surface of the model with a method that describes fault systems as 2D networks consisting of nodes and edges. Building on standard image analysis tools such as skeletonization and edge detection, we establish a hierarchical network structure that groups nodes and edges into components that make up individual evolving faults. This allows us to track fault geometries and kinematics through time enabling us to analyse the growth, linkage and disintegration of faults.

We find that the initial fault network is formed by rapid fault growth and linkage, followed by competition between neighbouring faults and coalescence into a mature fault network. At this stage, faults accumulate displacement without a further increase in length. Upon necking and basin-ward localisation, the first generation of faults shrink and disintegrate successively while being replaced by newly emerging faults in the rift centre. These new faults undergo a localisation process similar to the initial rift stage. We identify several of these basin-ward localisation phases, which all feature this pattern. In oblique rift models, where the extension direction is not parallel to the rift trend, we observe strain partitioning between the rift borders and the centre, with strike-slip faults emerging in the centre even at moderate obliquity. Analysing the spatio-temporal evolution of modelled faults thus allows us to map their entire life span to observed stages of rift system evolution.

How to cite: Brune, S., Wrona, T., Neuharth, D., Glerum, A., and Naliboff, J.: Life and Death of Normal Faults: Quantitative Analysis of Fault Network Evolution in 3D Rift Models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6294, https://doi.org/10.5194/egusphere-egu22-6294, 2022.

EGU22-6886 | Presentations | TS6.3

MARIBNO amphibious project: Structure of the northwestern Iberian margin and role of the inherited tectonics in the Alpine extension and inversion 

Alfonso Muñoz-Martín, Jose-Luis Granja-Bruña, Miguel Angel De la Fuente-Oliver, María Druet, Gerardo De Vicente, Jorge Gallastegui Suárez, and Adolfo Maestro and the MARIBNO WORKING GROUP

The northwestern margin of the Iberian Peninsula (western Bay of Biscay) is a unique place that gathers several outstanding geological features in a relatively reduced area. Here, a former hyperextended continental margin developed in proximity to a triple point, underwent a subsequent partial tectonic inversion yielding the present Cantabrian margin. For all these reasons, the northwest area of ​​Iberia can be considered as a natural laboratory for the study of the role of tectonic inheritance in the evolution of the extensional continental margins and their subsequent inversion. However, and largely due to the lack of interest from exploration companies, the northwestern margin of Iberia presented a great deficit of geophysical and geological information. Both scientific interest and the lack of information provided the main reasons for the MARIBNO amphibious project (2019-2022). This project is being carried out by a multidisciplinary geoscientific team leaded by the Complutense University of Madrid with the acquisition of offshore and onshore data. The main objectives are focused on the study of the crustal structure, the tectonic control by the structure prior to the alpine stages and the mapping and characterization of the crustal domains, combining geological and geophysical criteria.

A one month-long geophysical cruise was carried out aboard the BO Sarmiento de Gamboa (Spanish Research Council, CSIC) in September-October of 2021. Data acquisition was divided in two cruise legs: The WAS Leg consisted in the acquisition wide-angle seismic data (WAS) along 3 transects with simultaneous offshore-onshore recording in 3 component short-period instruments: Transect WAS-1 (∼320 km) recorded in 14 OBS and 11 land seismometers, Transect WAS-2 (∼260 km) recorded in 12 OBS and 10 land seismometers and Transect WAS-3 (∼255 km) recorded in 9 OBS and 12 land seismometers. The seismic source consisted in an airgun array with 4660 ci and 90 seconds of shot interval. The MCS leg consisted in the acquisition of 2D multichannel seismic reflection data (MCS) along 14 transects (∼1500 km) recorded on a digital streamer with a 12.5 m channel-interval. Several streamer configurations were deployed with 480, 240 and 168 channels and the seismic source consisted in an airgun array with 1960 ci. During both legs, continuous marine acquisition of multibeam bathymetry, gravity, geomagnetics and ultra-high resolution seismic data also were carried out. MARIBNO project is still underway, and the data are being processed and interpreted. Acquired information will be complemented and combined with the additional acquisition of onshore gravity and magnetic data and the information from several geological field mapping studies on seismic transects throughout the Cantabrian Mountains. Here we show some preliminary results and the current development of the MARIBNO amphibious project.

How to cite: Muñoz-Martín, A., Granja-Bruña, J.-L., De la Fuente-Oliver, M. A., Druet, M., De Vicente, G., Gallastegui Suárez, J., and Maestro, A. and the MARIBNO WORKING GROUP: MARIBNO amphibious project: Structure of the northwestern Iberian margin and role of the inherited tectonics in the Alpine extension and inversion, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6886, https://doi.org/10.5194/egusphere-egu22-6886, 2022.

EGU22-7480 | Presentations | TS6.3 | Highlight

3D evolution of extensional detachment faults and their effect on the architecture of rifts and rifted margins 

Per Terje Osmundsen, Gwenn Péron-Pinvidic, Julie Linnea Gresseth, and Alvar Braathen

Extensional detachment faults, core complexes and supradetachment basins play major roles in the evolution of 3D rifted margin architecture. The successive incision of basement from early to late stages in the margin evolution is rarely explained in 3D. One reason for this is likely the lack of a unifying model for how very large faults grow and link laterally, and how this, in turn, links to the temporal evolution of the margin. As fault shape exerts a fundamental control on syn-rift basin architecture, the 3D evolution of detachment faults is critical to understand sedimentation in associated basins.

In the proximal margin offshore Norway, one control on lateral variation appears to be the differential exploitation of `extraction´ structures that evolved above the ductile crust. This controlled flips in fault polarity under the proximal margin, and lateral transitions from supradetachment- to half-graben style, Late Paleozoic-Triassic basins. Extensional culminations and core complexes were associated with this deformation pattern at depth.

The growth of an extensional fault past a displacement of a few kilometers will involve a change in 3D fault shape related to the isostatic rollback of parts of the fault plane. As displacement magnitude varies along the fault plane, so will the amount of extensional unloading and associated isostatic compensation. With increasing extension this will enforce a particular shape on the fault plane, with an extensional culmination developing in the area of maximum displacement, and synclinal recesses evolving on the flanks. With continued extension, the culmination evolves into a core complex. Necking domains, where faults propagate into the ductile middle crust appear to be prime locations for this type of faulting. As large-magnitude faults combine into domain-bounding breakaway complexes, this results in intermittent occurrences of core complexes along the main breakaways and lateral transitions into steeper megafaults and fault arrays. At the Mid-Norwegian margin, we interpret the Jurassic-Cretaceous North Møre and south Vøring basins to illustrate this type of evolution. Components of strike-slip may modify this type of pattern, as illustrated by  continental core complexes exposed in areas such as Death Valley and western Norway.

 

How to cite: Osmundsen, P. T., Péron-Pinvidic, G., Gresseth, J. L., and Braathen, A.: 3D evolution of extensional detachment faults and their effect on the architecture of rifts and rifted margins, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7480, https://doi.org/10.5194/egusphere-egu22-7480, 2022.

The Neuquén Basin is a major Mesozoic sedimentary depocenter located in the foreland of the Andes Mountains in Argentina. The basin hosts world renown inversion systems that have been the target of georesource exploration for the last three decades. The Huincul High is a structurally and economically prominent ~270km long, E-W trending feature that formed by the accretion of exotic Paleozoic terranes influencing subsequent Mesozoic deformation in the basin. Exploration in Huincul High has been mainly focused on the shallow part of the inversion structures leaving a limited understanding of  deep structural architecture and early tectonic evolution. With this research, for the first time a set of 4 3D seismic reflection surveys covering an area of 1400km2 have been analysed and integrated with stratigraphic information from 15 exploratory wells to provide new insights into the tectonostratigraphic and kinematic evolution of the western reaches of the Huincul High.

Detailed horizon and fault interpretation revealed Late Triassic, isolated, 10-50km long NE-SW to NW-SE trending half grabens. These extensional systems are attributed to the Late Triassic cessation of the Andean subduction to the west and intraplate extension regime ensuing. Thickness map of the Lower Jurassic Los Molles unit shows the development of an extensive ~50km  long ~15km wide NE-SW depocentre at that time. It is proposed that Andean subduction was renewed at that time, moving the Neuquén Basin into a backarc environment with hotter, weaker continental lithosphere thinned by mantle underflow which might have caused ductile flexural sag and minimal brittle faulting.

Prominent NE-SW cylindrical inversion anticlines ~17km across and well-developed harpoon structures are observed in the hangingwall of reactivated  ~50km long, NE-SW trending, extensional faults. Growth strata analysis shows thinning of Middle to Lower Cretaceous strata over the crest of these folds suggesting a phase of  NW-SE compression at this time. This compressional phase is attributed to the increase in Andean subduction rate and shallowing of the subduction dip, as the Neuquén Basin is moved into a foreland setting. Fault displacement analysis suggests that the reactivated faults were formed as separate fault segments at the time of extension in the Late Triassic. Additionally, analysis indicates that faults segments with increased reactivation show prominent hangingwall inversion anticlines.

Dip-steered coherency extractions along the Early Cretaceous Vaca Muerta Formation showed en echelon NW-SE transtensional faults occurring directly above Late Triassic non inverted faults; decoupled by the underlying shaly and mechanically weak Los Molles unit. These observations point to a post-inversion tectonic event that might coincide with reconfiguration of subducted plates changing the principal stress orientation and causing strike slip reactivation.

These results highlight the importance of  structural inheritance of a pre-existing  fault architecture in the development of  consequent inversion, and how mechanically weak units can inhibit fault propagation during the later compressional events, acting as a decoupling layer.  A detailed evolutionary model is proposed for the western reaches of the Huincul High which envisages crustal weakening and thermal sag to explain the thickening of the Early Jurassic strata previous to the main Cretaceous inversion.

How to cite: Antonov, I., Scarselli, N., and Adam, J.: Tectonic and geometric assessment of inversion systems in the Huincul High, Neuquén Basin (Argentina) – the role of structural inheritance and mechanical stratigraphy, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8244, https://doi.org/10.5194/egusphere-egu22-8244, 2022.

EGU22-8726 | Presentations | TS6.3

Regional-scale proximal to distal footwall scarp-degradation variability of extensional faults 

Candela Martinez, Domenico Chiarella, Christopher A.-L Jackson, and Nicola Scarselli

Footwall fault scarp-degradation produces sediments resulting in gravity-driven syn-rift wedge-shaped deposits located on the immediate hangingwall. To understand which aspects control footwall scarp-degradation we propose a model suggesting where, why, and how degradation occurs. We compare five offshore 3D seismic surveys acquired on the Northern Carnarvon Basin (North West Shelf of Australia) calibrated with well data to assess these questions. Two 3D seismic surveys (i.e., Panaeus 2001 East and Fortuna) are located on the Dampier Sub-basin, proximal to the Western Australia coastline and three (i.e., Thebe, Bonaventure and Agrippina) in a more distal position on the Exmouth Plateau. Data show that degradation is more pronounced on the distal surveys compared to the proximal ones. On the proximal surveys, the sedimentation rate is greater than in the distal ones, and footwall scarp-degradation is less pronounced. Answering these questions will help us to predict the style and the amount of footwall scarp-degradation in similar extensional settings.

How to cite: Martinez, C., Chiarella, D., Jackson, C. A.-L., and Scarselli, N.: Regional-scale proximal to distal footwall scarp-degradation variability of extensional faults, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8726, https://doi.org/10.5194/egusphere-egu22-8726, 2022.

EGU22-10197 | Presentations | TS6.3 | Highlight

A Cenozoic Wilson cycle along the Puysegur Margin, New Zealand: The role of rift architecture and strike-slip dynamics enabling subduction initiation 

Brandon Shuck, Harm Van Avendonk, Sean Gulick, Michael Gurnis, Rupert Sutherland, Joann Stock, and Erin Hightower

Throughout Earth’s history, the movement, suturing, and rifting of tectonic plates in the Wilson cycle often takes advantage of lithospheric weaknesses and pre-existing plate boundaries. Continental rifting and subduction initiation represent arduous phases of this cycle for plate divergence and convergence, respectively, where strain is not yet focused into a narrow and mature plate boundary. Here we present an analysis of the Puysegur margin to demonstrate how past tectonic regimes create inherited lithospheric structures that facilitate subsequent stages of the Wilson cycle.

 

The Puysegur margin is a young subduction zone and forms the northern segment of the Australian-Pacific plate boundary south of New Zealand, which has evolved from divergence to strike-slip and recently to oblique convergence, all in the last ~45 million years. Magnetic anomalies and curved fracture zones located south of the Puysegur segment show the divergent phase involved seafloor spreading and the formation of new oceanic lithosphere. However, these features are not present in the upper Pacific plate at the latitudes of the Puysegur margin, and the lack of quality seismic images in this region hampered our understanding of the local crustal structure, which was assumed to be a northward extension of the oceanic domain. A deep penetrating multichannel reflection (MCS) and ocean-bottom seismometer (OBS) dataset was acquired in 2018 with the R/V Langseth and provided new high-quality seismic images of the crustal structure along the Puysegur margin.

 

Our seismic images reveal that the overriding Pacific plate contains stretched continental crust with magmatic intrusions, which formed from rifting between Zealandia continental plateaus during AUS-PAC plate divergence. This stretching phase was highly asymmetric and resulted in the opening of the Solander Basin. Rifting was more advanced to the south, yet never proceeded to breakup and seafloor spreading as previously thought. A new southern continent-ocean transition is inferred from potential field data, marking the boundary between stretched continental crust and new oceanic crust formed during the extensional phase.

 

Along-strike heterogeneity with mixed continental and oceanic domains and asymmetric rift architecture along the Puysegur margin were critical features for following tectonic regimes. Increasingly oblique plate motions sparked strike-slip motion, which localized near the pre-existing spreading center in the south, but along the western edge of the rift zone in relatively unstretched crust at the Puysegur margin in the north. Translational motion juxtaposed weak ~10 Myr old oceanic lithosphere with buoyant continental crust across the strike-slip boundary. Incipient subduction transpired as oceanic lithosphere from the south forcibly underthrust continent lithosphere at an oblique collision zone.

 

We suggest that subduction initiation at the Puysegur Trench was enabled by inherited buoyancy contrasts and structural weaknesses that were imprinted into the lithosphere during earlier phases of continental rifting and strike-slip along the plate boundary. In the global evolution of plate tectonics, strike-slip might be the key component to achieving the Wilson cycle, as it is the most efficient mechanism to offset terranes and juxtapose lithospheric domains of contrasting properties across broad regions, thus generating advantageous conditions for subduction initiation and subsequent closure of oceanic basins.

How to cite: Shuck, B., Van Avendonk, H., Gulick, S., Gurnis, M., Sutherland, R., Stock, J., and Hightower, E.: A Cenozoic Wilson cycle along the Puysegur Margin, New Zealand: The role of rift architecture and strike-slip dynamics enabling subduction initiation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10197, https://doi.org/10.5194/egusphere-egu22-10197, 2022.

EGU22-11453 | Presentations | TS6.3 | Highlight

Crustal structure and along-strike variations in the Gulf of Mexico conjugate margins: From early rifting to oceanic spreading 

Esther Izquierdo-Llavall, Jean Claude Ringenbach, François Sapin, Thierry Rives, Jean-Paul Callot, and Charlotte Nielsen

The Gulf of Mexico opened as a Late Triassic-Mid Jurassic continental rift that was first largely covered by the Mid-Jurassic Louann Salt and later split apart by a triangular-shaped oceanic crust. Salt in the Gulf of Mexico largely hampers the imaging and interpretation of underlying pre-salt and crustal geometries, which are fundamental for assessing the early kinematic evolution of the margin. To better define these deep geometries and their lateral variations, we built three seismic-based crustal-scale cross-sections across the Florida-Yucatan conjugate margins, in the areas where the Mid-Jurassic salt unit is thinner.

Seismic-based cross-sections image the architecture of rifting and the geometries of the continental and oceanic crusts and the transition between them (ocean-continent transition, OCT). They show a meaningful along-strike variation: the South Florida-East Yucatan area is characterized by a narrower rifted continental crust that evolves sharply to oceanic crust whereas in the North Florida and central-western Yucatan areas, the rifted continental crust is wider and the transition to the oceanic crust corresponds to a narrow magmatic or exhumed mantle domain. In the rifted continental crust, seismic profiles image doubly-verging basement faults organized into decoupled and coupled rift domains. The geometrical and cross-cutting relationships between these basement faults, the Louann Salt and the underlying pre-salt sequence indicates a progressive migration of rifting from proximal to distal domains and from the central and north-eastern to the south-eastern Gulf of Mexico.  

Bulk continental crust extension was determined using the area balancing method. Estimated horizontal extension values vary from a minimum of ∼120 km in the South Florida-East Yucatan conjugate to a minimum of ∼240 km in the North Florida-Central Yucatan conjugate, being systematically larger in the northern margin. Crustal domains identified in the cross-sections were laterally correlated and westwards extended considering gravity and magnetic anomalies data to build a regional-scale, crustal domains map of the Gulf of Mexico. This map, together with the crustal extension estimates, has been used as the reference to carry out a plate-scale reconstruction of the Gulf of Mexico from the early rifting stages to the end of oceanic spreading.

Based on our observations and considering previous models, we propose that the study area evolved from an early rift involving magmatism, to a magma-poor margin, with continental break-up (OCT formation) being characterized by mantle exhumation and associated magmatism along the North Florida and central-western Yucatan areas.

How to cite: Izquierdo-Llavall, E., Ringenbach, J. C., Sapin, F., Rives, T., Callot, J.-P., and Nielsen, C.: Crustal structure and along-strike variations in the Gulf of Mexico conjugate margins: From early rifting to oceanic spreading, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11453, https://doi.org/10.5194/egusphere-egu22-11453, 2022.

EGU22-11778 | Presentations | TS6.3

Preservation of the necking domain in orogens: a case study of the Mont-Blanc massif (Western Alps, France) 

Nicolas Dall'asta, Guilhem Hoareau, Gianreto Manatschal, and Charlotte Ribes

Rift-related inheritance plays a key role in orogenic building, by controlling the thermal state and the position of major sedimentary and crustal decollement levels. As recognized by various authors, a switch from thin- to thick-skinned style of deformation in reactivated rifted-margin during convergence occurs where the necking domain of the margin is involved in the subduction. This is observed in the External Crystalline Massifs (Aar, Mont-Blanc, Belledonne, Pelvoux, Argentera) located at the transition between the external and the internal domains of the western Alps corresponding also to the proximal-distal transition (necking domain) of the former Jurassic margin. Necking reactivation during Alpine convergence is accommodated by shear zones, rooted in the ductile middle crust, propagating  the deformation toward the external domain.  This Alpine overprint, which led to a lower greenschist metamorphism (ca. 330°C) in the External Crystalline Massifs, raise the question of the preservation of the rift-related, pre-alpine structures in the western Alps, and their use as fossil-analogues of present-day necking domains.

A case study is the internal Mont-Blanc massif, where preserved pre-rift to syn-rift (Triassic to Mid-Jurassic) cover is observed below the internal nappes, and on top the crustal basement (Mont-Blanc granite). The contact between these deposits and the underlying basement is a fault zone, made of a cataclastic basement overlaid by a black gouge. Above the contact, remnants of allochthonous pre-rift deposits and delaminated carbonates are observed. The syn-rift sandstones (Grès Singuliers Fm), which are either in contact with the fault or located above the pre-rift deposits, contain reworked clasts of cataclasite. Above the contact, in the cataclastic basement, some crinoid-rich sediments of likely Pliensbachian age fill open cracks. Taken together, these observations strongly point to the preservation of a pre-alpine, rift-related detachment fault of Jurassic age.

The petrographical and geochemical analysis of the exhumed fault indicates strong hydration-assisted deformation. In the cataclasite, feldspars breakdown and important element transfer (especially Ba, F, Si, Pb, Zn and REE) suggest fluid circulation in an open system. The black gouge matrix is mostly made of illite, likely recrystallized during the Alpine overprint. In addition, different generations of syn-kinematic veins are observed in the detachment. The first type, composed of graphite precipitated at ~400°C in the cataclasite. Syn-kinematic quartz and quartz hyalophane (Ba-rich feldspars) in the cataclasite and gouge were formed from a fluid above 170°C a salinity of ~9 wt.% NaCl-equivalent. The mobilized elements are the same as those involved in pre-alpine Pb-Zn (Ba-F) ore-deposits of the internal Mont-Blanc (Amône, Mont-Chemin, Catogne), suggesting a genetic link between rift-related faults and mineralisations.

Despite partial Alpine metamorphic overprint, the early tectonic, sedimentary and geochemical records of this rift-related detachment fault are very well preserved, making a good analogue of present-day necking domains. The example of Mont-Blanc massif gives an opportunity to study all these aspects in detail, in particular to understand fluid-mediated element mobility during rifting. Finally, it can be used to better understand the final stages of reactivation of the necking domain in a mature orogenic system.

How to cite: Dall'asta, N., Hoareau, G., Manatschal, G., and Ribes, C.: Preservation of the necking domain in orogens: a case study of the Mont-Blanc massif (Western Alps, France), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11778, https://doi.org/10.5194/egusphere-egu22-11778, 2022.

EGU22-285 | Presentations | GD8.2

A Paleozoic accretion history: Igneous and detrital zircon signatures of the Kulutingwak and Danish River formations in the Yelverton Inlet-Phillips Inlet region, Ellesmere Island, Nunavut, Canada 

Megan Koch, William C. McClelland, Jane A. Gilotti, Karolina Kośmińska, Karol Faehnrich, and Justin V. Strauss

The Ordovician Kulutingwak Formation of Ellesmere Island, Nunavut, Canada is an enigmatic assemblage that occurs exclusively in fault-bounded panels in a critical 30 kilometer transect between the crystalline basement of the exotic Pearya terrane and clastic rocks on the Laurentian margin. The Pearya terrane is hypothesized to have accreted to the Laurentian margin during late Silurian to Devonian time. The Kulutingwak Formation includes metasedimentary, volcanic, and volcaniclastic rocks with local carbonate olistoliths and serpentinite-bearing lithologies that collectively represent a subduction-related assemblage formed in an accretionary prism. As such, this formation has been cited as evidence of an arc-continent collision, giving these rocks a significant role in shaping tectonic models for the accretion of the Pearya terrane, and subsequently, the assembly of the circum-Arctic region during the Paleozoic. Igneous and detrital zircon U-Pb and Lu-Hf data from 11 samples collected from the Kulutingwak and Silurian Danish River formations between the Petersen Bay fault zone (PBFZ) and the Emma Fiord fault zone (EFFZ) record a dynamic early Paleozoic tectonic setting at the northern Laurentian margin. Detrital zircon spectra from the Kulutingwak samples adjacent to the PBFZ show major age peaks at ca. 960 Ma that record affinity with the Pearya terrane basement, as well as peaks at ca. 1820 Ma and 2700 Ma that suggest a Laurentian margin source. Additionally, two samples record the presence of a 502–508 Ma source which is not well-documented in this region. Kulutingwak Formation volcaniclastic rocks further to the south in the EFFZ yield U-Pb zircon ages 456–465 Ma and εHf(t) signatures of -5 to +10, implying association with volcaniclastic rocks of the newly redefined Ordovician Fire Bay Formation, a dismembered arc fragment equivalent to Ordovician arc-related rocks connected with the Pearya terrane. The data demonstrate that there are at least two distinctive components within the currently defined Kulutingwak Formation: one that records combined provenance signatures from the Pearya terrane and the Laurentian margin in the Paleozoic and another that signals the presence of an Ordovician arc at ca. 455–470 Ma. U-Pb detrital zircon data collected from the Silurian Danish River Formation in this region demonstrate affinity with the Pearya terrane, with a major age peak at ca. 960 Ma. Composite signatures of ca. 960, 1820, and 2700 Ma in the Kulutingwak Formation suggest that the Pearya terrane had reached the Laurentian margin in Late Ordovician to Silurian time.

How to cite: Koch, M., McClelland, W. C., Gilotti, J. A., Kośmińska, K., Faehnrich, K., and Strauss, J. V.: A Paleozoic accretion history: Igneous and detrital zircon signatures of the Kulutingwak and Danish River formations in the Yelverton Inlet-Phillips Inlet region, Ellesmere Island, Nunavut, Canada, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-285, https://doi.org/10.5194/egusphere-egu22-285, 2022.

Geochronological studies illuminate our understanding of the tectono-stratigraphic evolution of the Arctic Ocean, submarine features, continental shelves and adjoining landmasses. The Franklinian and Sverdrup basins of the Canadian High Arctic preserve a near-continuous Phanerozoic succession detailing the geologic evolution of the northern Laurentian margin from the Neoproterozoic to Cenozoic. Whereas previous studies have documented the structural and stratigraphic record of several episodes of orogenesis and first-order depositional cycles related to Circum-Arctic evolution, supporting geochronological data are sparse because the logistical challenges associated with fieldwork at high latitudes resulting in poor temporal resolution on the magnitude and timing of: 1) accretion of the Pearya terrane to the Laurentian margin; 2) the Devonian to Carboniferous Ellesmerian orogeny; and 3) Paleogene Eurekan deformation. In an effort to constrain the age of these tectonic episodes, we applied 40Ar/39Ar and (U-Th)/He low-temperature geochronology to major polydeformed NE-SW trending strike-slip fault zones that bisect the Pearya terrane and Franklinian Basin of northern Ellesmere Island, Canada. Total fusion 40Ar/39Ar dating was conducted on 165 single muscovite grains from 22 samples. Age dispersion was sample dependent, with some samples exhibiting robust Paleozoic ages corresponding to the assembly and accretion of the Pearya terrane, and other samples yielding intra-sample date dispersion that spanned the late Paleozoic and Mesozoic, indicative of a previously unreported post-Ellesmerian and pre-Eurekan history. Zircon (U-Th)/He dates from 11 samples (n: 73) and apatite (U-Th)/He data from 6 samples (n: 21) are largely Eocene in age, with dominant populations of c. 48 Ma and c. 41 Ma, respectively. Inverse thermal history modelling of (U-Th)/He data indicates episodic Mesozoic burial and unroofing that coincide with changes in the regional stress regime from dominant N-S to WNW-ESE compression, and rapid cooling during the nascent (>53 Ma) and initial (53 Ma to 47 Ma) phases of Eurekan deformation. The improved geochronologic resolution of the eastern Canadian High Arctic will allow better correlation to offshore structural features and to deformation events on the Greenland plate and Svalbard archipelago.

How to cite: Schneider, D. and Powell, J.: Phanerozoic record of northern Ellesmere Island, Canadian High Arctic, resolved through 40Ar/39Ar and (U-Th)/He geochronology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1122, https://doi.org/10.5194/egusphere-egu22-1122, 2022.

EGU22-2379 | Presentations | GD8.2 | Highlight

The Permian-Triassic boundary across the Barents Shelf: an intricate record of climate change, mass extinction, recovery, and basin reorganisation 

Valentin Zuchuat, Lars Eivind Augland, Morgan T. Jones, Arve R.N. Sleveland, Richard Twitchett, Francisco J. Rodríguez-Tovar, Øyvind Hammer, Kim Senger, Peter Betlem, Holly E. Turner, Ivar Midtkandal, Henrik H. Svensen, and Sverre Planke

About 252 million years ago, near the end of the Permian, the Earth experienced its most dramatic mass extinction, caused by magmatic intrusions and volcanic eruptions associated with the Siberian Traps Large Igneous Province. This led to catastrophic global climatic changes, impacts of which lasted well into the Early Triassic.

Here, we summarise the results gathered from the study of sedimentary successions spread across the Barents Shelf that recorded the End Permian Mass Extinction (EPME) and its aftermaths across the Permian-Triassic boundary. Data and samples were collected from the Festningen section in western Spitsbergen; the DD-1 core and the associated river section in Deltadalen, central Spitsbergen; a core (7933/4-U-3) drilled by the Norwegian Petroleum Directorate offshore Kvitøya in northern Svalbard; and a core (7130/4-1; production licence 586) recovered from the Finnmark Platform in the Barents Sea. A series of state-of-the-art analyses were conducted on the collected material, including detailed facies analysis, organic and C-isotope geochemistry, mercury content, geochronology, high resolution XRF core scanning, petrography, ichnology, and palaeontology. Analyses were, where relevant, tied to the outcrops using digital outcrop models.

Traditionally, the Permian-Triassic boundary in Svalbard (and across the High Arctic regions) was placed at the marked and rapid facies change at the top of the siliceous mudstones and spiculites of the Kapp Starostin Formation, which are overlain by soft, non-siliceous mudstones and siltstones of the Vardebukta and Vikinghøgda formations. This abrupt facies change, which also marks the collapse of sponges, occurs across a few centimetres. Given that the non-siliceous mudstones were definitely of Early Triassic age, based on ammonoid biostratigraphy, this lithostratigraphic boundary was believed to represent a lacuna or a hiatus of several million years, with the uppermost Permian strata absent from the sedimentary record.

The base of the Triassic, however, is not defined by ammonoid biostratigraphy but by the conodont Hindeodus parvus, which was recently reported to occur a few meters above the lithostratigraphic boundary in the Deltadalen section. This means that the lithostratigraphic boundary is of Permian age. Additionally, our new data show that sedimentation was continuous across this lithostratigraphic boundary, corresponding to major environmental changes, potentially associated with a reorganisation of the basin(s) physiography.

Furthermore, the 6-8 ‰ δ13Corg negative excursion associated with the EPME falls between the lithostratigraphic and the Permian-Triassic boundary at all measured sections. These negative carbon isotope excursions occur in intervals with numerous tephra layers, the lowest of which has been dated at 252.13 ± 0.62 Ma, potentially connecting the recorded changes to the Siberian Traps. The EPME is also corroborated by the very abrupt decline of trace fossil abundance and diversity, as anoxia extended from proximal and shallow water to deeper settings. Geochemical and ichnological data support the existence of multiple anoxic pulses, separated by very brief periods of enhanced oxygen levels. It took ca. 150 Kyr for life to recover after the EPME, based on sedimentation rate calculations. Data also suggest that the hinterland of the basin experienced a shift towards more arid climatic conditions and increased eutrophication.

How to cite: Zuchuat, V., Augland, L. E., Jones, M. T., Sleveland, A. R. N., Twitchett, R., Rodríguez-Tovar, F. J., Hammer, Ø., Senger, K., Betlem, P., Turner, H. E., Midtkandal, I., Svensen, H. H., and Planke, S.: The Permian-Triassic boundary across the Barents Shelf: an intricate record of climate change, mass extinction, recovery, and basin reorganisation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2379, https://doi.org/10.5194/egusphere-egu22-2379, 2022.

EGU22-4322 | Presentations | GD8.2

Amerasia Basin: new data and new geological model 

Anatoly Nikishin, Eugene Petrov, Elizaveta Rodina, Ksenia Startseva, Andrey Chernykh, Sierd Cloetingh, Gillian Foulger, and Henry Posamentier

We present an interpretation of the regional seismic lines for the Amerasia Basin, and new data from analyses of rocks from the Alpha-Mendeleev Rise. This report is based primarily on interpretation of 2D seismic lines and analysis of magnetic and gravity field anomalies, from data acquired through the Russian Arktika-2011, Arktika-2012, Arktika -2014, and Arktika-2020 projects. We use also open Canadian seismic data (Shimeld et al., 2021) and published data. We propose that the Alpha-Mendeleev Rise is a Eurasian aborted double-sided volcanic passive continental margin with stretched and hyper-extended continental crust intruded by basalts. This rise has a number of SDR-like seismic units. The age of volcanism is ~125-100 Ma. The Podvodnikov, Toll, Mendeleev, Nautilus, Stefansson basins have SDR-like seismic units. The top of SDR-like units has a similar age in all basins. The Alpha-Mendeleev Rise has an axis of symmetry. The East North Chukchi, Toll, Mendeleev, Nautilus, Stefansson basins are coeval basins with very stretched continental crust. They are connected by a long united axial line of hyperextension, subsidence and volcanism.  The Makarov, Podvodnikov, West North Chukchi basins are coeval basins with very stretched continental crust. They are connected by a long united axial line of hyperextension, subsidence and volcanism.  The Alpha-Mendeleev Rise and all mentioned basins originated simultaneously in the same geodynamic environment during the HALIP magmatic epoch at nearly 125-100 Ma. This study was supported by the Russian Science Foundation (Grant 22-27-00160).

How to cite: Nikishin, A., Petrov, E., Rodina, E., Startseva, K., Chernykh, A., Cloetingh, S., Foulger, G., and Posamentier, H.: Amerasia Basin: new data and new geological model, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4322, https://doi.org/10.5194/egusphere-egu22-4322, 2022.

EGU22-4415 | Presentations | GD8.2

SDR (Seaward Dipping Reflectors) mapping in the Amerasia Basin 

Elizaveta Rodina, Anatoly Nikishin, and Ksenia Startseva

Study area includes Alpha-Mendeleev Rise and contiguous deep-water basins – Toll, Mendeleev, Nautilus and Stefansson Basins near the eastern slope and Podvodnikov and Makarov Basins near the western slope. The western boundary is Lomonosov Ridge; the eastern boundary is Chukchi Plateau and part of the Canada Basin. There are Chukchi and East Siberian Seas on the continental shelf.

Within the study area, we studied and interpreted seismic 2D profiles from the Russian Arktika-2011, Arktika-2012, Arktika -2014, and Arktika-2020 expeditions. We also worked with open Canadian seismic data (Shimeld et al., 2021) and published data (e.g., Ilhan, Coakley, 2018). A unified seismostratigraphic correlation was carried out for the entire region.

Many half-grabens locate on the edges of deep-sea basins. Bright-amplitude reflectors with wedge-shaped architecture fill half-grabens. These reflectors are similar to SDR and they represent by interbedding of basaltic lavas and sedimentary rocks. They are typical for the synrift complex within the study area. The top of the synrift complex (or top of SDRs like units) is a bright boundary with age ~100 Ma.  Sometimes the top of the synrift complex contains conical edifices with a chaotic internal structure. Their height is 400-800 m. This is possible underwater volcanoes. The base of the synrift complex (or base of SDRs like units) is unclear and corresponds to the top of the acoustic basement. This age is near 125 Ma. We assume that SDRs like units and volcanos were formed during the HALIP epoch (~125-80 Ma).

 We found a regularity in the distribution of half-graben and SDRs like units. They are all located at the edges of the basins near the slopes of the uplifts. Two axes can be distinguished as the centers where SDRs like units and half-grabens converge. The western axis goes through Podvodnikov Basin and corresponds with the central uplift of the Podvodnikov basin. Reflectors dip from the western slope of the Mendeleev Rise from one side and from the Lomonosov Ridge from another. They converge near the central uplift. The eastern axis goes through Toll, Mendeleev, Nautilus and Stefansson Basins. In Toll and Mendeleev Basins reflectors and half-grabens dip from east slope of Mendeleev Rise from one side and from Chukchi Plateau from another. The Stefansson Basin looks similar to the Podvodnikov Basin. The central uplift is located in the center of the Stefansson Basin. Reflectors and half-grabens dip from Alpha Rise from one side and from Sever Spur from another. We have compiled a map of the distribution of SDR’s like units, volcanoes and half-grabens based on the map of the acoustic basement.

This study was supported by the Russian Science Foundation (Grant 22-27-00160).

How to cite: Rodina, E., Nikishin, A., and Startseva, K.: SDR (Seaward Dipping Reflectors) mapping in the Amerasia Basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4415, https://doi.org/10.5194/egusphere-egu22-4415, 2022.

EGU22-4449 | Presentations | GD8.2

The great Arctic Eocene strike-slip zone Umky 

Ksenia Startseva, Anatoly Nikishin, and Elizaveta Rodina

On the seismic lines acquired in 2011-2020 for the North-Chukchi Sea and East Siberian Sea basins plenty of low-amplitude normal faults is identified. Maximal apparent throw of the faults is 100-200 ms, and occasionally reaches up to 300-400 ms. Dip angles of the faults are often directed towards each other, the resulting flower structure is related to strike-slip tension. For individual faults it is possible to ascertain strike azimuth – near 350° for the North Chukchi basin and near 340° in East Siberian basin. By the seismic data, the faults are distributed within an area of ~1.500 km long- and ~350 km wide.

According to interpretation, the faults activation occurred from 45 Ma to 34 Ma. This time corresponds to a regional tectonic rebuilding, that is observed across all the region. For example, a sharp slowdown of the Eurasian Basin spreading had place then. Formation of the North-Chukchi and East Siberian basins is related to Aptian-Albian (~125 Ma) rifting, that manifested itself on the De Long Islands and the Mendeleev Rise. Isometric form of the basins could indicate the conditions of pull-apart tension. Data of gravity and magnetic anomalies support this assumption – a long linear anomaly of ~285° strike is identified to the North of the Wrangel Island (in Chukchi, the last is called Umkilir – “White Bear Island”). The anomaly is interpreted as regional strike-slip that was formed ~125 Ma. The angle between the strike-sleep and the multiple low-amplitude Eocene faults is about 55-65°. It is possible to relate the low-amplitude faults to the reactivation of the great strike-slip.

This study was supported by the Russian Science Foundation (Grant 22-27-00160).

How to cite: Startseva, K., Nikishin, A., and Rodina, E.: The great Arctic Eocene strike-slip zone Umky, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4449, https://doi.org/10.5194/egusphere-egu22-4449, 2022.

EGU22-5930 | Presentations | GD8.2

Variably depleted mantle in the source of Azores lavas 

Paul Béguelin, Andreas Stracke, Felix Genske, Michael Bizimis, Christoph Beier, and Michael Willig

The Azores Plateau in the North Atlantic is a classic example of near-ridge oceanic plateau (600 km) associated with the upwelling of the Azores mantle plume. The radiogenic isotope signatures of Azores lavas show systematic inter-island variations, which are often interpreted in terms of sampling several distinct, chemically enriched reservoirs from the Azores plume [1].

Here we discuss new radiogenic cerium isotope data on Azores lavas in the context of recent isotope data on olivine-hosted melt inclusions [2]. Olivine-hosted melt inclusions have very high neodymium isotope ratios (up to εNd = 18.1), suggesting that variably depleted mantle is the dominant component of the Azores mantle source [2]. Radiogenic Ce isotopes reflect the time-integrated La/Ce ratio of the mantle source. La/Ce approaches zero values in incompatible element depleted mantle, while the Sm/Nd and Lu/Hf ratios retain higher, more variable values. Melts from variably depleted mantle therefore develop distinct signatures in Ce–Nd–Hf space [3].

The new Ce isotope values for 36 whole-rock lava samples covering the whole Azores Plateau reveal a number of parallel, vertically stacked trends in Ce–Nd and Ce–Hf isotope space, pointing to variably incompatible depleted end-members, that are not discernible in Sr–Nd–Pb–Hf isotope space. The observed isotope trends in Ce–Nd–Hf space are readily explained by variable contribution of melts from volumetrically dominant, but variably depleted mantle and similar, but inherently heterogeneous enriched local plume components. Hence, although not directly reflected in the erupted basalts on a whole-rock scale [1, 2], variable contribution of melts from a variably, in part highly depleted mantle control the isotope composition of Azores lavas.

These results indicate the North Atlantic mantle below the Azores is variably depleted and contains highly depleted domains. The lavas closest to the proposed plume center [4] do not correspond to either extreme in terms of mantle depletion, suggesting mantle depletion in Azores is inherently complex and not a simple mixing product between plume and ridge mantle.

 

[1] Béguelin et al. (2017) Geochimica et Cosmochimica Acta, 218, 132-152.

[2] Stracke et al. (2019) Nature Geoscience, 12(10), 851-855.

[3] Willig et al. (2020) Geochimica et Cosmochimica Acta, 272, 36-53.

[4] Bourdon et al. (2005) Earth and Planetary Science Letters, 239, 42-56.

How to cite: Béguelin, P., Stracke, A., Genske, F., Bizimis, M., Beier, C., and Willig, M.: Variably depleted mantle in the source of Azores lavas, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5930, https://doi.org/10.5194/egusphere-egu22-5930, 2022.

EGU22-5989 | Presentations | GD8.2 | Highlight

The anomalous North Atlantic region 

Hans Thybo and Irina Artemieva

The whole North Atlantic region has highly anomalous topography and bathymetry. Observations show evidence for anomalously shallow bathymetry in the ocean as well as recent rapid topographic change with onshore uplift close to the Atlantic coast and simultaneous subsidence of basins on the continental shelves, most likely throughout the Mesozoic. We present a geophysical interpretation of the whole region with emphasis on data relevant for assessing hypsometric change

Most of the North Atlantic Ocean has anomalously shallow bathymetry by up-to 4 km compared to other oceans. Bathymetry is elevated by up-to 2 km and follows the square-root-of-age model, except for the region between Greenland Iceland Faroe Ridge (GIF) and the Jan Mayen Fracture Zone as well as in the Labrador Sea to Baffin Bay. Heat flow follows with large scatter the square-root-of-age model in parts of the ocean and is anomalously low on the Reykjanes and Mohns spreading ridges. Near-zero free-air gravity anomalies indicate that the oceanic areas are generally in isostatic equilibrium except along the mid-oceanic ridges, whereas anomalously low Bouguer anomalies in the oceanic areas indicate low density in the uppermost mantle. Anomalously thick crust is observed along GIF and extends into the Davies Strait. There is no correlation between bathymetry and heat flow, which indicates that the anomalous bathymetry mainly is caused by compositional variation and isostatic compensation of low density continental lithosphere within the oceanic regions. The location of major oceanic fracture zones and continental fragments appears to be controlled by onshore structures.

The onshore circum-Atlantic areas show rapid uplift close to the coast with rates of up-to 3 cm/yr. This is surprisingly mainly associated with strong positive free-air gravity anomalies, which would predict isostatic subsidence. Some parts of the high topography, however, appear supported by low-density anomalies below the seismic Moho. It is enigmatic that the presumed Archaean-Proterozoic continental Barents Sea region is submerged and includes deep sedimentary basins.

How to cite: Thybo, H. and Artemieva, I.: The anomalous North Atlantic region, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5989, https://doi.org/10.5194/egusphere-egu22-5989, 2022.

EGU22-6068 | Presentations | GD8.2

Evaluating the crustal architectures of the Eastern Seaboard of the United States: Insights from seismic reflection and potential field data 

Mike Shotton, Estelle Mortimer, Mohamed Gouiza, and Chris Green

Passive margins are commonly categorised into two end-member models based on the amount of magma produced during continental rifting and breakup, resulting in ‘magma-rich margins’, or ‘magma-poor margins’ as a generic classification. However, in recent years, substantial variability within these models, due to parameters such as rheology, structural inheritance, variations in magmatic budget, has been identified. Similarly, attempting to confidently interpret crustal architectures, particularly within the ocean-continent transition zone, is challenging and much uncertainty in geometries and crustal type exists across many rifted margins across the globe which require careful and robust interpretation to attempt to reduce this uncertainty.

This contribution focuses on the Eastern Seaboard of the United States; in which we show a suite of seismic interpretations (from seismic reflection data), together with validations from potential field data to produce a comprehensive map of the crustal types along the margin. Much recent work on the margin has investigated the segmentation along strike, indicating that the architecture of the Eastern Seaboard does not conform to any of the end-member models. Here we provide evidence of the segmentation and non-conforming nature of the margin, consistent with recent work on the US Eastern Seaboard which is at odds with typical models of rifted margin architectures. Furthermore, to accompany the new crustal architectures map, we propose a conceptual structural model of the development of the margin, constrained by our observations and accounting for the three-dimensional nature of the margin evolution.

How to cite: Shotton, M., Mortimer, E., Gouiza, M., and Green, C.: Evaluating the crustal architectures of the Eastern Seaboard of the United States: Insights from seismic reflection and potential field data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6068, https://doi.org/10.5194/egusphere-egu22-6068, 2022.

Cretaceous to earliest Oligocene plate motions between Greenland and North America are only modellable at high resolution from a short-lived (61-42 Ma) sequence of magnetic isochrons in the Labrador Sea. Understanding them at other times is hampered by interpretational conflicts and low resolution in geoscientific observations of the Labrador Sea, Davis Strait, Baffin Bay, and Eurekan Orogen. To better contextualize these observations, we build and manipulate models of North America-Eurasia and Eurasia-Greenland divergence in order to depict post-84 Ma North American-Greenland motions at quantified high resolution. Among our findings, we show that the North American-Eurasian plate boundary propagated northwards, leading the continental shelves in the Labrador Sea to separate by 74-72 Ma and in Baffin Bay later, at around 63 Ma, and that field evidence for the Eurekan Orogeny having occurred in two distinct phases is directly related to a 46 Ma change in Greenland-North American plate motion parameters.

How to cite: Causer, A., Eagles, G., Pérez-Díaz, L., and Adam, J.: Cenozoic relative movements of Greenland and North America by closure of the North Atlantic-Arctic plate circuit: The Labrador Sea, Davis Strait, Baffin Bay, and Eurekan Orogen, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6077, https://doi.org/10.5194/egusphere-egu22-6077, 2022.

EGU22-6201 | Presentations | GD8.2

Provenance Analysis of the Andrée Land Basin and the Paleogeography of Svalbard in the Devonian 

Owen Anfinson, Margo Odlum, Karsten Piepjohn, Erini Poulaki, Grace Shephard, Daniel Stockli, Devin Levang, and Maria Jensen

During the Devonian, the Svalbard Archipelago lay near the equator, occupying an important paleogeographic position at the intersection of Caledonian and Ellesmerian orogens. We provide new sediment provenance constraints, including detrital zircon U-Pb ages, from the Devonian Andrée Land Basin, Svalbard, to understand the tectonic history of the archipelago at that time. Sedimentary provenance analysis of Devonian aged strata can help reconstruct the sediment sources and paleogeography to understand the assembly of the domains that make up Svalbard, that are presently separated by Devonian sedimentary basins and(or) faults with syn- to post Devonian displacement. The studied Andrée Land Group strata in Dicksonland, which are part of the North Atlantic's Old Red Sandstone, consist of the Early Devonian Wood Bay Formation and Middle to Late Devonian Mimerdalen subgroup. Paleocurrent indicators from Lower to lower-Middle Devonian strata record north-directed sediment transport. Detrital zircon U-Pb data are dominated by ages sourced from Svalbard’s Northwestern and Southwestern Basement provinces. In Middle and Upper Devonian strata, paleocurrents and detrital zircon ages suggest a shift to a predominantly eastern-northeastern provenance, likely sourced from the uplifting Ny-Friesland block along the Billefjorden Fault Zone. The addition of significant late Ediacaran-early Cambrian detrital zircons in a sample from the uppermost Planteryggen Formation (Frasnian) indicate sources associated with the Timanian orogen and provide a useful palaeogeographic indicator when compared to other regional detrital zircon data sets. Detrital zircon ages and provenance data suggest Svalbard may have already been assembled, similar to the block we see today, with the Andrée Land Basin between modern exposures of the Southwestern/Northwestern and the Northeastern basement provinces. Comparison of detrital zircon ages from Andrée Land Group strata with those from other circum Arctic Lower, Middle, and Upper Devonian strata provides further insight on Svalbard’s paleogeographic position in the Devonian.

How to cite: Anfinson, O., Odlum, M., Piepjohn, K., Poulaki, E., Shephard, G., Stockli, D., Levang, D., and Jensen, M.: Provenance Analysis of the Andrée Land Basin and the Paleogeography of Svalbard in the Devonian, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6201, https://doi.org/10.5194/egusphere-egu22-6201, 2022.

EGU22-6253 | Presentations | GD8.2 | Highlight

The Arctic and NE Atlantic Realms: A comparison 

Gillian Foulger, Anatoly Nikishin, Elizaveta Rodina, Ksenia Startseva, Laurent Gernigon, Laurent Geoffroy, Jordan Phethean, and Andrey Chernykh

The disintegration of Pangea north of the Charlie Gibbs fracture zone led to the formation of the NE Atlantic and Arctic Oceans. Both these oceans are exceptionally complex in terms of diversity of the structures they contain and the sequence of events leading to their formation. Recent, extensive work by cross-disciplinary international groups has cast a great deal of new light on the structure and evolution of both oceans. Both have experienced fan-shaped oceanic-type spreading and ridge growth by linear propagation. Both contain shallow, linear bathymetric highs which comprise substantially or almost wholly, continental crust. There are also regions of continental crust, some hyper-extended, capped with lavas. Much of the NE Atlantic Ocean is floored by oceanic crust produced by classical, albeit piecemeal, oceanic spreading. The spreading rate is low and dwindles to ultra-low on the Gakkel Ridge in the Eurasia Basin of the Arctic Ocean. The Gakkel Ridge is flanked by linear, oceanic-like magnetic anomalies although it is not entirely clear whether these represent fully oceanic crust formation or whether some residual stretched continental crust remains beneath this region. The same may be true of the extinct Canada Basin spreading axis in the Amerasia Basin. Likewise, the nature and location of the continent-ocean transition in the NE Atlantic is currently under discussion and it has recently been proposed that the oldest linear magnetic anomalies, closest to the continental edges, characterize some form of magma-injected continental crust. A similar structure has been recently proposed for the Greenland-Iceland-Faroe Ridge  and the Alpha-Mendeleev Rise. What is currently unclear is the extents, in both oceans, of the three kinds of crust – true continental crust including microcontinents, magma-injected continental crust, and fully oceanic crust. There is furthermore likely a structural and geological continuum between these types. Classical linear magnetic anomalies are discontinuous between sections of the spreading ridge, raising the question of whether continuous fully oceanic crust connects these sections. In our presentation we will summarize what is known geologically and tectonically about both oceans, compare and contrast them, and outline their evolution. We will discuss the extents of the three types of crust and explore the implications for the history and mechanisms of ocean formation and the origins and extents of flood basalts. Of particular interest also is the control of pre-existing structure on the style of breakup.

How to cite: Foulger, G., Nikishin, A., Rodina, E., Startseva, K., Gernigon, L., Geoffroy, L., Phethean, J., and Chernykh, A.: The Arctic and NE Atlantic Realms: A comparison, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6253, https://doi.org/10.5194/egusphere-egu22-6253, 2022.

EGU22-7053 | Presentations | GD8.2

New insights into the brittle evolution along the passive continental margin of Western Norway from U-Pb calcite dating 

Åse Hestnes, Kerstin Drost, Deta Gasser, Joachim Jacobs, Thomas Scheiber, Tor Sømme, and David Chew

We here present the first U-Pb geochronology from calcites precipitated on fracture and fault surfaces from the passive continental margin of Western Norway. The evolution of passive continental rifted margins is reflected in complex fracture and fault networks which have been activated and reactivated through time. Constraining the timing of fault activity and fracturing can assist in revealing the interaction between tectonic processes and the topographic response onshore. Recently, U-Pb calcite dating has proven to be a useful tool to complement other geochronological methods and to produce more complete records of brittle deformation in different geological settings. In this study, we collected 35 calcite samples from different fault and fracture planes in Western Norway, 14 of which gave reliable U-Pb dates. The onshore field area is located at the junction of the NE-SW trending Norwegian Sea and the N-S trending North Sea. 1) The oldest calcites measured are from the Dalsfjord fault, a complex brittle fault related to the Nordfjord-Sogn Detachment Zone. The ages obtained from a green cataclasite indicate fluid flow and calcite precipitation around 208 ± 25 Ma and 205 ± 6 Ma, whereas a reddish cataclasite and fault gouge zone were dated 142 ± 15 Ma. 2) Two calcite samples from the northern part of the study area were collected along fractures parallel to the Møre-Trøndelag Fault Complex and yield dates of 89 ± 4 Ma and 79 ± 3 Ma. 3) Five samples from variously oriented fractures and faults spread over the field area gave dates of 69 ± 2 Ma, 67 ±15 Ma, 65 ± 2 Ma, 64 ± 2 Ma and 59 ± 2 Ma. These ages can be linked to the base Tertiary unconformity in the offshore stratigraphic record of the northern North Sea interpreted to be caused by onshore uplift. Several processes have been proposed to cause a possible uplift during this time span; a) regional influence of the Icelandic mantle plume, b) rift footwall uplift, c) climatically controlled topographic changes. 4) Five samples from across the field area yield dates of 49 ± 3 Ma, 35 ± 1 Ma, 21 ± 1 Ma, 5.5 ± 4.5 Ma and 0.8 ± 0.1 Ma. All these calcites precipitated on faults and fractures striking NE-SW, and its formation may be related to relaxation along the passive margin. The dated calcites from this study provide Cenozoic brittle deformation ages much younger than previously obtained by other geochronological methods, possibly allowing to decipher the youngest brittle tectonic evolution of the margin in unprecedented detail.

How to cite: Hestnes, Å., Drost, K., Gasser, D., Jacobs, J., Scheiber, T., Sømme, T., and Chew, D.: New insights into the brittle evolution along the passive continental margin of Western Norway from U-Pb calcite dating, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7053, https://doi.org/10.5194/egusphere-egu22-7053, 2022.

EGU22-9399 | Presentations | GD8.2 | Highlight

A digital Circum-Arctic geological repository from the NORRAM project 

Carmen Gaina, Grace Shephard, Alexander Minakov, Owen Anfinson, Victoria Ershova, Andrew Schaeffer, Kim Senger, Daniel Stockli, Bernard Coakley, Lars Eivind Augland, Pascal Audet, Ivar Midtkandal, and Morgan Jones

Most of the Arctic region is contained within the territory of Norway, Russia, USA, Canada and Denmark/Greenland, yet the natural boundaries and processes do not conform to these political borders. This remote region requires special logistics, equipment and substantial financial support. The last decade has seen an increase in knowledge about the northern polar region for economic and political reasons, such as the extended continental shelf claims under UNCLOS and Arctic Council activities.

It is crucial that scientific research, activities and their outcome are visible to the broader scientific community and communicated to the wider public. In recent years considerable effort has been invested by several groups and institutions to make various data and results available online and to use it for education and outreach. Examples include: the Arctic Observing Viewer which is a web mapping application in support of U.S. SEARCH, AON, SIOS, and other Arctic Observing networks (https://arcticobservingviewer.org/); Arctic Research Mapping Application (https://armap.org/) and the NSF Arctic Data Center (https://arctic data.io) for locating projects and data supported by US funding agencies; Svalbox (www.svalbox.no), a database for digital outcrop models from Svalbard, the comprehensive PANGAEA database  (https://www.pangaea.de), a data publisher for Earth and Environmental sciences; and GeoMapApp (http://www.geomapapp.org/), a map-based application for browsing, visualizing and analyzing a diverse suite of curated global and regional geoscience data sets.

While a wealth of data can be located and viewed in these databases and data repositories, the scientific community and geoscience educators may benefit from a collection of geological and geophysical data that can be easily visualized, analyzed and used for a quick assessment of present-day geodynamic setting and further for paleogeographic reconstructions  in the circum-Arctic region.

Consequently, a group of scientists from four Arctic countries and their collaborators are aiming to consolidate and further develop the Arctic-related common scientific basis and educational programmes under the auspices of the Norwegian Research Council programme INTPART (International Partnerships for Excellent Education, Research and Innovation).

The project NOR-R-AM (https://norramarctic.wordpress.com/), established in 2017, focused on assessing the openly available information accumulated at participating institutes. During the first phase of this project, we have gathered and interpreted data in various sub-regions, especially in Svalbard and in Russia. The second phase of the NOR-R-AM project aims to complete and launch the digital Circum-Arctic geodynamics platform. This web-based platform will incorporate geological and geophysical data and models, tomographic and kinematic models and paleogeography and paleoclimate indicators. The digital Circum-Arctic geological repository,  to be hosted by our project webpage https://norramarctic.wordpress.com/, assembles the data in openly accessible formats that are compatible with GPlates, GeomapApp and Google Earth. These data are consistently formatted to simplify exchange and completely open to the scientific community.

How to cite: Gaina, C., Shephard, G., Minakov, A., Anfinson, O., Ershova, V., Schaeffer, A., Senger, K., Stockli, D., Coakley, B., Augland, L. E., Audet, P., Midtkandal, I., and Jones, M.: A digital Circum-Arctic geological repository from the NORRAM project, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9399, https://doi.org/10.5194/egusphere-egu22-9399, 2022.

EGU22-10387 | Presentations | GD8.2 | Highlight

Lithosphere response to erosion: Model and case studies 

Sergei Medvedev and Ebbe Hartz

Extensive surface erosion may cause sizable lithospheric deformations. The effects are even more remarkable in regions subjected to glacial erosion. The isostatic response shielded by flexurally strong lithosphere is usually wider than localized glacial erosion and causes non-linear local effects. We use erosion backward in time (EBT) to model this process. In our experiments, we numerically fill the eroded voids with crustal material and calculate isostatic response to this added surface load. We assume that these calculations approximate amplitudes of erosion-related processes occurred in nature. Our studies started with considering enigmatic marine Mesozoic sediments stored at the elevation of 1.2 km in central east Greenland, the area free from recent compressional tectonic processes. The location is surrounded by the world’s biggest fjord system, Scoresby Sund. Application of the EBT allows us to estimate the unloading by the glacial fjord carving and conclude about a km-scale regional uplift explaining elevated marine sediments. Similar study on the development of the Europe’s biggest plateau, Hardangervidda in the southern Norway, demonstrated that glacial erosion caused up to 40% uplift of the plateau. Analyzing the Quaternary evolution of the North Sea, we found that on-shore erosion and off-shore sediment accumulation results in differential vertical motion of the lithosphere of up to 1 km across the sea. Applied to a particular petroleum system, the Troll field, this tilting explains significant oil spilling during the Quaternary.

How to cite: Medvedev, S. and Hartz, E.: Lithosphere response to erosion: Model and case studies, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10387, https://doi.org/10.5194/egusphere-egu22-10387, 2022.

EGU22-11241 | Presentations | GD8.2

The Eurekan in eastern North Greenland: insights from thermochronology 

Katrin Meier, Paul O'Sullivan, Patrick Monien, Karsten Piepjohn, Frank Lisker, and Cornelia Spiegel

Eastern North Greenland is a key area for studying the reorganisation of the North Atlantic-Arctic Realm during the Cenozoic. Due to its crucial position at the intersection of Atlantic Ocean, Arctic Ocean, and the West Greenland Rift Basin this area was significantly involved in the Eureka Orogeny leading to intracontinental compression/transpression observed on the Svalbard-Barents margin and the Canadian Archipelago as well as Northern Greenland. In the Neogene the final breakup occurred in this area, leading to the deep-water connection of the Arctic and North Atlantic Oceans.

It is characterized by the Carboniferous-Paleogene deposits of the Wandel Sea Basin overlaying Mesoproterozoic to early Palaeozoic supracrustal rocks. They occur in a series of pull apart basins along a zone of NE-SW-oriented faults. These faults are part of the DeGeer Shear Zone, along which the lateral offset of Greenland and Spitsbergen occurred during the Eureka Orogeny. In accordance the deposits are deformed, but the timing and the structural context of the deformation is much debated. Also, some deposits show unusually high thermal maturities of which the origin and geodynamic context is unclear.

We took samples across the Tolle-Land-Fault-Zone from the coast in the NE into the Caledonian basement in SW and applied apatite fission tack analysis and (U-Th-Sm)/He thermochronology to reconstruct the thermal history of the respective segments of the fault zone and their thermal evolution in respect to the deformation and opening of the northern Atlantic. Preliminary results will be presented and the exhumation history and timing of deformation and thermal anomalies in eastern North Greenland and influence of the breakup will be discussed.

How to cite: Meier, K., O'Sullivan, P., Monien, P., Piepjohn, K., Lisker, F., and Spiegel, C.: The Eurekan in eastern North Greenland: insights from thermochronology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11241, https://doi.org/10.5194/egusphere-egu22-11241, 2022.

EGU22-12218 | Presentations | GD8.2

Current geodynamics and evolution of Tjörnes transform zone, North Iceland 

Viacheslav Bogoliubskii, Evgeny Dubinin, and Andrey Grokholsky

Tjörnes transform zone (TFZ) is complicated fracture zone in North Iceland connecting Kolbeinsey ridge and Northern rift zone of Iceland. It includes several different structures such as segmented oblique rift, amagmatic rifts and oblique slip fault zones. They developed consequently since ca. 9 Ma. The aim of this work is to determine current geodynamic activity and ratio of tectonic and magmatic activity of each structure and adjacent structures of Mid-Atlantic ridge (MAR) basing on normal faults morphometric parameters and to reconstruct evolution of TFZ by physical modelling. Morphometric analysis is based on multibeam bathymetry data of Marine and Freshwater Research Institute in Iceland and ArcticDEM digital elevation model. There were collected data on more than 900 normal faults on five parameters: heave, thrust, length, distance between faults and maximum profile curvature. They reflect recent rate of horizontal and vertical deformations and morphological age of the normal fault. Heave and distance ratio shows the relative intensity of tectonic and magmatic activity. The results show that structures have different level of recent tectonic activity and therefore, are on different stages of their evolution. In addition, they have various tectono-magmatic ratio that proceeds from their development stage, width of faulting zone and mantle structure. Physical modeling is based extending setting with mineral oil that have numerical resemblance with oceanic crust in density, shear modulus and thickness. Two-layered model have elastic bottom layer, brittle top one and local heating source corresponding to Icelandic plume impulses. Initial configuration reflects two spreading segments of MAR that develop transform zone in conditions of crust thinning in direction out of Icelandic plume center. In result of their interaction is generation of overlapping spreading centers. One of them became extinct and another one develops into transtensive transform zone, which corresponds to Husavik-Flatey oblique slip fracture zone (HFFZ) and adjacent amagmatic rift. Activation of local heating source rejuvenates extinct branch of the overlap and generates subparallel to extension direction rifting fractures reconstructing Grímsey oblique rift with high magmatic activity. HFFZ activity abruptly declines. In conclusion, consequent development, activation and decline of structures correctly correlate with results of morphometric analysis and reflect the development stages of each structure. The specific current structure of TFZ is determined by initial development of overlapping spreading centers and their control by Icelandic plume magmatic impulses.

How to cite: Bogoliubskii, V., Dubinin, E., and Grokholsky, A.: Current geodynamics and evolution of Tjörnes transform zone, North Iceland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12218, https://doi.org/10.5194/egusphere-egu22-12218, 2022.

EGU22-12316 | Presentations | GD8.2

The age of monzonitoids of the Mount Yarkeu, Polar Urals: first U-Pb (LA-ICP-MS) and 40Ar-39Ar ages 

Ivan Sobolev, Ilya Vikentiev, Viktor Sheshukov, Alexandr Dubenskii, Alexey Travin, and Anastasiya Novikova

Collisional igneous units of the Carboniferous and Permian age in the Polar Urals are poorly studied. This is due to the fact that most of them are probably hidden under the Mesozoic-Cenozoic cover of the West Siberian Plate. Thin bodies of gabbroids, lamprophyres, monzonitoids, and granitoids are known (Musyur, Yarkeu, Yayu, and Pogurej complexes), which are usually attributed to the collisional stage of the Uralian orogeny. Their age, in most cases, is based on geological data and methodologically outdated K-Ar ages (Shishikin et al., 2007; Pryamonosov et al., 2001).

We have studied one of the largest intrusions in the Polar Urals attributed (Shishkin et al., 2007) to the Late Carboniferous Yarkeu complex of the West Ural megazone and considered to be collisional. The pluton is located 13 km north of Kharp township, making up most of Mount Yarkeu. The intrusion is predominantly composed of monzogabbro, monzodiorite, and monzonite which form a «ring» structure among the Neoproterozoic plagiogranitoids of the Kharbey-Sob' complex, with which they have indistinct (gradual) contacts. K-Ar dating of K-feldspar and plagioclase mix from quartz monzonite (Pryamonosov et al., 2001) yielded the age of 310±10 Ma.

To clarify the time of monzonitoids formation, we carried out additional isotope-geochronological studies using modern methods (U-Pb and Ar-Ar). From the monzodiorite sample, 48 zircon grains were dated according to the method (Nikishin et al., 2020). Discordance in all cases did not exceed 2%. The individual 206Pb-238U ages of dated grains are in the range from 650–707 Ma, and the average concordant age is 680±2 Ma (95% confidence interval, MSWD=0.35).

The 40Ar-39Ar dating of the primary magmatic amphibole from monzodiorite was carried out by the method of stepwise heating according to the standard method (Travin et al., 2009). In the high-temperature part of the age spectrum, a six-step plateau was distinguished, characterized by 83.5% of the released 39Ar and a value of 669±8 Ma (MSWD=0.62).

The new U-Pb and Ar-Ar Neoproterozoic ages are similar and correspond to the time of formation of monzodiorites in the considered pluton. The younger Carboniferous K-Ar age (310±10 Ma) obtained from feldspars (Pryamonosov et al., 2001) is probably rejuvenated. The disturbance of the K-Ar isotope system in feldspars can be explained by the significant saussuritization of plagioclase as well as the lower closing temperature of the K-Ar isotope system in plagioclase and K-feldspar compared to magmatic amphibole. Thus, the Late Carboniferous age of feldspars does not correspond to the time of formation of monzonitoids but to the dynamo-thermal events associated with the collisional stage of the Uralian orogeny (Puchkov, 2010), which occurred at the end of the assembly of the Pangea (Kuznetsov, Romanyuk, 2014).

The obtained Neoproterozoic age of monzodiorite is close to the zircon ages 671±4 Ma and 662±6 Ma from the host subduction-related diorites and plagiogranitoids of the Kharbey-Sob complex (Dushin et al., 2014). The monzonitoids of Mount Yarkeu complement the evolutionary trend of the Late Precambrian subduction-related magmatism attributed to the Neoproterozoic Kharbey-Sob' complex.

This work was supported by RFBR grant 19-55-26009.

How to cite: Sobolev, I., Vikentiev, I., Sheshukov, V., Dubenskii, A., Travin, A., and Novikova, A.: The age of monzonitoids of the Mount Yarkeu, Polar Urals: first U-Pb (LA-ICP-MS) and 40Ar-39Ar ages, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12316, https://doi.org/10.5194/egusphere-egu22-12316, 2022.

TS7 – Convergent tectonic settings

EGU22-1613 | Presentations | TS7.1

How does lithospheric strength, mantle hydration and slab flexure relate to seismicity in the southern Central Andes? 

Constanza Rodriguez Piceda, Magdalena Scheck-Wenderoth, Mauro Cacace, Judith Bott, Ya-Jian Gao, Frederik Tilmann, and Manfred Strecker

The southern Central Andes (SCA, 29°S—39°S) orogen is one of the seismically most active regions along the length of the South-American convergent margin, where past earthquakes (e.g., San Juan in 1944, Valdivia M9.5 in 1960 and M8.8 Maule in 2010) have had devastating effects on the population. Past research has extensively focused on linking the occurrence of seismic activity with the stress regime on individual faults at a local scale.  In order to more systematically address the relationship between the long-term rheological configuration of the whole lithosphere and the spatial patterns of seismic deformation in the SCA, we computed a 3D model of the expected mechanical strength and rheology (brittle, ductile) of the SCA and adjacent forearc and foreland regions based on an existing 3D model describing the first-order variations of thickness, composition and temperature of geological units forming the upper and subducting plates. We found that the spatial variation in the predicted rheology correlates well with the distribution of seismic deformation in the upper plate, with seismicity bounded to the modelled brittle deformation domain. Moreover, seismic events localize at the transition between mechanically strong and weak domains. This ultimately indicates that the strength of the lithosphere exerts a first-order control on the mechanical stability of the region.

In contrast, the results from the rheological model fail to reconcile the observed slab seismicity at depths > 50—70 km, where ductile rheological conditions are expected. In this case, we evaluated possible additional mechanisms triggering these earthquakes, including compaction of sediments at the interface, metamorphic reactions within the oceanic crust and mantle, and slab flexural stresses. To characterize the state of hydration of the mantle related to dehydration reactions and/or sediment compaction, we made use of the Vp/Vs ratio from a seismic tomography model. The majority of the slab seismicity was found to spatially correlate with hydrated areas of the slab and overlying continental mantle, apart from a cluster where the slab attains a sub-horizontal angle. In this region, the correlation between the focal mechanisms of these earthquakes and the slab orientation, suggests that seismicity here is driven by enhanced flexural stresses within the oceanic plate.

This contribution showcases the importance of a quantitative characterization of the rheological state of the lithosphere to elucidate the causative dynamics of the spatial distribution of seismicity in the area.

How to cite: Rodriguez Piceda, C., Scheck-Wenderoth, M., Cacace, M., Bott, J., Gao, Y.-J., Tilmann, F., and Strecker, M.: How does lithospheric strength, mantle hydration and slab flexure relate to seismicity in the southern Central Andes?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1613, https://doi.org/10.5194/egusphere-egu22-1613, 2022.

EGU22-2924 | Presentations | TS7.1

Multi-disciplinary assessment of the August 12, 2021, South Sandwich earthquake doublet 

Malte Metz, Angela Carillo Ponce, Felipe Vera, Simone Cesca, Frederik Tilmann, and Joachim Saul

On August 12, 2021, an earthquake doublet with a cumulative magnitude MW 8.0 – 8.3 hit the South Sandwich Trench in the South Atlantic where the South American plate is subducted beneath the Sandwich microplate. Significant differences in location, depth, and magnitude are reported by international agencies. Discrepant results might be due to the short inter-event time of ~150 s between both subevents and the lack of local and regional data.

We apply a multi-disciplinary approach to clarify the source processes and characterize different features of the doublet. Our centroid solutions of the mainshocks, separated by ~290 km, confirm the overall southward rupture directivity. The predominant thrust mechanisms, with different strike directions, suggest the activation of a bent portion of the slab. We estimate a cumulative magnitude of Mwc 7.65 inverted from body waves in the frequency band 0.01 – 0.03 Hz. Our magnitude estimate is substantially smaller than the one reported, e.g., by Global CMT, suggesting that a significant part of the moment has been released at lower frequency as a slow slip process. It is verified by a W-phase inversion in the frequency band 0.005 - 0.01 Hz with a resulting magnitude Mww of 8.0. The iterative deconvolution and stacking method (IDS) resolves high slip patches located in the area of the two mainshock centroids. High-frequency back-projection results confirm the unilateral southward rupture propagation. Complex fault and slab geometries do not significantly improve the fit, providing no clear evidence for the activation of secondary faults. Centroid moment tensors, estimated for 87 aftershocks between August 12, 2021 and August 31, 2021, support the identification and characterization of activated fault segments.

How to cite: Metz, M., Carillo Ponce, A., Vera, F., Cesca, S., Tilmann, F., and Saul, J.: Multi-disciplinary assessment of the August 12, 2021, South Sandwich earthquake doublet, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2924, https://doi.org/10.5194/egusphere-egu22-2924, 2022.

EGU22-6099 | Presentations | TS7.1

Recurrent episodes of transient deformation in NW Sulawesi, Indonesia 

Nicolai Nijholt, Wim Simons, Taco Broerse, Joni Efendi, Dina Sarsito, and Riccardo Riva

The Celebes Sea subducts beneath the North Arm of Sulawesi, Indonesia, at the Minahassa trench. Over the past three decades, only a few Mw>7 earthquakes ruptured this plate interface, despite a 40 mm/yr convergence rate. The left-lateral Palu-Koro fault delineates the extent of the overriding plate at the western termination of the Minahassa subduction zone and hosted a Mw7.5 earthquake in September 2018. Observations of post-seismic surface motion following the 2018 event were interpreted in a previous study to result from afterslip that extended underneath the co-seismic rupture plane. A mismatch between observed post-seismic surface motions and predictions from afterslip distributions remained at the North Arm of Sulawesi.

In this study we revisit and reprocess the GNSS observations in NW Sulawesi. We analyse the post-2018 time series to determine whether the post-seismic signal can be ascribed to a single source. This is not the case, as we detect another, yet smaller amplitude signal. We take a Bayesian approach and find that this smaller magnitude signal corresponds to slow slip on the Minahassa subduction interface. This delayed-triggered, (apparently aseismic) slow slip event occurred just east of the 1996 Mw7.9 megathrust rupture.

The 20-year long time series is characterized by four additional periods of transient surface motion. Three of these periods are likely the result of distinct slow slip events and one is a post-seismic signal from the 2008 subduction Mw7.4 earthquake. The presumed slow slip events generally take more than 300 days to quiet down again with a recurrence interval of about five years.

How to cite: Nijholt, N., Simons, W., Broerse, T., Efendi, J., Sarsito, D., and Riva, R.: Recurrent episodes of transient deformation in NW Sulawesi, Indonesia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6099, https://doi.org/10.5194/egusphere-egu22-6099, 2022.

EGU22-6527 | Presentations | TS7.1

Probing the structure of the flat subduction in Oaxaca, Mexico, using a temporal seismic array. 

Marco Calò, Erika Alinne Solano Hernández, Karina Bernal Manzanilla, Luisa García Gomora, Xyoli Perez-Campos, and Arturo Iglesias Mendoza

Cocos plate assumes a peculiar flat subduction beneath Mexico. Oaxaca region is the part of Mexico where the trench is closest to the coastline and where a transition from flat to a more dipping subduction plane occurs.

The closest seismic broadband seismometers existing near the coast are managed by the Mexican National Seismological Service (SSN) and consist of three stations installed over a straight coastline of Oaxaca of more than 200 km. The limited number of stations makes it very      difficult to get a detailed study of the seismicity able to provide sufficient information to characterize the events of magnitude less than 4.0-4.5 in this portion of the subduction.

In this work we show the preliminary results of a temporary network of 11 stations (9 broadband and 2 Raspberry Shakes) installed since September 2021 on the Oaxaca coast and designed to complement the coverage of the SSN stations. The two networks are now able to provide enough information to obtain refined catalogs and carry out studies that can probe the structure of the crust and upper mantle of the region with unprecedented detail.

In particular we will show the first results of the refined event locations, focal mechanisms and 3D seismic velocity models. All this information is lighting several features unknown of this portion of the Cocos plate and the overlaying North America one, opening new questions about the tectonics and geodynamics of the region.

Work supported by the PASPA-DGAPA, UNAM program, as a sabbatical year at Universidad del Mar (UMAR), Puerto Angel, by the PAPIIT-DGAPA project: IN108221, and by the internal project of the UMAR: 2II2003 and PRODEP UMAR-PTC-181.

How to cite: Calò, M., Solano Hernández, E. A., Bernal Manzanilla, K., García Gomora, L., Perez-Campos, X., and Iglesias Mendoza, A.: Probing the structure of the flat subduction in Oaxaca, Mexico, using a temporal seismic array., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6527, https://doi.org/10.5194/egusphere-egu22-6527, 2022.

EGU22-6564 | Presentations | TS7.1

Transformational Faulting in Metastable Olivine, from Lab to Slab 

Julien Gasc, Clémence Daigre, Damien Deldicque, Arefeh Moarefvand, Blandine Gardonio, Julien Fauconnier, Claudio Madonna, Pamela Burnley, and Alexandre Schubnel

     This year marks the 100th anniversary of the discovery of Deep Focus Earthquakes (DFEs). Despite the elaboration of several hypotheses, the mechanisms responsible for their occurrence at depths where rocks flow in a viscous way are not entirely elucidated. DFEs are far from ubiquitous and only occur in certain subducting slabs as they descend through the mantle transition zone, where olivine transforms to wadsleyite and ringwoodite. This has led to associating DFEs to the transformation of metastable olivine. Faulting induced by the olivine transformation was proven to cause brittle behavior under conditions where ductile deformation otherwise prevails [Burnley et al., 1991]. It can also explain the anomalously high DFE activity in Tonga, which has been attributed to the thermal state of the subducting slab, colder slabs allowing for more metastable olivine.

     However, there are limited data regarding the conditions required for transformational faulting in terms of reaction kinetics, as well as regarding its possible propagation in ringwoodite peridotites. The seminal work of Burnley, Green and co-authors regarding transformational faulting used a Ge-olivine analogue, a material that undergoes the transition to the ringwoodite structure (Ge-spinel) at much lower pressures than the silicate counterpart [Burnley et al., 1991]. Here we continue to build upon this work by combining high pressure and temperature deformation experiments with Acoustic Emission (AE) monitoring. The experiments investigate lower temperatures and strain rates to assess the extrapolation of transformational faulting towards natural conditions. Ge-olivine samples were deformed in the Ge-spinel field at 1.5 GPa and various temperatures in a modified Griggs apparatus.

     We demonstrate that transformational faulting can initiate in metastable olivine, and then continue to propagate via shear-enhanced melting in the stable high-pressure phase, which is a paramount finding since transformational faulting has been contested as the origin of DFEs on the basis that large DFEs cannot be contained within a metastable olivine wedge. The experiments yielded a range of mechanical behaviors and acoustic signals depending on the kinetics of the olivine-ringwoodite transformation. The b-values associated with the obtained AEs range from 0.6-1.5, consistent with those of DFEs. In addition, we evidence that transformational faulting is controlled by the ratio between strain rate and reaction kinetics and extrapolate this relationship to the natural conditions of DFEs. Counterintuitively, these results imply that cold slabs induce transformational faulting at higher temperatures as a result of faster descent rates. This produces more numerous small DFEs and explains the higher b-values observed.

Burnley, P. C., H. W. Green, and D. J. Prior (1991), Faulting Associated With The Olivine To Spinel Transformation In Mg2geo4 And Its Implications For Deep-Focus Earthquakes, Journal of Geophysical Research-Solid Earth and Planets, 96(B1), 425-443.

How to cite: Gasc, J., Daigre, C., Deldicque, D., Moarefvand, A., Gardonio, B., Fauconnier, J., Madonna, C., Burnley, P., and Schubnel, A.: Transformational Faulting in Metastable Olivine, from Lab to Slab, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6564, https://doi.org/10.5194/egusphere-egu22-6564, 2022.

EGU22-6888 | Presentations | TS7.1

First analysis of shallow tremors in the Guerrero seismic gap. 

Raymundo Plata-Martinez and Yoshihiro Ito

The Guerrero seismic gap, at the Mexican subduction zone, has been a region of great seismological interest because of the absence of a large earthquake in more than 110 years. If an earthquake were to rupture the entire Guerrero seismic gap the resulting earthquake could be disastrous to major Mexican cities. Additionally, the Guerrero subduction zone has plenty of slow earthquake activity with large slow slip events and tectonic tremors, located at the deep plate interface. To obtain a new and unique observation point of seismicity in the Guerrero seismic gap and continue evaluating its seismic risk, we deployed an array of ocean bottom seismometers (OBS) offshore the Guerrero seismic gap. We were able to detect and locate shallow tremors near the trench and deduce that a portion of the shallow plate interface undergoes stable slip. We used data from the OBS to analyse the new catalogue of shallow tremors and describe their source. Focal mechanisms of shallow tremors were estimated using S wave polarisation. We found that slip azimuth tends to follow the subduction plate motion, suggesting that tremors rupture at the plate interface. We also estimated shallow tremor radiated seismic energy. We found a heterogeneous energy release of shallow tremors along strike. Our observations of a heterogeneous shallow tremor energy release can be explained with the different mechanical properties, inside and outside the Guerrero seismic gap, and help to characterise the seismogenic zone at the shallow plate interface.

How to cite: Plata-Martinez, R. and Ito, Y.: First analysis of shallow tremors in the Guerrero seismic gap., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6888, https://doi.org/10.5194/egusphere-egu22-6888, 2022.

EGU22-8542 | Presentations | TS7.1

Back-arc thrusting in the Jakarta basin 

Sonny Aribowo, Laurent Husson, Christophe Basile, Danny H. Natawidjaja, Christine Authemayou, Mudrik R. Daryono, and Manon Lorcery

The Java subduction megathrust is undoubtedly the source of high magnitude, extremely damaging earthquakes. In the back-arc of the subduction zone, severe earthquakes also affect the northern part of Java. The Jakarta basin lies at the western end of the Java back-arc thrust, which stems on the seismogenic Flores thrust in the east and propagates westward across Java. The tectonic activity of the Java Back-arc Thrust in the Jakarta basin has been overlooked because of its low recurrence time. Yet, historical records reveal that it was destructive, resulting in severe destruction in Bogor and Jakarta. Tracking fault activity in large cities is problematic because the original landscape is often profoundly anthropized and has little to do with its pre-industrial physiography. In the Jakarta basin, this is even more complex owing to the fast Plio-Quaternary sedimentation that conceals the morphotectonic features associated with the fault. We combine geomorphic observations and subsurface data using DEMs and optical imagery, seismic reflection and biostratigraphic well data. At depth, seismic data reveal a partitioned fault network of compressive fault-propagation folds and transpressive flower structures that deform the Plio-Quaternary sedimentary layers of the Jakarta basin and interplay with volcanoes. At the surface, morphological observations in the rims of the basin reveal that several river meanders were abandoned and uplifted hundreds of meters above the current riverbeds above the fault network. In the basin, multiple meter scale waterfalls that we interpret as knickpoints above active faults scar the flat surface of the basin. We conclude that the western end of the Java back-arc thrust fault bears a potentially high risk for the infrastructures of the densely populated province of Jakarta.

How to cite: Aribowo, S., Husson, L., Basile, C., Natawidjaja, D. H., Authemayou, C., Daryono, M. R., and Lorcery, M.: Back-arc thrusting in the Jakarta basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8542, https://doi.org/10.5194/egusphere-egu22-8542, 2022.

EGU22-8846 | Presentations | TS7.1

Testing the Strain-rate Hypothesis for Deep Slab Seismicity 

Magali Billen, Rebecca Fildes, Marcel Thielmann, and Menno Fraters

The occurrence of deep earthquakes within subducting lithosphere (slabs) remains enigmatic because these earthquakes have many similarities to shallow earthquakes, yet frictional failure is strongly inhibited at high pressure. Regardless of depth, earthquakes occur where the temperature is cold enough that elastic deformation is accumulated over time: for frictionally controlled earthquakes at shallow depth, the rate of seismic moment release is correlated with the strain-rate. Comparison of spatial variation in strain-rate magnitude from 2D simulations of subduction to observed seismicity versus depth profiles suggest that strain-rate may also be a determining factor in the occurrence of deep slab seismicity (1). In addition, proposed mechanisms for deep earthquakes, including transformational faulting of metastable olivine and thermal shear instability, are known to depend directly on strain-rate. To test the hypothesis that strain-rate is a determining factor in the spatial distribution of deep earthquakes, we are creating 2D models of subduction with visco-elasto-plastic (VEP) rheology and a free surface in the software ASPECT (2). The 2D slab structure is constructed for specific locations in which the slab geometry is extracted from Slab 2.0 (3) and the plate age and convergence rate are used to define the thermal structure using a new mass-conserving slab temperature model (4) implemented in the Geodynamic WorldBuilder (5). The resulting strain-rate and stress, together with the pressure and temperature along multiple transects of the slab are used as input values for a 1D thermal shear instability model (6) using the same VEP rheology as the slab deformation models.  Using this approach we can test whether the conditions in the slab favor failure through thermal shear instability and compare the spatial distibution to obsered seismicity. Initial results of this workflow will be presented, including how we have overcome some of the challenges in running VEP models for comparison to present-day slab seismicity. References: 1. Billen, M. I. , Sci. Advances, 2020. 2. Bangerth, W. et al., https://doi.org/10.5281/ZENODO.5131909, 2021. 3. Hayes, G.P. et al., Science, 2018. 4. Billen, M. I. and Fraters, M. R. T., EGU Abstract, 2022. 5. Fraters, M. R. T. et al., Solid earth, 2019. 6. Thielmann, M. Tectonophysics, 2018. 

 

How to cite: Billen, M., Fildes, R., Thielmann, M., and Fraters, M.: Testing the Strain-rate Hypothesis for Deep Slab Seismicity, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8846, https://doi.org/10.5194/egusphere-egu22-8846, 2022.

The occurrence of deep-focus earthquakes (h > 300 km) is restricted to a handful of regions worldwide, generally associated with subduction zones. In particular, the South American subduction zone hosts two narrow belts of deep-focus seismicity with depths greater than ~500 km along the Peru-Brazil border and Bolivia/northern Argentina. This subduction zone has a thermal parameter of Φ < 2500 km and is regarded as a warm end-member. Only in 2015, the USGS catalog listed up to 25 deep-focus events in the Peru-Brazil belt, with magnitudes and depths ranging from 4.0 to 7.6 Mw and 515 to 655 km, respectively. Notably, this sequence included a well-investigated doublet of two 7.6 Mw events occurring 5 min apart trailed by a number of aftershocks of magnitude 4.0 Mw or larger. Published focal mechanisms for the main doublet display predominantly double-couple components that closely agree with the GCMT solution (E1: 350°, 39°, -80° and E2: 350°, 30°, -81°), suggesting shear failure at those depths. Mechanisms capable of shear instability at those large depths traditionally include dehydration embrittlement, transformational faulting, thermal runaway or a combination of those. Aiming at investigating the physical mechanism responsible for these deep-focus events, we are using a combination of regional and teleseismic recordings from the Brazilian Seismographic Network (RSBR) and other regional and national networks in the continent to determine focal mechanisms for deep-focus earthquakes (M > 4) that occurred between 2014 and 2022. The mechanisms are being determined through a Cut and Paste approach, which compensates for inaccuracies in the velocity model through independent relative time shifts between observations and predictions for P, SV and SH wave trains sampling both the upper and lower hemispheres of the focal sphere. The results on the 2015 doublet, using the full dataset (regional and teleseismic stations), indicated two very similar normal faults fully consistent with the GCMT solutions, at the preferred depths of 616 (E1) and 621 (E2) km. Preliminary inversions using only regional networks (RSBR) for 15 smaller earthquakes (4.3 < M < 7.1) also yield normal mechanisms with T axes oriented roughly E-W. This apparent uniformity of the focal mechanisms for the South-American deep-focus earthquakes, with near-vertical P axes and near-horizontal (east-west-oriented) T axes, strongly suggests vertical compression along the subducting plate is the main source of stress driving deep-focus seismicity. Down-dip compression is expected from either buoyancy forces, equilibrium phase transformations or a metastable olivine wedge (MOW); however, how earthquakes are nucleated at those depths is harder to explain. Transformational faulting within the MOW has been the preferred mechanism in cold slabs, while in warm slabs its presence has been more debated due to wedge size being expected to decrease with temperature. Transformational faulting in other metastable minerals such as enstatite is our preferred alternative, as dehydration embrittlement and thermal runaway seem to lack the capacity of triggering earthquakes at those large depths.

How to cite: Leite Neto, G. and Julià, J.: Investigating Source Mechanisms of Deep-Focus Earthquakes at the Peru-Brazil Border with Regional and Teleseismic Data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9820, https://doi.org/10.5194/egusphere-egu22-9820, 2022.

EGU22-11060 | Presentations | TS7.1

Megathrust Seismicity Through the Lens of Explainable Artificial Intelligence 

Juan Carlos Graciosa, Fabio Antonio Capitanio, Mitchell Hargreaves, Thyagarajulu Gollapalli, and Mohd Zuhair

Understanding the controls on large magnitude seismicity occurrence remains an open challenge, yet a pressing one, for the exceptional hazard associated with earthquakes. Different parameters are proposed to exert control on the generation and propagation of megathrust earthquakes and untangling their complex interactions across scales remains challenging. Here, we use explainable artificial intelligence to unravel the interactions between different parameters and elucidate the underlying mechanisms. We use three types of datasets from a number of convergent margins: a) a catalogue of earthquake hypocentre and rupture, b) geophysical observations of subduction zones properties (e.g., gravity, bathymetric roughness, sediment thickness), and c) the distribution of stress within the slab due to slab pull calculated from flexure models. These constitute the three types of nodes in the input layer of a Fully Connected Network (FCN) trained to classify earthquake magnitude embedding the state of the system (b), the driving mechanism (c) and the resulting seismicity (a). We then analyse the trained network using Layer-wise Relevance Propagation (LRP) to determine the relative weights of the input nodes, providing relevant constraints on the mechanisms that dominate the seismicity in a region, their scale and likelihood.

How to cite: Graciosa, J. C., Capitanio, F. A., Hargreaves, M., Gollapalli, T., and Zuhair, M.: Megathrust Seismicity Through the Lens of Explainable Artificial Intelligence, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11060, https://doi.org/10.5194/egusphere-egu22-11060, 2022.

EGU22-11670 | Presentations | TS7.1

From the Izu-Bonin to the north of Hokkaido : how did the M9.0 Tohoku earthquake affect the Pacific plate seismicity ? 

Blandine Gardonio, David Marsan, Stéphanie Durand, and Alexandre Schubnel

The last twenty years have seen a number of large, devastating earthquakes on subduction zones. In many ways, the M9.0 Tohoku-oki earthquake was bewildering for the seismological community. It occurred on a previously identified coupled area but ruptured a larger zone than expected and, above all, the large amount of near-trench coseismic slip was a surprise.

Because Japan is one of the best area instrumented in the world, the 2011 Mw 9.0 Tohoku-oki earthquake is one of the world's best-recorded ruptures. Many studies have analyzed with great details the pre-seismic, co-seismic and post-seismic phases of the Tohoku earthquake. Researchers also focused on the triggering of on-land seismicity following the mega-thrust earthquake. However, no study zoom out and considered the consequences of this earthquake on the Pacific plate in this area.

 

In this study, we analyzed the Japanese Meteorological Agency seismic catalog over ten years of data to assess the consequences of such large mega-thrust earthquake over the Pacific plate from the Izu-Bonin area to the north of Hokkaido island. We studied the seismicity from 0 to 700km depth, taking advantage of one of the most complete subduction zone catalogue.

Our results show that the seismic rate south of Japan experienced a decrease at the time of Tohoku about 30% and an increase of 20% underneath the Hokkaido island. The subduction zone that is downdip Tohoku doesn’t seem affected by the megathrust earthquake. While it is difficult to understand and to model such large scale effects of the Tohoku earthquake on the Pacific plate, we think it is primordial to observe and detail them with precision.

How to cite: Gardonio, B., Marsan, D., Durand, S., and Schubnel, A.: From the Izu-Bonin to the north of Hokkaido : how did the M9.0 Tohoku earthquake affect the Pacific plate seismicity ?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11670, https://doi.org/10.5194/egusphere-egu22-11670, 2022.

EGU22-11762 | Presentations | TS7.1

Crushed and fried: ductile rupture at depth due to grain size reduction and shear heating 

Marcel Thielmann and Thibault Duretz

Since their discovery in 1928, deep earthquakes have been the subject of extensive research to unravel their nucleation and rupture mechanisms. Due to the elevated pressures and temperatures at depths below 50 km, brittle failure becomes less likely and ductile deformation is favored. To date, there is no consensus on the mechanisms resulting in deep earthquake generation. Three main mechanisms (dehydration embrittlement, transformational faulting and thermal runaway) have been proposed to cause deep earthquakes, but neither of them has been sufficiently quantified to yield a definite answer under which conditions they are active.

Here, we explore the feasibility of the thermal runaway hypothesis using 1D and 2D thermo-mechanical models. In particular, we investigate the impact of grain size reduction in conjunction with shear heating to see whether grain size reduction and shear heating are competitive mechanisms (which would prevent thermal runaway) or whether they are collaborative. Our results show that the combination of both mechanisms facilitates thermal runaway and significantly reduces the stress required for the occurrence of thermal runaway. We then investigate whether this combined failure mechanism may explain the seismicity observed in regions of detaching lithosphere, such as the Hindu Kush and the Vrancea earthquake nests. 

How to cite: Thielmann, M. and Duretz, T.: Crushed and fried: ductile rupture at depth due to grain size reduction and shear heating, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11762, https://doi.org/10.5194/egusphere-egu22-11762, 2022.

EGU22-12386 | Presentations | TS7.1

Lithospheric structure in and around Slow Slip in the Alaska Subduction Region 

Pousali Mukherjee and Yoshihiro Ito

Subduction zones host some of the greatest megathrust earthquakes in the world. Slow earthquakes have been also discovered around the subduction zones of the Pacific rim very close to megathrust earthquakes in several subduction zones in Chile, Cascadia, Mexico, Alaska, and New Zealand (Obara and Kato, 2016). Investigating the lithosphere of the slow earthquake area versus non slow-earthquake areas in subduction zones is crucial in understanding the role of the internal structure to control slow earthquakes. Deep transient slow slip had been detected in the Lower and Upper Cook Inlet in the Alaska subduction region(Fu et al. 2015; Li et al. 2016; Wei et al. 2012). In this study, we investigate the lithospheric structure beneath the stations in and around the slow earthquake area in Alaska. We also study the non slow-earthquake areas in the Alaska subduction zone using receiver function analysis and inversion method using teleseismic earthquakes. Here we focus on, especially the Vs and Vp/Vs ratios from both the slow and non-slow earthquake areas, because of the sensitivity  to the fluid distribution in the lithosphere; the fluid distribution possibly controls the potential occurrence of slow earthquakes.
Additionally, the nature of the slab can also play a crucial factor. The velocities around the plate interface region in the lower continental mantle, subducted oceanic crust and upper oceanic mantle has the potential to reveal information that the structural heterogeneity could be related to the slow slip.

How to cite: Mukherjee, P. and Ito, Y.: Lithospheric structure in and around Slow Slip in the Alaska Subduction Region, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12386, https://doi.org/10.5194/egusphere-egu22-12386, 2022.

An increase of both shallow and intraslab intermediate-depth seismicity has been observed days to years before some great subduction earthquakes, as before Tohoku-oki (Mw 9.0, 2011), Maule (Mw 8.8, 2010) or Iquique (Mw 8.2, 2014) earthquakes (Bouchon et al., 2016, Jara et al,. 2017). These observations suggest that a link exists between these deep and shallow foreshocks, but it is still poorly understood and not characterized in a systematic manner. Some studies have attempted to address this lack of systematic characterization by using a statistical approach (Delbridge et al., 2017).

The aim of this study is to systematically and statistically identify and characterize the potential correlations between deep and shallow seismicity. We want to assess whether or not such interactions exist. If they exist, we plan to characterize when and where they occur, at what frequency, their characteristic duration, and with what spatial pattern.  

For this purpose, we develop a statistical method to assess the relevance of deep-shallow interactions, that allows to identify statistically significant correlations between deep and shallow seismicity. We focused on the seismicity of the Japan trench subduction zone during the decade prior to the Tohoku-oki earthquake, because deep-shallow interactions were identified there, and because we can test the events picked by our method against the correlations highlighted in published papers (Bouchon et al., 2016). The correlation values between the deep and shallow events from the Japan Meteorological Agency catalog are calculated on various different sliding-windows with durations from month to week. These correlation values are then compared to the ones obtained using synthetic series of shallow events that meet the spectral properties of the real series, and the significance of the correlation is calculated.

Some windows show a strong correlation. The dependence of our results to different parameters, such as the completeness magnitude, the length of the window, the lag, the smoothing etc… are evaluated. The spatio-temporal analysis of the seismicity on maps for these windows is also explored. While the results are still preliminary, we believe that this method has the potential to systematically and quantitatively assess the current presumptions on the link between deep and shallow seismicity, that would lead to a better understanding of the mechanisms leading to megathrust earthquakes.

 

Bouchon, M., Marsan, D., Durand, V., Campillo, M., Perfettini, H., Madariaga, R., & Gardonio, B. (2016). Potential slab deformation and plunge prior to the Tohoku, Iquique and Maule earthquakes. Nature Geoscience, 9(5), 380.

Delbridge, B. G., Kita, S., Uchida, N., Johnson, C. W., Matsuzawa, T., & Bürgmann, R. (2017). Temporal variation of intermediate‐depth earthquakes around the time of the M9. 0 Tohoku‐oki earthquake. Geophysical Research Letters, 44(8), 3580-3590.

Jara, J., Socquet, A., Marsan, D., & Bouchon, M. (2017). Long-Term Interactions Between Intermediate Depth and Shallow Seismicity in North Chile Subduction Zone. Geophysical Research Letters, 44(18), 9283-9292.

How to cite: Chouli, A., Marsan, D., Giffard-Roisin, S., Bouchon, M., and Socquet, A.: Analysis of the potential correlation between intraslab intermediate-depth and shallow earthquakes in the Japan trench subduction zone prior to the Mw 9.0 Tohoku-oki earthquake, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12565, https://doi.org/10.5194/egusphere-egu22-12565, 2022.

EGU22-104 | Presentations | TS7.2

Evidence of back folding in the Himachal Himalaya: A reassessment of the tectonic models in light of new evidence 

Arun Ojha, Deepak Srivastava, and Gordon Lister

Understanding how the geological architecture of the Himalaya has been constructed demands well-constrained tectonic models supported and validated by field observations. The channel flow model has been used to explain the structural architecture in many different sectors of the Himalaya. However, the model appeared to have failed in the classic example of the Himachal Himalaya, so in 2007 Webb proposed the Tectonic Wedge Model. But the key to this model is the existence of a regional-scale recumbent anticline, illustrated in many different papers and in textbooks. This structure is known variously as the Phojal fold, or the Sikhar nappe, or the Kalath anticline. Webb’s Tectonic Wedge Model requires the South Tibetan Detachment (STD) to also be recumbently folded, along with the Phojal fold. Our detailed field observations are contrary to the regional structures proposed in the existing models. First, it is evident that ‘photo geology’ has produced an optical illusion. Field mapping shows that the Phojal Fold is a north-east vergent reclined back fold. Thus, despite having been developed on the km-scale, the Phojal Fold has nothing to do with the formation of the earlier formed recumbent folds. There is no doubt that an early period of recumbent folding has produced regional-scale structures in the NW Himalaya. These folds post-date the first recognized period of Barrovian metamorphism. However, because the axial-plane cleavage of the recumbent folds is a pressure-solution cleavage, it can be inferred that these metamorphic rocks had cooled and been exhumed to shallow crustal levels prior to the start of the early recumbent folding event. The second period of Barrovian metamorphism was associated with the STD, which post-dates the earlier recumbent folds, but pre-dates back folding. The underpinning of the Tectonic Wedge Model has been removed. Hence the validity of the model is on trial.

How to cite: Ojha, A., Srivastava, D., and Lister, G.: Evidence of back folding in the Himachal Himalaya: A reassessment of the tectonic models in light of new evidence, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-104, https://doi.org/10.5194/egusphere-egu22-104, 2022.

EGU22-110 | Presentations | TS7.2

Burial and exhumation history of the Georgian sector of the central Greater Caucasus 

Thomas Gusmeo, William Cavazza, Massimiliano Zattin, Sveva Corrado, Andrea Schito, Victor Alania, and Onise Enukidze

The integration of low-temperature thermochronological and thermal maturity analyses constrains the maximum temperatures experienced during burial by the sedimentary fill of the central sector of the Greater Caucasus basin and the timing of its structural inversion. Raman spectroscopy, illite percentage and stacking order in illite-smectite mixed layers, illite crystallinity index, and Rock-Eval Pyrolysis analyses indicate that the maximum paleotemperatures experienced by the Greater Caucasus basin fill increase progressively from about 100 °C in the southern foothills of the central Greater Caucasus to close to 400 °C approaching the axial zone of the orogen. Apatite fission-track and apatite and zircon (U-Th)/He analyses along the same transect yielded ZHe ages between about 137 and 5 Ma, AFT central ages between about 37 and 4 Ma, and AHe ages between about 10 and 2 Ma, with progressively younger ages approaching the axial zone of the Greater Caucasus. Statistical inverse modelling of thermochronological data, integrating thermal maturity results and all other geological and geochronological constraints available, points to episodic exhumation during structural inversion of the central Greater Caucasus basin. Such basin was first partially inverted in Late Cretaceous/Paleocene times following Northern Neotethys closure along the Sevan-Akera suture zone; renewed basin inversion occurred since Middle-Late Miocene times as a consequence of far-field compressional stress transmission from the Arabia-Eurasia hard collision along the Bitlis-Zagros suture zone. It should be emphasised that this sequence of events applies only to the central portion of the Greater Caucasus and by no means should be extended to the other parts of such a large and complex orogenic system.

How to cite: Gusmeo, T., Cavazza, W., Zattin, M., Corrado, S., Schito, A., Alania, V., and Enukidze, O.: Burial and exhumation history of the Georgian sector of the central Greater Caucasus, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-110, https://doi.org/10.5194/egusphere-egu22-110, 2022.

Fold and thrust belts and prominent orogens are found primarily along continental plate boundaries. Our knowledge of how these orogens are formed is based on the deformation of the upper crust. However, continental interiors also exhibit fold and thrust belts that may not be related to plate boundary collision. In these intraplate settings, structural heterogeneities in the deep lithosphere have been identified as an important factor in the formation of these belts. Particularly, inherited deep zones of weakness may initiate orogenesis in continent interiors. Aside from structural heterogeneity, the rheological strength of the lithosphere also has a primary role affecting the kinematics of deformation in the lithosphere. To investigate the interplay of rheology and pre-existing structures, we designed a set of physical scaled analogue experiments in a convergent setting that tests (a) the presence and absence of a pre-existing weak zone in the lithospheric mantle and (b) the effects of the rheological strength of the lithospheric mantle. The tectonic evolution of the model is recorded to acquire a time series data set of the velocity field, strain in the model, and the development of structures in the upper crust. Results show that a weak zone in the lithospheric mantle allows deformation to be accommodated by displacement along this zone and is transferred into the overlying lower and upper crust, regardless of lithosphere strength. In contrast, a model absent of a weak zone accommodates deformation by folding and thickening of the viscous layers. The viscous lithosphere in models with a strong lithospheric mantle tends to buckle creating a sequence of brittle faults in the upper crust. Specifically, the rheology of the lithosphere dictates the distribution of strain. Our results are further used to interpret the genetic formation of an intracontinental fold and thrust belt found on Ellesmere Island in the Canadian Arctic Archipelago.

How to cite: Santimano, T. and Pysklywec, R.: Fold and thrust belts in an intraplate setting- An interplay between rheology and inherited deep structures., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3252, https://doi.org/10.5194/egusphere-egu22-3252, 2022.

EGU22-3639 | Presentations | TS7.2

The deformation pattern of subducting seamount: insights from the structural evolution of the Late Cretaceous Durkan Complex in the North Makran domain (Makran Accretionary Prism, SE Iran) 

Edoardo Barbero, Luca Pandolfi, Morteza Delavari, Asghar Dolati, Maria Di Rosa, Federica Zaccarini, Emilio Saccani, and Michele Marroni

The occurrence of topographic relief along the subducting plate is thought to play a significant role in controlling the architecture and the deformation processes of subduction complexes Seamounts and seamounts chain represent topographic reliefs of the seafloor whose ultimate fate is the interaction with subduction complexes at convergent plate boundaries. Geophysical data (e.g., von Huene & Lallemand, 1990) and numerical modeling (e.g., Ruh et al., 2016) demonstrate that subducting seamounts contribute to modify the frontal part of the subduction complexes controlling the morphology of the frontal wedge, the fore-arc subsidence, the deformation and stress pattern, the triggering of tectonic erosion, as well as the migration and localization of the basal décollement. Complementary data with respect to geophysics and numerical modeling dataset can be derived from structural investigations on seamounts accreted in ancient accretionary prism or within collisional belts.

Here, we present the results of a multiscale (from map- to micro-scale) structural study of the western Durkan Complex in the Makran Accretionary Prism (SE Iran) that has been recently interpreted as including fragments of Late Cretaceous seamounts with the aim to shed light on the mechanism of accretion of seamount materials and the factors controlling the localization and propagation of the basal décollement. The results from the Durkan Complex indicate a polyphase deformation history characterized by three main deformative phases (D1, D2, and D3), likely occurred from the Late Cretaceous to the Miocene-Pliocene (?). The D1 is characterized by sub-isoclinal to close folds associated to an axial plane foliation and shear zone, and likely represents the underplating of seamount fragments at shallow to intermediate levels of the Makran accretionary prism. The D1 shear zones are preferentially composed of volcaniclastic rocks derived from successions representing seamount slope and cap. The D2 deformation stage is characterized by open to close folds with sub-horizontal axial plane and likely developed during the progressive exhumation up to shallow structural levels of previously accreted seamount fragments. The D1 and D2 structures are unconformably sealed by a late Paleocene – Eocene siliciclastic succession that is, in turn, deformed by W-verging thrust faults typical of the D3 phase. This phase likely testifies for a Miocene (?) -Pliocene (?) tectonic rework of the accreted seamount fragments with the activation of out-of sequence thrusts.

In conclusion, our findings indicate that seamounts are deformed within subduction complexes during the underplating and subsequent exhumation at shallower structural levels. As a general rule, the stratigraphic architecture of the subducting seamount, in particular the occurrence of thick volcaniclastic successions, likely controls the position of the basal décollement of the prism during the underplating phase.

 

Ruh, J. B., Sallarès, V., Ranero, C. R., Gerya, T., 2016. Crustal deformation dynamics and stress evolution during seamount subduction: High-resolution 3-D numerical modeling. Journal of Geophysical Research: Solid Earth 121(9), 6880–6902. https://doi.org/10.1002/2016JB013250

von Huene, R., Lallemand, S., 1990. Tectonic erosion along the Japan and Peru convergent margins. Geological Society of America Bulletin 102 (6), 704-720.

How to cite: Barbero, E., Pandolfi, L., Delavari, M., Dolati, A., Di Rosa, M., Zaccarini, F., Saccani, E., and Marroni, M.: The deformation pattern of subducting seamount: insights from the structural evolution of the Late Cretaceous Durkan Complex in the North Makran domain (Makran Accretionary Prism, SE Iran), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3639, https://doi.org/10.5194/egusphere-egu22-3639, 2022.

EGU22-3681 | Presentations | TS7.2

Significance of the northern Andean Block extrusion and genesis of the Interandean Valley: Paleomagnetic evidence from the “Ecuadorian Orocline” 

Gaia Siravo, Fabio Speranza, Maurizio Mulas, and Vincenzo Costanzo Alvarez

GPS data suggest that the NW South America corner forms a semi-rigid and distinct tectonic block (Northern Andean Block) drifting at 0.6 cm/yr NE-ward along regional dextral strike-slip faults that bound an oceanic terrane accreted in Late Cretaceous times to western Ecuador and Colombia. This is consistent with an average 0.76 cm/yr Quaternary slip rate obtained from field investigation along the main strike-slip faults. Nevertheless, pure thrust tectonics characterize the external (eastern) Northern Andes deformation front from Ecuador to Colombia. Thus, the relevance of strike-slip versus thrust tectonics during Cenozoic times and their relation with oceanic terrane accretion are unclear. 

The incertitude on the magnitude of a hypothetical Cenozoic strike-slip deformation is reflected by the variable interpretations of the tectonic regime that generated the Ecuadorian Interandean Valley. This tectonic depression, blanketing the eastern side of the Cordillera Occidental, has been variably considered as due to extensional, thrust, or strike-slip tectonics.

Paleomagnetism may represent an important tool to unravel the Cenozoic tectonic history of the Northern Andean Block, as peculiar patterns of vertical axis rotations arise from strike-slip and thrust tectonics.

Here we report on the paleomagnetism of 31 mid-upper Eocene to upper Miocene mainly volcanic sites from the Cordilleras Occidental and Real of southern Ecuador. Eleven sites show that the western Cordillera Occidental underwent a 24°±10° clockwise (CW) rotation with respect to South America after late Miocene, while no rotation occurred further east. We relate the regional CW rotation to the emplacement of the Cordillera Occidental nappe onto the continental sediments of the Interandean Valley. As rotation and continental sedimentation onset ages are similar, we interpret such tectonic depression as a narrow flexural basin formed ahead of the advancing nappe front.

Previous authors find a post-Cretaceous 28°±9° CW rotation of the Coastal forearc that is statistically indistinguishable from the 24°±10° Neogene CW rotation documented by us in the Cordillera Occidental and Interandean Valley, implying that the whole W Ecuador Andean chain was detached and rotated over a mid-crustal detachment during the last 10 Ma. Eocene-Miocene paleomagnetic inclination values are systematically consistent with those expected for South America, thus excluding latitudinal terrane drift. Our results show that thrust tectonics prevailed over strike-slip displacement in the southern Ecuadorian Andes during the late Cenozoic.

Finally, we note that the orogenic reentrant-salient sequence of the Nazca trench / Andean chain from northern Chile to Ecuador mimics closely the margin of the Archean–Paleoproterozoic Amazonian Craton and other minor cratons of South America. Considering our results on a continental scale and in combination with previous paleomagnetic data from the Andean belt we infer that the stiff crust of the Amazonian Craton behaved as a foreland indenter, hampered inland deformation propagation, and caused the formation of what we call the “Ecuadorian Orocline”, arisen by opposite-sign nappe rotations around the Craton apex.

How to cite: Siravo, G., Speranza, F., Mulas, M., and Costanzo Alvarez, V.: Significance of the northern Andean Block extrusion and genesis of the Interandean Valley: Paleomagnetic evidence from the “Ecuadorian Orocline”, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3681, https://doi.org/10.5194/egusphere-egu22-3681, 2022.

EGU22-4105 | Presentations | TS7.2

The Jura Fold-and-Thrust Belt: timing and kinematic of faulting and thrusting 

Jon Mosar, Marc Schori, Sandra Borderie, Louis Hauvette, Adeline Marro, Omar Radaideh, Anna Sommaruga, and Anina Ursprung

The Jura Mountains in France and Switzerland are a classical thin-skinned fold-and-thrust belt (FTB), which developed as part of the Alpine orogenic foreland, together with the Western Alpine Molasse Basin. The Molasse Basin initiated as a flexural basin and evolved into a wedge-top Basin following the initiation of the main foreland décollement level. The Jura FTB thus forms the frontal portion of the Alpine foreland, which enjoyed a transport of some 30km towards the foreland along the main décollement in the mechanically weak Triassic salt-rich evaporites.

Overall the Jura FTB behaves as a mechanical wedge in hydrostatic conditions, that is propagating towards the Alpine foreland. Wedge-internal accommodations, due to changes in the surface topography and the basal décollement inclination, as well as in the basal friction, are operated by oscillating forward and backward stepping sequences of thrusting and related fold development. Basement topography associated with inherited faults leads to a kinematic preconditioning of the structures developing in the detached cover. Analogue modelling has helped show that oblique steps in the basement topography lead to the formation of normal and reverse faulting and oblique fold structures in the cover.

Herein we will discuss the link of different types of faults observed in the field, such as normal faults, inverted inherited faults, thrust faults and strike-slip faults, to major tectonic processes such as flexural bending, rifting, faulting due to steps in basement topography, and thrusting inside a mechanical wedge.

Works on relative chronology of faults, combined with new results from kinematic section modelling and data on published and new deformation ages from calcites (using U-Pb) make it possible to assess the timing of deformation. It is thus possible to show that thrust faults and strike-slip faults, as well as, normal and inverted faults were active at different times and witness superposed events. Deformation in the Jura FTB is partitioned and distributed along discrete faults that clearly operate in a forward and backward oscillating manner. We further can identify different structural domains that can be considered as distinct tectonic nappes. These domains are bound by major strike-slip faults (acting as inherited, rigid boundaries), progressive en-echelon relay zones and major thrusts. The present-day deformation involving both the detached cover and the mechanical basement will be discussed.

How to cite: Mosar, J., Schori, M., Borderie, S., Hauvette, L., Marro, A., Radaideh, O., Sommaruga, A., and Ursprung, A.: The Jura Fold-and-Thrust Belt: timing and kinematic of faulting and thrusting, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4105, https://doi.org/10.5194/egusphere-egu22-4105, 2022.

EGU22-4607 | Presentations | TS7.2

Tectonics of the Western Jura Fold-and-Thrust Belt: from the Geneva Basin to the Bienne Valley (France). Mapping and forward modelling. 

Adeline Marro, Anna Sommaruga, Louis Hauvette, Sandra Borderie, Marc Schori, and Jon Mosar

The arcuate Jura Mountains Fold-and-Thrust Belt (FTB) is situated in the NW Alpine Foreland and its formation is related to the Alpine orogeny. The western part of the Jura FTB, investigated here, is situated in France to the north of the Geneva Basin (Switzerland). The geothermal project “GEothermie2020”  of the larger Geneva area allowed us to re-assessed the structural geology and the kinematic evolution of the internal part of Western Jura FTB from the Geneva Basin (Switzerland) to the Bienne Valley (France).

Stratigraphic harmonization, new geological and tectonic maps, new seismic interpretation, and a new near top Basement surface were used to construct a kinematic model. This model using forward modelling techniques has been developed in the software Movetm by Petroleum Experts. The forward model relies on fault-bend fold, trishear, and fault-parallel flow algorithms, and provides a valid and balanced cross-section. The model is constrained by surface, well and seismic data. Therefore, the depth of the near base Mesozoic horizon has been well constrained by seismic depth-converted lines. Thus, we can show, that the top basement under the Jura domain is dipping 1.7° to the SE, whereas under the Geneva Basin it is dipping between 2.7°-3.3° to the SE. The results of our modelling show a shortening of 23.6 km for the western Internal Jura FTB along a basal detachment and a forward stepping deformation accompanied by minor back-stepping thrust sequences. The first deformation is attributed to the thrusting of the Crêt de la Neige anticline followed by the Crêt Chalam thrust and its imbrications. Then, the Tacon thrust and finally the Bienne thrust nucleate. Imbricate fault-bend folding explains the high southern slopes of the anticlines found in this area. In addition to the primary décollement level situated at the base of the Keuper Group evaporites, three other detachment levels are found in marly layers. Using such a multiple thrust horizon approach avoids having to introduce thick unaccounted for evaporitic duplexes in the Keuper units, basement horst, or inverted Permo-Carboniferous grabens. The change in dip of the top basement located under the SE flank of the Crêt de la Neige anticline, at the transition of the Jura FTB to the Molasse Basin, is considered to be linked to a preexisting Paleozoic normal fault and could correspond to the northern edge of a suspected Permo-Carboniferous graben interpreted on seismic lines under the Geneva Basin. This step can be considered as an initiation point for structures developing in the detached cover.

How to cite: Marro, A., Sommaruga, A., Hauvette, L., Borderie, S., Schori, M., and Mosar, J.: Tectonics of the Western Jura Fold-and-Thrust Belt: from the Geneva Basin to the Bienne Valley (France). Mapping and forward modelling., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4607, https://doi.org/10.5194/egusphere-egu22-4607, 2022.

EGU22-4911 | Presentations | TS7.2

The role of the SE China passive margin for the formation of Taiwan orogen 

Mateus Rodrigues de Vargas, Geoffroy Mohn, and Julie Tugend

Taiwan orogen records a singular geological context where different stages of convergence are preserved. From south to north, the Taiwan region records the transition from oceanic and continental subduction of the SE China passive margin to its collision with the Luzon Magmatic Arc.

This study aims to define the thermal, compositional, and structural inheritance of the Chinese SE passive margin onto the processes of continental subduction and early collision. We combined geological and geophysical data (e.g., crustal thickness, seismicity, gravimetry, and magnetic anomaly maps) to propose a structural rift domain map of the SE China margin and its inversion. Open access seismic data is currently being interpreted to identify key tectonostratigraphic sequences, showing the crustal architecture and the tectonic-sedimentary evolution of the region. By building these offshore-onshore transects, we aim to capture the along-strike variations of the trench morphology. Initial results suggest a northward thickening of the accretionary prism in relation to the change from oceanic to continental subduction.

This work is part of an ongoing Ph.D. thesis in which the analysis of the results will not only focus on establishing new first-order tectonic models for the early collision but also on better constraining the control of former rifted margin on the locus of the deformation in this tectonically active zone.

How to cite: Rodrigues de Vargas, M., Mohn, G., and Tugend, J.: The role of the SE China passive margin for the formation of Taiwan orogen, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4911, https://doi.org/10.5194/egusphere-egu22-4911, 2022.

EGU22-5086 | Presentations | TS7.2

Tectonic Characteristics and Controls on Hydrocarbon Accumulation in Middle Section of Western Sichuan Depression 

Xinpeng Wang, Shuping Chen, Chi Zhang, and Wenyong Li

Western Sichuan Depression is located in the west of the Sichuan Basin and has shown great gas prospects for many years. Due to the characteristics of multiple stages of tectonic evolution and multiple directions of tectonic distribution, petroleum geological conditions are extremely complex in this area. In this paper, we use geological data, seismic data, well logging, and petroleum geological data to study the tectonic characteristics and controls on hydrocarbon accumulation in the middle section of the Western Sichuan Depression. The middle part of the Western Sichuan Depression is dominated by thrust structures, including thrust structures formed by the combination of thrust faults, fault triangular belt, and thrust imbricate structures, as well as fold deformation related to thrust faults, such as snake-head structure and slippage fold. The study area is characterized by east-west zonation and up-down stratification. In the process of formation and evolution, Western Sichuan Foreland Basin mainly experienced three tectonic periods, namely the Indosinian period, the Yanshan period, and the Himalayan period. Multi-stage tectonics, the change of force source, and principal stress direction also lead to the formation of tectonic series and tectonic belts with different trends. Most of the traps of the Leikoupo Formation in the region had their embryonic form in the late Indochinese period, which was further developed in the Yanshanian period, and basically formed in the early Himalayan period. Therefore, the tectonic conditions and accumulation conditions were well arranged, forming self-generation and self-accumulation or a combination of self-generation and self-accumulation and up-generation and sub-accumulation reservoir formation mode. The superior accumulation conditions and tectonic conditions make the Marine strata of the Leikoupo Formation of the Western Sichuan Depression show more favorable exploration potential. This study reveals structural style of the piedmont belt in the foreland basin and establishes reliable evidences for the further development of regional structural and accumulation models, which are crucial for further oil and gas explorations.

How to cite: Wang, X., Chen, S., Zhang, C., and Li, W.: Tectonic Characteristics and Controls on Hydrocarbon Accumulation in Middle Section of Western Sichuan Depression, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5086, https://doi.org/10.5194/egusphere-egu22-5086, 2022.

EGU22-5905 | Presentations | TS7.2

Reverse fault propagation in shales and associated decametric deformation gradients. 

Francho Gracia Puzo, Charles Aubourg, and Antonio Casas Sainz

The southern Pyrenean Zone shows a classical thin-skinned fold-and-thrust belt. Particularly interesting is the thrust sequence detached in the Upper Triassic low-strength level cropping out in the central-western sector of the chain (Leyre-Orba thrust system). Along its mapped trace, the Leyre thrust cleanly places the Cretaceous units on top of the Eocene (syn-tectonic) marls of the Jaca basin. However, in the footwall of this thrust there is a series of smaller-scale faults related to the main thrust and involving exclusively the marly units.

Understanding the deformation that marls (often lacking structural indicators) have acquired is a subject of interest to many geoscientists, given the role that these rocks play in geological storage systems. Knowing the state of the rock fabric may be essential to understand variations in its expected physical properties. In particular, Anisotropy of Magnetic Susceptibility (AMS) is a technique that can be successfully (although perhaps not easily) applied on these lithologies, provided that clay minerals present on marls are responsible of the magnetic signal of the fabric.

The marls of the Arro-Fiscal formation show fracturing and a pervasive cleavage along a width of hundreds of meters along strike the Leyre fault. The penetrativity of cleavage gradually increases with the proximity to the main fault, as demonstrated by Boiron et al. (2020). However, new data presented in Gracia-Puzo et al. (2021) and this communication show that the deformation gradient is not a single progression, but that there rather are variations in the intensity of deformation, as indicated by the magnetic fabric data of the marls, what can also be correlated with outcrop observations in the field.

A second look at the outcrops, after considering AMS data, has permitted to detect faults that a priori were not observed, since they involve the same monotonous lithology in both walls. Therefore, they are not presented in previous cartographies. In outcrop view, we can detect areas where the marls have undergone significant deformation, with a very penetrative, almost slaty cleavage. These deformation zones are metric in thickness, and the less intense pencil cleavage in the marls can extend several tens of meters in thickness across strike.

For realizing the presence of these faults, the study of the magnetic fabric has revealed as a useful tool, since it gives a very accurate picture of strain conditions (Parés, 1999; Gracia-Puzo, 2021). In this presentation, microscopic data are also added. Together with the AMS dataset, they are aimed to characterize the fabric of the deformed marl, and thus to understand how deformation has developed in the context of the foreland of the Leyre thrust and the Arro-Fiscal Formation, at different scales. Gathering AMS data, thin sections and field observations, we conclude that a symmetrical deformation shadow is observed in these faults, involving both the foot-wall and hanging-wall.

Finally, in this work, we aim to characterize these strained beds, which differ in scale and geometry from other known deformed marls, thus extending our knowledge of shale cleavage formation.

How to cite: Gracia Puzo, F., Aubourg, C., and Casas Sainz, A.: Reverse fault propagation in shales and associated decametric deformation gradients., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5905, https://doi.org/10.5194/egusphere-egu22-5905, 2022.

EGU22-5906 | Presentations | TS7.2

Along strike structural changes in thin-skinned thrusts: 3-D approach to the Leyre thrust (Southern Pyrenees). 

Antonio Casas, Francho Gracia-Puzo, and Charles Aubourg

Interpretation at depth of geological structures and cross-section reconstruction of fold and thrust belts requires either (1) constraints derived from geophysical exploration (seismic, gravimetric or, in some cases, magnetic) or borehole data, or, alternatively, (2) assumptions about the geometrical model that help to accept or discard, or, eventually, to evaluate the feasibility of possible solutions. In this sense, 3-D reconstructions can help to correct and modify the reconstruction at depth of the main structural traits of a structure or a set of structures. Factors to take into consideration include the consistency in shortening figures along strike for each thrust sheet and the whole set of thrust sheets, and the deformation associated with thrust fronts, together with the consistency in constraints referred to the relative chronology between the different thrust slices. In this work we present the results of a 3-D high-resolution modelling of the Leyre thrust (Southern Pyrenees), confronting different possible models of its structure at depth, and showing the usefulness of 3-D reconstruction. The interest for its study lies in the strong along-strike changes observed, that must be linked to the particular kinematics of this sector of the Pyrenean chain. The proposed geometrical reconstruction benefits from the outstanding outcrops along the Esca valley transect and the existence of geophysical low quality data that, nevertheless, allow to establish some limits to the maximum depth of particular horizons.

The Leyre thrust is a plurikilometric, E-W striking, shallow-dipping, South-verging thrust located within the Eocene Jaca-Pamplona basin and detached at depth in the Upper Triassic evaporites (the regional décollement for many thrust systems in this area). The overall geometry of the outcropping segment of the Leyre thrust is a low-angle ramp of the Cretaceous-Paleocene competent units (folded and cut with high-angle ramp geometry), onto the Eocene marls that show pervasive slaty cleavage related to the thrust front. A second thrust sheet can be inferred at depth also involving the Cretaceous-Paleocene sequence. Furthermore, a back-thrust linked to a box-fold anticline appears in the hangingwall of the main thrust. This box folds shows a strong eastwards plunge, and disappears laterally towards the East. Finally, a slightly oblique thrust (WNW-ESE) ramps up the box-fold, with increasing displacement from West to East. The connection between this latter thrust and the back-thrust at the rear front of the box-fold is probably related with the warping of the fault surface and (possibly) a clockwise rotation of the uppermost thrust sheet.

All in all, the 3-D reconstruction proposed allows to update and contrast some of the tectonic models classically proposed for the area (see e.g. Labaume et al., 1985), reducing the number of superimposed thrust sheets and relating their geometry with an overall break-back (or hanging-wall-sequence) kinematics triggered by the blocking of movement at particular thrusts and the upward steepening of thrust surfaces. Development of (hardly-to-detect) thrust surfaces in the marls located in the footwall of the frontal thrust would be the manifestation of the last movements of the thrust system.

How to cite: Casas, A., Gracia-Puzo, F., and Aubourg, C.: Along strike structural changes in thin-skinned thrusts: 3-D approach to the Leyre thrust (Southern Pyrenees)., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5906, https://doi.org/10.5194/egusphere-egu22-5906, 2022.

EGU22-6798 | Presentations | TS7.2

Structural styles and tectonic inheritance in the Andean fold-thrust belt and foreland basin 

Brian K. Horton and Andrés Folguera

Andean orogenesis is expressed in the diverse deformational records of crustal structures and sedimentary basins in western South America.  Here we summarize retroarc structural styles within the Andean orogenic belt and foreland basin system through consideration of regional contractional fault geometries, their kinematic interactions with other structures, and the comparative involvement of crystalline basement and sedimentary cover rocks.  In assessing the controls on structural style, we emphasize the importance of precursor conditions and employ the concept of tectonic inheritance to identify four factors that influence Andean deformation.  (1) Structural inheritance involves the reactivation of preexisting faults or basement fabrics and accompanying inversion of sedimentary basins.  (2) Stratigraphic inheritance is exemplified by the preferential localization of interconnected thin-skinned structures above regional décollements developed in wedge-shaped stratigraphic packages versus isolated basement-involved thick-skinned fault structures formed in provinces with limited cover strata.  (3) Rheological properties guide the activation of new structures by means of the integrated strength, rock and mineral composition, fluid content and pressure, and associated mechanical heterogeneities and anisotropies that define crustal and lithospheric architecture.  (4) Thermal structure in the form of initial thermal conditions and later thermal perturbations (such as cooling/heating episodes related to arc magmatism, subducting slab dynamics, or lithospheric removal) can promote inboard advance or outboard retreat of deformation.  Spatial and temporal variations in the relative importance of these four inherited attributes likely resulted in a complex evolution of structural styles during Andean shortening. 

The major styles include: (1) thin-skinned fold-thrust systems affecting principally cover strata with ramp-flat structures above gently dipping regional décollements that ultimately root in middle to upper crustal levels; (2) thick-skinned basement-involved block uplifts delineated by isolated high-angle reverse fault structures that penetrate deeply and may root in the lower crust; (3) pre-Andean (preorogenic) and (4) Andean (synorogenic) extensional basins that have been inverted by fault reactivation during later shortening; (5) upper-crustal backthrust belts linked to deeper foreland-directed structures; and (6) salt-involved contractional structures with weak décollement horizons that facilitate lateral flow of evaporite facies.  These structural styles are not mutually exclusive and may overlap in time and space.  We propose that evaluation of the contrasting roles of structural, stratigraphic, rheological, and thermal inheritance will help explain how numerous Andean structures do not bear simple relationships to the history of plate convergence, subduction, and magmatism along the western margin of South America.

How to cite: Horton, B. K. and Folguera, A.: Structural styles and tectonic inheritance in the Andean fold-thrust belt and foreland basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6798, https://doi.org/10.5194/egusphere-egu22-6798, 2022.

When orogeny reactivates extensional structures or uplifts pre-existing depocenters in the foreland (inversion), the overall nature, dimension, and geometry of these rheological heterogeneities represent one of the main controlling factors in the spatio-temporal evolution of foreland fold-and-thrust belts. Relationships between inversion structures in the foreland and far-field stresses caused by orogenic fronts have long been identified (e.g., Ziegler, 1989, Geol. Soc. Spec. Publ. 44). However, conditions that facilitate or hinder basin inversion in these settings remain unclear, mainly due to the intrinsic complexity of analysing multiple overprinted geological events.

We use novel laboratory experiments of basin inversion to investigate how compressional stresses are transferred across a heterogeneous crust. More specifically, we determine how the presence of multiple extensional basins in the foreland controls the location, occurrence, and sequencing of foreland thrusts. Quantitative analysis of our experiments allows us to define conceptual models for comparison and application to natural examples where geological interpretation remains partially conjectural due to their intrinsic complexity, such as the permo-carboniferous troughs beneath the Swiss Molasse basin or the inverted Broad Fourteens Basin in the North Sea.

Our experiments are built in a modelling apparatus with a mobile backstop, using quartz sand to model brittle crustal materials and glass microbeads to simulate a weaker basal detachment layer. Velocity discontinuities at the base are created by attaching multiple thin basal sheets to the mobile wall during extensional phases (pulling). The location of each extensional basin is defined by the lengths of the basal sheets. During extension, the resulting graben-like structures are progressively filled with microbeads to create a sedimentary infill that is less competent than the surrounding rock. The basal sheets are completely detached from the mobile wall before the initiation of the shortening phase (pushing). Topography, surface and lateral deformation is quantified employing a high-resolution particle imaging velocimetry (PIV) system.

We present results of shortening multiple extensional basins at fixed distances from the orogenic front. Detailed analysis shows that extensional basin faults are not reactivated during shortening, but instead inversion is characterised by an initial squeezing of the basin fill and subsequent formation of either frontal or back thrusts that localise along the microbead-sand interface, leading to the overall uplift of the basins. This mechanism occurs independent of the distance of the basin to the orogenic front. However, when several grabens are present, the extent of shortening that each extensional structure localises differs greatly between experiments, showing variability according to the number of basins and their distance to the orogenic front.

When compared to reference models with a homogeneous crust, our results show that the presence of multiple extensional basins in the foreland exerts a first-order control on the evolution of propagating fold-and-thrust belts. Thrust location and sequencing evolve differently, with frontal thrusts developing along pre-existing basins boundaries at early stages, and subsequent stages of back thrust formation characterising wedge thickening at the hinterland of the extensional basins.

How to cite: Molnar, N. and Buiter, S.: Analogue modelling of inversion tectonics: investigating the role of multiple extensional basins in foreland fold-and-thrust belts, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7027, https://doi.org/10.5194/egusphere-egu22-7027, 2022.

EGU22-7144 | Presentations | TS7.2

Development of a hidden fold and thrust belt in the Himalayan piedmont and distribution of active tectonics 

Etienne Large, Pascale Huyghe, Jean-Louis Mugnier, François Jouanne, Bertrand Guillier, and Tapan Chakraborty

The pattern of active deformation of Himalayan frontal structures is complex with out-of-sequence reactivations in the chain and development of scarps associated to earthquake ruptures reaching the surface in the piedmont. We analyze passive seismic records using the Horizontal-to-Vertical Spectral Ratio method along three North-South trending profiles of the Darjeeling Himalayan piedmont, revealing subsurface structures down to 600 meters and imaging the Siwalik sedimentary rocks / recent deposits interface. We find evidence for a thrust fold system hidden beneath the plain correlated to geomorphologic scarps revealed by topographic profiles. These morphological surfaces are incised by large rivers of the piedmont by several tens of meters during phases of low sedimentation, thus slightly emerging in the plainThese scarps are supposedly induced by thrust deformation related to great earthquakes propagating south of the morphological front and inducing subsurface ruptures in the piedmont. This interpretation is comforted by the lateral correlation of the imaged thrusts and associated folds with previously evidenced fault scarps associated to active thrusts of the Darjeeling piedmont. In the piedmont of East/Central Nepal, oil company seismic profiles image similar thrusts and associated folds that can also be correlated to both local incision of small rivers draining the southern flank of the Siwalik hills, and uplift evidenced by a previously analyzed leveling profile.

The long-term kinematic evolution of this hidden thrust fold belt is slow, with a tectonic uplift of the hangingwall lower than the subsidence rate of the foreland basin, i.e., less than ~ half a millimeter per year. The evolution of the hidden structures corresponds to that of an embryonic thrust belt affected by a layer parallel shortening (LPS) acting in the long term with a shortening rate of the order of 5-10% of the shortening rate of the whole Himalayan thrust system. An aseismic deformation associated with the LPS structures that could absorb the entire deformation of the embryonic thrust belt in East/Central Nepal is suggested by the comparison of the long term structural evolution with geodetic and paleoseismological studies. The amplitude of this aseismic deformation is however too limited to significantly reduce the seismic hazard in the Himalayan piedmont.

How to cite: Large, E., Huyghe, P., Mugnier, J.-L., Jouanne, F., Guillier, B., and Chakraborty, T.: Development of a hidden fold and thrust belt in the Himalayan piedmont and distribution of active tectonics, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7144, https://doi.org/10.5194/egusphere-egu22-7144, 2022.

EGU22-7262 | Presentations | TS7.2

Reconstruction of the Ukrainian Carpathians fold-and-thrust belt from low-temperature thermochronology and tectono-stratigraphic analysis. 

Marion Roger, Arjan de Leeuw, Peter van der Beek, and Laurent Husson

The Carpathians fold-and-thrust belt resulted from the accretion of sediments during subduction of the European slab in the Cenozoic, and the collision of the ALCAPA and Tisza-Dacia blocks with the East European margin in the Early-Middle Miocene. In this study we unravel the history of nappe stacking and the thermal evolution of the Ukrainian Carpathians wedge by combining low-temperature thermochronology and tectono-stratigraphic analysis.

We collected 11 sandstone samples for (U-Th)/He and fission-track dating on detrital apatites and zircons. The resulting thermochronological data were modelled using QTQt to constrain the time-temperature paths independently for several nappes. We compare the results with the burial histories of the respective nappes as derived from their stratigraphy.

All zircon (U-Th)/He (ZHe) ages in our samples are older than the depositional age of the corresponding strata; they are thus non-reset and thought to mark sediment provenance. We identified two groups of ZHe ages; a younger group with ages around 130 Ma to 90 Ma in the inner nappes, and an older group with ZHe ages around 450 Ma to 200 Ma in the outer belt. Potential sources for these zircons are thought to be the Tisza-Dacia basement and its sedimentary cover for the younger ZHe age group, and the East European shield and/or its sedimentary cover for the zircons with older ZHe ages in the external nappes. Apatite (U-Th)/He (AHe) ages are mostly <20 Ma and show a trend of progressive younging toward the outer nappes. Apatite fission-track (AFT) ages display a similar pattern with overall younging of the central age from the inner to the outer nappes, except for the outermost Skyba nappe where AFT central ages are around 10 My older than in the adjacent Krosno nappe.

Modelling the sample time-temperature paths from AHe, ZHe and AFT data permits to unravel the chronology of nappe stacking. Most of the AFT samples are partially reset, allowing to better constrain the burial and exhumation pathways. The inner Magura and Marmarosh nappes started cooling from a peak burial temperature of 100 ± 5°C at 40 to 29 Ma. Our two samples from the following nappes, Burkut and Rakhiv, show younger cooling ages with an onset at 24 ± 2 Ma and at ~10 Ma, respectively, and significantly higher burial temperatures (≈150 °C) than the other nappes, provoking the total resetting of AFT ages. The next nappe, Krosno, started cooling between 21 and 17 Ma from peak burial temperatures of 100 ± 8°C. The Skyba nappe started cooling between 22 and 16 Ma. Whereas the onset of this cooling is similar to the Krosno nappe, the maximum burial temperature of Skyba is higher (130 ± 5°C) and at odds with the minor thickness (<1500 m) of the sedimentary overburden.

These results indicate potential out-of-sequence thrusting and/or significant erosional exhumation in the innermost nappes. For the middle nappes, burial by tectonic overthrusting and/or kilometre-scale syn-tectonic sedimentation is required. The higher temperatures experienced by the outermost nappes can resulted from overthrusting and complete erosion of the middle nappes.

How to cite: Roger, M., de Leeuw, A., van der Beek, P., and Husson, L.: Reconstruction of the Ukrainian Carpathians fold-and-thrust belt from low-temperature thermochronology and tectono-stratigraphic analysis., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7262, https://doi.org/10.5194/egusphere-egu22-7262, 2022.

EGU22-7288 | Presentations | TS7.2

Assessing burial history using stylolite roughness paleopiezometry with a twist in the Umbria-Marche Apennine Ridge 

Olivier Lacombe, Aurélie Labeur, Nicolas E. Beaudoin, and Jean-Paul Callot

Stylolite are rough structures developed by pressure solution, usually related either to burial stress or to tectonic contraction. The stylolite roughness, i.e., the difference in height between two points separated by a given distance along a track, yields quantitative information about the normal stress applied to the stylolite plane. The stress magnitude is accessed by applying signal analysis such as Average Wavelet Coefficient (AWC) or Fourier Transform (FT) onto a stylolite track, returning a characteristic length (cross-over length, Lc) at which two regimes of self-affine properties switch. In the case of a sedimentary, bedding-parallel stylolite, Lc scales to the magnitude of the vertical principal stress σ1, hence to the burial depth at the end of the life of the studied stylolite. When applied to bedding-parallel stylolite populations in foreland basins and fold-and-thrust belts, this Stylolite Roughness Inversion Technique / paleopiezometer (SRIT) allowed estimating the maximum burial experienced by a strata before σ1 became horizontal at the onset of tectonic contraction. We have collected hundreds of stylolites in the Meso-Cenozoic carbonate sequence along a wide SW-NE transect across the Umbria Marche Apennine Ridge (Apennines, Italy). On this dataset we conducted stylolite roughness inversion with both FT and AWC in order to quantify the maximum burial reached in the different parts across the belt before the Apenninic contraction begun. Doing so, we observed some discrepancies between Lc values obtained by either one or the other signal analysis method, implying a user dependent choice of the method based on best fit of the treatment and on consistency between all results. In order to (1) find the source of this difference, (2) correct this effect and (3) assess whether it impacts the derived vertical stress magnitude, we built virtual composite stylolites by assembling consistent stylolite tracks together to increase the range of roughness covered by the signal analysis. We present a statistical comparison of the results of the application of SRIT on single tracks and on composite ones. In both cases, the resulting depths are of the same order of values, and within the range of uncertainties, allowing a confident reconstruction of the pre-contractional burial depth across the Umbria Marche Apennine Ridge. However, the resulting Lc are closer for the two regression methods in the case of composite stylolites. The new approach therefore reduces the risk associated with a choice between signal analysis methods related to the user and expands its easiness of application.

Key words: paleopiezometry, stylolites, compressive deformation, folding, vertical stress, compaction and burial depth

How to cite: Lacombe, O., Labeur, A., Beaudoin, N. E., and Callot, J.-P.: Assessing burial history using stylolite roughness paleopiezometry with a twist in the Umbria-Marche Apennine Ridge, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7288, https://doi.org/10.5194/egusphere-egu22-7288, 2022.

EGU22-7548 | Presentations | TS7.2

Constraining the formation of the fault-bound Cianzo basin, NW Argentina using low-temperature thermochronology 

Willemijn S.M.T. van Kooten, Edward R. Sobel, Cecilia del Papa, Patricio Payrola, Daniel Starck, and Alejandro Bande

The transition from the Eastern Cordillera to the Santa Barbara System in NW Argentina is characterized by the inversion of pre-existing Cretaceous and Paleozoic structures. Within this complex fold-and-thrust belt, the Miocene Cianzo basin with its rich sedimentary and structural record tells the tale of Andean reactivation of an extensional fault system and the incorporation of the former Salta rift basin into the orogenic wedge. In the Cretaceous, the intracontinental Salta rift was widely distributed in NW Argentina, with multiple sub-basins radiating from a central high. The Cianzo basin, at that time situated at the northern margin of the ENE-WSW striking Lomas de Olmedo sub-basin, impressively shows the transition from condensed post-rift strata on top of the rift shoulder to thick, proximal syn- and post-rift strata of the Salta Group in the adjacent half-graben. These sediments were buried by up to 3 km of clastics from the approaching orogenic wedge, causing apatite (U-Th-Sm)/He (AHe) and, in part, apatite fission track (AFT) ages to be reset. In the Miocene, deformation reached the Eastern Cordillera, gradually dissecting the foreland basin along pre-existing faults and forming local depocenters such as the Cianzo basin, which is surrounded by inverted normal faults and basement block uplifts. Its unique structural setting and complete sedimentary record provide an excellent natural laboratory to study fold-and-thrust belt formation through reactivation of pre-existing structures. Although the structural and sedimentary characteristics of the Cianzo basin have been studied in detail, low-temperature thermochronology data to quantify deformation processes is lacking. We provide AHe, AFT and zircon (U-Th-Sm)/He (ZHe) cooling ages from 39 samples from the Cianzo basin and adjacent areas. Jurassic ZHe ages from the Aparzo ranges may reflect pre-Salta Group exhumation of the rift shoulder, an event which is also recorded in thick, proximal agglomerates that were shed into restricted depocenters. AHe and AFT data document a Middle-Late Miocene onset of rapid exhumation of the Abra de Zenta, Hornocal and Aparzo ranges that border the Cianzo basin. Furthermore, AHe and AFT ages constrain the sequence of deformation for large folds such as the Cianzo syncline. The new dataset refines the timing of reactivation of pre-existing normal faults that now bound the Cianzo basin and sheds a new light on the propagation of the Eastern Cordillera fold-and-thrust belt in time and space.

How to cite: van Kooten, W. S. M. T., Sobel, E. R., del Papa, C., Payrola, P., Starck, D., and Bande, A.: Constraining the formation of the fault-bound Cianzo basin, NW Argentina using low-temperature thermochronology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7548, https://doi.org/10.5194/egusphere-egu22-7548, 2022.

EGU22-7974 | Presentations | TS7.2

Dynamic experiments investigating non-critical orogenic wedges 

Susanne Buiter and Nicolas Molnar

A series of influential papers in the 1980’s showed how the long-term evolution of fold-and-thrust belts and accretionary wedges (here collectively termed orogenic wedges) can quantitatively be described as striving towards a mechanical equilibrium defined by their internal and basal material strengths (Dahlen 1984, Dahlen et al. 1984, Davis et al. 1983). Unstable orogenic wedges will deform to adjust their basal and surface slopes to a critical taper angle, defined by a wedge that is at the verge of failure everywhere. Critical taper theory has been confirmed by analogue and numerical experiments and found numerous successful applications in field studies.

The success of critical taper theory forms a framework that allows investigating non-critical behaviour of orogenic wedges. Previous numerical and analogue studies pointed out that: (1) Only portions of orogenic wedges may be at failure at any given time, separating critically stressed from non-critical segments (Lohrmann et al. 2003, Simpson 2011). As these wedges still observe a critical taper, this may indicate that it is the critically stressed segments that define the overall wedge shape. (2) Numerical experiments often attain a critical taper at lower shortening percentages than analogue experiments. We speculate that this may be related to larger amounts of strain softening generally used in numerical setups and/or the number of shear zones that forms at equivalent shortening (which is controlled by numerical resolution and analogue material properties). This non-criticality is thus likely only a transient state.

We here ask the question whether structural inheritance from earlier compressional or extensional deformation phases may lead to longer-term non-critical wedge behaviour by favouring out-of-sequence thrusting or shear zone propagation into the foreland. To address this question, we combine a review of previous dynamic wedge experiments with new analogue experiments that investigate the influence of inherited shear zones and variations in material properties on wedge evolution. We shorten quartz sand layers overlying a weak basal microbeads layer with a non-deformable backstop. The backstop has two independently moving parts, allowing to alternate thin- and thick-skinned deformation. We find that the reactivation of basement shear zones formed in earlier deformation phases is short-lived and does not affect thrusting to a degree that would distinguish these wedges from those without inheritance. We extend these experiments by including variations in internal material properties and weaker shear zones, remaining however in the domain of brittle orogenic wedges.

Non-critical wedge behaviour may only be a transient state, but could occur frequently owing to variations in material properties or structural inheritance, which are to be expected in regions of inter-plate shortening of former rift regions. Our contribution hopes to highlight the potential for future modelling studies of orogenic wedges to examine how non-critical wedge behaviour could play into the evolution of fold-and-thrust belts and accretionary wedges.

How to cite: Buiter, S. and Molnar, N.: Dynamic experiments investigating non-critical orogenic wedges, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7974, https://doi.org/10.5194/egusphere-egu22-7974, 2022.

EGU22-8263 | Presentations | TS7.2

Structural evolution of the outer Indo-Burma Wedge: Insights from field observations and laboratory experiments 

Animesh Das, Sreetama Roy, Sujit Dasgupta, and Santanu Bose

The outer wedge of the Indo-Burma wedge (IBW) has resulted due to oblique subduction of the Indian Plate below the Burma. In this study, we will use the analysis of outcrop-scale structures from Tripura-Mizoram fold belt (TMFB) to evaluate the structural evolution of the outer wedge of IBW. TMFB belongs to the widest section of the outer wedge that stretches from east to west for around 270 km (along 23.5° N latitude). The first order structure of the outer wedge is characterized by a series of north-south trending anticlines-and-synclines of varying tightness. Analysis of our field observations provide a detailed understanding on the evolution of the first-order structure of the outer wedge of IBW. Weshow that the style of folding progressively becomes complex towards the hinterland direction of the wedge. The complexity of the fold structure is defined by the development of different geometries of folds, including refolding of earlier structures. Interestingly, different geometries of folds towards the hinterland share a uniform orientation of folds axes, implying pure shear deformation. Our field observations allow us to infer that the outer wedge sediments of IBW have deformed in a ductile manner over a shallow decollement, lying beneath the Neogene sediments of the outer wedge. We attribute the ductile behaviour of the outer wedge sediments to the dominance of weak shale horizons and high pore fluid pressure in the entire Neogene sequence of the outer wedge. To gain a complete understanding on the style of the strain distribution within TMFB, we performed scaled laboratory modelling under oblique convergence. We used Polydimethyl Siloxane (PDMS) to simulate the viscous rheology of the Neogene sediments. Model results show strong consistency not only with the existence of across-strike variations in the tightness of fold patterns from east to west but also provides a strong basis for explaining the occurrence of along-strike variations of deformation intensity in the outer wedge of IBW, which gradually increases southward with narrowing the width of the wedge.

How to cite: Das, A., Roy, S., Dasgupta, S., and Bose, S.: Structural evolution of the outer Indo-Burma Wedge: Insights from field observations and laboratory experiments, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8263, https://doi.org/10.5194/egusphere-egu22-8263, 2022.

EGU22-8489 | Presentations | TS7.2

Internal deformation of the Dolomites Indenter, eastern Southern Alps: Orthogonal to oblique basin inversion investigated in crustal scale analogue models 

Anna-Katharina Sieberer, Ernst Willingshofer, Thomas Klotz, Hugo Ortner, and Hannah Pomella

The Dolomites Indenter (DI) represents the front of the Neogene to ongoing N(W)-directed continental indentation of Adria into Europe. In this contribution, we focus on the internal deformation of the DI and its eastern continuation towards the Dinarides. Using a series of crustal scale analogue models, we investigate the effect of Jurassic E-W extension on the NW-SE directed shortening of the DI during Alpine orogeny.

The brittle and brittle-ductile analogue experiments can be grouped in two sub-series. In sub-series A, the platform-basin topography has been created by pre-scribing an initial strength contrast between platforms and basins followed by one stage of indentation. In sub-series B, graben structures were developed through an initial extensional phase, subsequently followed by compression. The evolving grabens were syn-kinematically filled up to different thicknesses depending on the material used; either with quartz sand up to a platform/basin thickness ratio of 0,75 or with feldspar sand or glass beads up to the initial, non-stretched crustal thickness. The brittle upper crust of platforms was simulated with quartz sand, the brittle to ductile middle crust by either glass beads or by a mixture of polydimethylsiloxane (PDMS) silicon putty and quartz sand. In both sub-series, variations in the orientation of rheological boundaries with respect to the convergence direction have been modelled. This (oblique) basin inversion allows us to test various deformational wavelengths as well as timing and localisation of uplift of the DI’s upper to middle crust.

Modelling results of (oblique) basin inversion confirm the localisation of deformation in areas of lateral strength contrasts (Brun and Nalpas, 1996), as transitions from platforms to basins represent. Spacing of in-sequence thrusts is larger on platforms and smaller in basins, visible in both, models of sub-series A (inversion of strength difference only) and B (inversion of strength difference and actual normal faults). The vergence of in-sequence structures varies from mostly foreland directed using glass beads as basal detachment, to pop-up structures using putty, to a combination of both using quartz sand only. Based on our modelling observations, we propose that the overall style of deformation is less dependent on the material of the basal décollement, but is ruled by the inherited platform/basin configuration.

To compare analogue modelling results with deformation in the DI, structural fieldwork accompanied by thermochronological sampling was carried out (for details on structural and thermochronological data see the contribution of Klotz et al. in session GD8.4). According to field observations, the shortening direction along several of the studied faults, e.g. the overall SSE-vergent Belluno thrust (Valsugana fault system, external eastern Southern Alps, Italy), changes locally from top SSW to top SSE along strike. We infer that the variability of shortening directions along these thrust faults depends on inherited geometries and is not the result of different deformation phases. One possible conclusion from this observation is that the number of deformation phases in the Southern Alps may have been overestimated so far.

References:

Brun, J.-P., Nalpas, T. (1996). Graben inversion in nature and experiments. Tectonics. v. 15, no. 3, p. 677-687.

How to cite: Sieberer, A.-K., Willingshofer, E., Klotz, T., Ortner, H., and Pomella, H.: Internal deformation of the Dolomites Indenter, eastern Southern Alps: Orthogonal to oblique basin inversion investigated in crustal scale analogue models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8489, https://doi.org/10.5194/egusphere-egu22-8489, 2022.

EGU22-8497 | Presentations | TS7.2

Deformation, uplift and exhumation across the northern sectors of the Iranian Plateau: insights from low-temperature thermochronology data and intermontane basins fill units 

Paolo Ballato, Maria Laura Balestrieri, Istvan Dunkl, Philipp Balling, Mohammad Paknia, Ghasem Heidarzadeh, Masoud Biralvand, Gerold Zeilinger, Mohammad Ghassemi, Claudio Faccenna, and Manfred Strecker

The Iranian Plateau represents a NW-SE striking, elongated, elevated (mean elevation of ~1.8 km), arid, mostly internally drained (~65 % of its area) and aseismic morphotectonic feature of the Arabia-Eurasia collision zone. With a crustal thickness up to ~65 km, the southern plateau margin includes the High Zagros Mountains and the plate suture zone. The northern plateau margin, instead, consists of the Urumieh-Dokhtar Magmatic Zone and the western Alborz-Talesh Mountains from SE and NW Iran, respectively, which exhibit a crustal thickness ranging from 40 to 50-55 km. The plateau interior is characterized by a low-topographic relief morphology with six major, mostly internally drained intermontane sedimentary basins. The backbones of these basins are mainly represented by the Sanandaj-Sirjan Zone. Plateau uplift commenced after ~17 Ma, as documented by the occurrence of Lower Miocene shallow-water marine sediments of the Qom Formation within the plateau interior. Although the Iranian Plateau represents the second largest collisional plateau after Tibet, the chronology of the events and the mechanisms that built it are poorly constrained.

In this study, we combine a new low-temperature thermochronologic dataset including apatite fission- track and apatite (U-Th-Sm)/He ages from the northern plateau sectors and its interior with structural and stratigraphic data from different intermontane basins and literature thermochronology data. Combined, this information shows that after a mild phase of post late Eocene contractional deformation, collisional deformation started in the early Miocene along the plate suture zone to the south and in the middle Miocene (~16 Ma) in the Talesh-Alborz Mountains to the north. Subsequently, around 12-10 Ma, deformation jumped in the plateau interior over a rather large area including the Urumieh-Dokhtar and Sanandaj-Sirjan zones, apparently without a specific pattern of propagation. Upper plate deformation occurred mostly through the reactivation of older NE-dipping structures that led to the topographic growth of several mountain ranges spanning a wavelength of ~50-60 km. This was associated with the compartmentalization of the upper plate and the development of different intermontane basins. There, basin filling processes inhibited intrabasinal deformation and faulting along the major range-bounding faults producing the smoothed, low-relief landscape typical of an orogenic plateau.

Combined, these results provide new information concerning the mechanisms and the timing of the lateral, orogen-perpendicular, growth of the Iranian Plateau

How to cite: Ballato, P., Balestrieri, M. L., Dunkl, I., Balling, P., Paknia, M., Heidarzadeh, G., Biralvand, M., Zeilinger, G., Ghassemi, M., Faccenna, C., and Strecker, M.: Deformation, uplift and exhumation across the northern sectors of the Iranian Plateau: insights from low-temperature thermochronology data and intermontane basins fill units, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8497, https://doi.org/10.5194/egusphere-egu22-8497, 2022.

EGU22-8958 | Presentations | TS7.2

Structural styles and shortening estimates for the inverted external British Variscides to determine maximum thrust displacements. 

William A. J. Rutter, Marios N. Miliorizos, Nikolaos S. Melis, and Nicholas Reiss

The Bristol Channel contains major Variscan thrusts juxtaposing distinct tectonostratigraphic terranes:  the Upper Carboniferous Rhenohercynian, Culm (south) and Sub-Variscan Foredeep, Coalfield (north). There is agreement the contrasts across the Channel are not restricted to this, since underlying marine Devonian differs from continental ORS and Lower Carboniferous radiolarian-chert differs from the Main Limestone. The famous basins were mapped intricately over 100+ years by the UK geological survey and by academics across Europe, and questions about their juxtaposition date back to 1895 in the Quarterly Journal of the Geological Society, London.

Our aim, is to use structural styles and shortening to determine an upper limit for displacements upon the major thrusts. We investigate the magnitudes of shortening from south to north through the Culm and north Devon basins, and from west to east across SW Dyfed, central South Wales, Bristol, Mendips, Oxfordshire, and Kent, using an immense legacy of sections drawn by various authors, including the recent basin dynamics group of Wales.

Estimates corrected for Mesozoic negative inversion show 45% shortening due to accommodation-chevron and box folding in the Culm, 40% due to folds, back-thrusts, and fore-thrusts in the north Devon basin, 30% beneath northern parts of the Channel, and 33% along the strike of the foredeep from Wales to Kent. There is also great contrast in deformation style, between the Culm continuous-folds and the foredeep with reactivated faults, rounded folds, and thrusts, related to preferential slip along seams within central parts of the Middle Coal Measures.

Shortening can be 70%, close to underthrusts in the southern Culm; adjacent to regional thrusts along the north Devon coast; and, proximal to disturbances within the foredeep. This intensity of composite deformation would not be out of place close to tectonic-scale thrusts, between these terranes. Additionally, thrusts of this scale are detectable on regional seismic profiles and were the topics of recent studies. Structural inspection reveals significant 1km-scale displacements along NW-SE strike-slip faults common to both terranes and upon WSW-ENE oblique-ramp thrusts local to the Vale of Glamorgan and Severn estuary. WNW-ESE frontal ramps with ~10km-scale displacements are considered candidate ‘stems’ to tectonic-scale thrusts and are found in Gower, Devon, and inner Channel.

Further investigations could elaborate the style of transmission of major thrust displacement from beneath the hinterland into the foredeep, whether by reactivation, decapitation, translation, and rotation of structural fabrics. There are complications of Mesozoic negative and Cenozoic positive inversions to consider in section restoration and adjustments are required to reveal how large displacements were dissipated exactly.

Reservations are that shortenings in hanging-walls can be poor indicators of displacement magnitude upon individual thrusts within sequences. Nevertheless, we conclude there is nothing contrary to the occurrence of a 100km-scale displacement, especially if accounting the tectonic-scale dimension and 300-500km geographic separations of modern terranes analogous to facies equivalent to the Culm and foredeep.

How to cite: Rutter, W. A. J., Miliorizos, M. N., Melis, N. S., and Reiss, N.: Structural styles and shortening estimates for the inverted external British Variscides to determine maximum thrust displacements., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8958, https://doi.org/10.5194/egusphere-egu22-8958, 2022.

EGU22-9211 | Presentations | TS7.2

Late Quaternary deformation of the sub-Himalaya on 100 kyr timescales 

Chloé Bouscary, Georgina King, Djordje Grujic, Jérôme Lavé, György Hetényi, and Frédéric Herman

In mountain accretionary wedges, it is generally considered that the preservation of a topography in mechanical equilibrium is modulated by the activation of faults, sometimes internal to the prism, sometimes frontal. The folds of the Himalayan foothills correspond to the most frontal structures of the Himalayan prism. Understanding the timing of the initiation and the activity of these frontal folds can provide valuable information on the deformation sequences within the range (reactivation of the MCT, prograde sequences and transfer to frontal folds, ...) in response to tectonic and climatic forcing. Late Cenozoic climatic changes, including glaciations, might have impacted the denudation of the Himalayan range. The study of recent deformation rates is thus key for understanding lateral variations in deformation along the entire Himalayan arc, which will bring new constraints on the interactions between tectonics and surface processes at different scales time, as well as deepen our understanding of the seismic behaviour of the range.

 

Here we quantify exhumation rates in the Himalayan foothills using luminescence thermochronometry, which is a recently developed very-low temperature thermochronometer applicable between tens of years and a few hundred kyr. In contrast to classical methods, it can resolve thermal histories from the upper few km of the Earth’s crust, allowing spatial variations in exhumation rates across the Himalayas to be deciphered on sub-Quaternary timescales. An extensive data set of more than 40 Siwalik rock samples, from Western Nepal to Eastern Bhutan, was measured to complement other thermochronometric data and understand the sub-Quaternary deformation on the Himalayan foreland.

 

The results show along-strike variations in exhumation rates in the Himalayan foothills during the late Quaternary, with exhumation rates across the sub-Himalaya varying locally independently of precipitation trends and changes in the modern convergence rates. These along-strike variations may suggest that over the last 300 kyr, Himalayan shortening has not only been accommodated by the most frontal faults along the Himalayan range.

How to cite: Bouscary, C., King, G., Grujic, D., Lavé, J., Hetényi, G., and Herman, F.: Late Quaternary deformation of the sub-Himalaya on 100 kyr timescales, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9211, https://doi.org/10.5194/egusphere-egu22-9211, 2022.

The Epiligurian wedge-top basins of the Italian Northern Apennines fold and-thrust belt have been thoroughly investigated in the past from a sedimentological and paleogeographic perspective leading to the identification of several regional unconformities and the appreciation of their significance to track down the complex evolution of the accretionary wedge. Among these, a major Burdigalian unconformity has been recognised as a key regional element marking an abrupt shift from a deep marine (pre-Burdigalian) to platform (post-Burdigalian) environment during the progressive uplift of the accretionary wedge. We integrate these studies by providing a solid structural framework wherein to set this evolution. We investigated the pattern and the kinematics of the deformation structures deforming the Epiligurian Units both in the pre- and post-Burdigalian sequences exposed in the Emilia-Romagna Region of the Northern Apennines. Field investigations were integrated with the remote sensing of lineaments mapped at the regional scale to unravel the significance of the Burdigalian unconformity during the thickening and later dismantling of the Northern Apennines wedge. Fieldwork data document the existence of different structures and lineament trends affecting the pre- and post-Burdigalian sedimentary sequences. For example, the lowermost units of the pre-Burdigalian sequence are affected by top-to-the SE, NE-SW-striking reverse faults defined by planar slip surfaces associated with thin clastic damage zones. These reverse faults are cut across by scattered normal faults accommodating centimetric to decimetric throws and associated with clusters of disaggregation deformation bands. The post-Burdigalian succession, instead, is affected by more systematic trends of both reverse and normal faults. The reverse faults are oriented either NE-SW or WNW-ESE, with a general NW or NE tectonic transport, respectively. The crosscutting normal faults strike from NW-SE to NE-SW and are associated with extension-oriented NE-SW and NW-SE, respectively. Normal faults are locally decorated by calcite slickenfibres and syn-kinematic calcite veins, documenting structurally controlled circulation of mineralising paleofluids. All the structures affecting both the pre- and post-Burdigalian sequences are linked to a tectonic evolution encompassing syn-orogenic compression and post-orogenic extension, with the latter accompanied by local instabilities during overall thinning of the transiently supercritical wedge. To assess the significance of our results on a regional scale, a remote sensing analysis of tectonic and morphological lineaments was performed by systematically mapping lineaments within a study area of 200 km² at an observation scale varying from 1:50.000 to 1:5.000. Statistical analysis of open-access dataset focused on reverse and normal faults, confirming the significant lineament orientation variations indicated by field data. NE-SW striking normal and reverse faults define the pre-Burdigalian dataset, whereas NE-SW-striking normal faults and NW-SE-striking compressional structures define the post-Burdigalian dataset. Preliminary results from the combination of field and remote sensing made it possible to not only differentiate tectonic and morphological elements and to identify the preferential trend of deformation structures, but to also conclude that the polyphasic tectonic evolution of the Epiligurian Units during the NE-verging accretion of the Northern Apennines wedge accommodated significant changes in stress field orientation and faulting regime in the pre-and post-Burdigalian period.

 

 

How to cite: Stendardi, F., Ceccato, A., Vignaroli, G., and Viola, G.: Syn-to post-accretionary tectonic history of the wedge-top Epiligurian Units (Northern Apennines, Italy) as constrained by structural and remote sensing analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9386, https://doi.org/10.5194/egusphere-egu22-9386, 2022.

The Taiwan thrust-and-fold belt results from the oblique arc-continent collision between the Eurasian Plate and the Luzon Volcanic Arc. In this context, inherited structures from the E-directed underthrusting Eurasian continental margin are being reactivated, causing uplift of crystalline basement rocks and the formation of transverse zones that influence the evolution of the structure, seismicity and topography of the Taiwan thrust-and-fold belt. The depth and geometry of the crystalline basement-cover interface of the continental margin are partly constrained by seismic velocities and the locations of earthquake hypocenters. However, further constraints are needed in order to obtain a better resolved location and geometry of this interface since this would improve the understanding of the deep structure of the thrust belt.

In this work, we investigate the geometry and position of first-order discontinuities of the underthrusting Eurasian continental margin to understand i) the role of the crystalline basement and the inherited structures in the deformation and, ii) the overall crustal geometry resulting from this collision. The approach we use is based on FFT and derivative based analyses, and 2D modelling of absolute gravity and magnetic anomalies. Techniques such as the calculation of the averaged power spectra have allowed us to infer the depth to the top of the most important discontinuities through the analysis of their gravity and magnetic wavelength signature. Results, obtained over different datasets show an upper interface at ~6 km depth and a lower at ~13 km depth. These are average values that we have better constrained through modelling, integration with other structural studies and comparison with tomography and seismic data. Results have helped us to improve the comprehension of the crustal structure of Taiwan and the Eurasian continental margin.

This research is part of project PGC2018-094227-B-I00 funded by the Spanish Research Agency of the Ministry of Science and Innovation of Spain. Olivia Lozano acknowledges funding from the same agency through contract PRE2019-091431.

How to cite: Lozano Blanco, O., Ayarza, P., Álvarez-Marrón, J., and Brown, D.: Depth to main crustal interfaces calculated through potential field data analysis and modelling: Implications for the study of inherited structures in Southern Taiwan, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9529, https://doi.org/10.5194/egusphere-egu22-9529, 2022.

EGU22-10064 | Presentations | TS7.2

Along-strike variations in the timing and magnitude of exhumation in the eastern Peruvian Andes 

Sarah Falkowski, Todd Ehlers, Nadine McQuarrie, Victoria Buford Parks, Chloë Glover, and José Cárdenas

The spatio-temporal history and control of uplift and incision of the eastern flank of the Central Andean Plateau margin is a point of controversial discussion. For example, ca. 4 Ma incision has been suggested for canyons in Bolivia and South Peru (>1250 km apart) and could be interpreted as either tectonically or climatically driven.

To evaluate the sensitivity of cooling ages to climatic and/or tectonic driven erosional exhumation, we build upon previous work and contribute new low-temperature thermochronometer data from three, up to 190-km-long transects from the eastern Andean Plateau to the Subandean Zone in southeastern Peru. The transects extend from the plateau down the San Gabán, Marcapata, and Tres Cruces valleys and include both valley bottom and interfluve samples. This is different from previous work and allows for an evaluation of age-elevation relationships along and across strike.

We present new thermochronometer dates from 46 apatite (U-Th)/He (age range ~1–41 Ma), 23 zircon (U-Th)/He (~4–284 Ma), 21 apatite fission-track (~3–63 Ma), and 11 zircon fission-track (~14–37 Ma) bedrock samples, as well as thermal models. All samples are interpreted in the context of sample elevation and neighboring structures.

We discuss the Miocene–Pliocene exhumation history of the Eastern Cordillera, including differences in the exhumation magnitude between the transects that are ca. 50–100 km away from each other. Based on age-elevation and age-distance relationships of the different thermochronometers and thermal models, we find that causes of exhumation and canyon incision cannot be as clearly identified and separated in time as previously suggested. However, plateau incision in the latest Miocene or later is consistent with climate enhanced incision and needed to explain the relationship between apatite (U-Th)/He and higher-temperature thermochronometer ages. Future work will integrate thermo-kinematic and erosion models to help gain further insight into the deformation history of the area.

How to cite: Falkowski, S., Ehlers, T., McQuarrie, N., Buford Parks, V., Glover, C., and Cárdenas, J.: Along-strike variations in the timing and magnitude of exhumation in the eastern Peruvian Andes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10064, https://doi.org/10.5194/egusphere-egu22-10064, 2022.

EGU22-10312 | Presentations | TS7.2

Fold evolution and the transition from folding to faulting: New insights from the carbonate multilayer succession of the Italian Eastern Southern Alps 

Costantino Zuccari, Giulio Viola, Guy Simpson, Manuel Curzi, Luca Aldega, and Gianluca Vignaroli

Understanding how folds and faults nucleate and grow is key to unravelling the tectonic and seismic evolution of both active and fossil fold-and-thrust belts (FATB). The progressive growth of folds and the transition from folding to faulting in FATBs are complex phenomena that reflect the combined effects of numerous deformation processes and boundary conditions. To better understand these complexities, we studied a folded sequence within the shortened Mesozoic carbonate multilayer succession of the seismically active Italian Eastern Southern Alps (ESA). The studied mesoscopic folds are parasitic to hanging- and footwall hectometric folds associated with regional-scale S-verging thrusts. We aimed to constrain (1) the folding style of the area, (2) the parameters governing the transition from folding to faulting through time, (3) the seismic vs. aseismic behaviour during the folding-faulting transition in carbonate-dominated fold-and-thrust belts, and (4) the overall tectonic framework of the ESA. Our approach relied on i) the structural analysis of symmetric and asymmetric folds and of the locally associated thrusts to assess the overall structural style and derive geometrical constraints upon the documented deformation features, ii) XRD analysis of the deformed carbonate multilayer to define its mineralogical composition and to establish the influence thereof upon deformation, and iii) mechanical modelling based on the Finite Element Method (FEM) to study the factors governing fold symmetry versus asymmetry.

Our field analysis shows that folds evolve from symmetric and open to south-verging asymmetric and close to tight before eventually being decapitated by discrete faults. This occurs once fold forelimbs exceed ~80°, which corresponds roughly with when the ratio between fore- and backlimbs dip angle exceeds ~3.3.  The mesoscopic thrusts that dissect asymmetric folds firstly localise along the gently dipping backlimbs, exploiting clay-rich beds therein, and then propagate toward the foreland by cutting across the steep forelimbs, producing cataclastic domains. Layer-parallel shearing and cataclasis are the dominant deformation modes during thrusting along the backlimb and forelimb, respectively. FEM modelling, used to constrain the transition from symmetric to asymmetric folding, shows that it is mainly controlled by (i) the thickness and vertical distribution of different rock types and (ii) the growth of first order folds at larger scales. In multilayer sequences we observe that small scale folds are initially symmetrical, forming under pure shear conditions. However, these structures may later become passively rotated in simple shear as they become parasitic to the growth of larger scale folds.

Finally, we propose a scenario of fold growth and transition from folding to faulting that has implications on the tectonic evolution of fold-and-thrust belts, including the coexistence of seismic and aseismic deformation during progressive shortening.

How to cite: Zuccari, C., Viola, G., Simpson, G., Curzi, M., Aldega, L., and Vignaroli, G.: Fold evolution and the transition from folding to faulting: New insights from the carbonate multilayer succession of the Italian Eastern Southern Alps, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10312, https://doi.org/10.5194/egusphere-egu22-10312, 2022.

EGU22-11171 | Presentations | TS7.2

Modes and geometry of crustal-scale detachment folds in hot orogens – insights from physical modeling 

Prokop Závada, Ondřej Krýza, Karel Schulmann, Ondrej Lexa, and Tan Shu

The concept of detachment folding was developed between the '60s and '80s and generally describes displacement and buckling deformation of a competent layer above a weak, usually low viscosity horizon during tectonic shortening. From this definition, and based on the Biot-Ramberg theory, it is clear that geometrical parameters of such folds depend on contrasting rheology in both layers or on the rheological gradient in a complex multilayer. These systems were originally studied in association with the thin-skinned deformation and salt tectonics, and recently with regards to large-scale lithospheric deformation. In the latter, the rapidly heated lower crust is partially melted and a thin melt layer at the MOHO depth serves as the detachment horizon during collision and shortening. 

Our experimental work contributes to the understanding of the geometrical, kinematic and dynamic behaviour of such types of detachment folds as this deformation process strongly depends on a thermally dependent rheological gradient and nonlinear shortening velocity. The natural prototype for our models is for example the Chandmann or Bugat metamorphic domes in central Asia (CAOB). Our aim is to parametrize the style of such crustal-scale detachment folds depending on the rheological properties of the layered crust and the thermal gradient.

For this purpose, we developed an apparatus for thermal analogue models capable of producing thermal gradients and programmable shortening. Paraffin wax is used as the analogue for the partially molten lower crust. The advantage of this material is, that it reproduces the temperature-controlled rheological stratification of the crust in hot orogens with a melt layer at the bottom (at Moho) superposed by partially molten crust. The upper crust is represented by a granular mixture of low-density cenosphere particles and silica sand, respectively. To keep the models properly dynamically scaled, we take into account the relationship for progressively decelerated plate convergence in the orogens. 

With increasing of both, basal heating and shortening rate, the folds' finite geometry converges to a system of pseudo-symmetric folds, cored by various amounts of the melt with respect to their position in the fold sequence. The dynamics of the fold amplification also depends on the position in the array of folds and is described by four evolutionary steps; initial perturbation, amplification with the melt inflow into axial zones of the folds, locking and simple vertical extrusion. 

With decreasing intensity of basal heating, the total melt amount is lower, deformation is more localized and converges to brittle-ductile coupling. Typical products are thrust systems on a local scale or pop-up structures on a large scale. Melt is localized in form of small fingers underneath the pop-up structures. Relatively colder and slower models display homogeneous thickening.

A higher degree of heating results in melt redistributed along the axial planes of folds. Analysis of the layer interfaces curvature, paths and tortuosity of the material particles in these high-temperature experiments (based on resultant displacements calculated by the PIV method) also revealed asymmetrical evolution of the P-T-t paths for associated limbs of the pseudo-symmetrical folds.

 

How to cite: Závada, P., Krýza, O., Schulmann, K., Lexa, O., and Shu, T.: Modes and geometry of crustal-scale detachment folds in hot orogens – insights from physical modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11171, https://doi.org/10.5194/egusphere-egu22-11171, 2022.

Synorogenic sediments have often been used to constrain nappe movements and geodynamic processes. This contribution presents a case study from the Alps, in which synorogenic deposition (Lech-, Rossfeld-, Losenstein-, and Branderfleck Fms., Gosau Group) is affected by processes on different scales, that have led to a bewildering multitude of interpretations. We add another one.

Presently, the Northern Calcareous Alps (NCA) are a thin-skinned fold-and-thrust belt in the external part of the Austroalpine unit, which represents the upper plate during Cenozoic Alpine orogeny. However, orogeny started in the late Early Cretaceous, when large parts of the Austroalpine and the entire NCA were in a lower plate position. This major geodynamic change also controlled deposition of synorogenic sediments.

Prior to Cretaceous onset of subduction, the NCA were still in sedimentary contact with the underlying lithosphere. Most paleogeographic reconstructions show the NW edge of the Adriatic microplate at the transition from a passive margin in the SW to a transform-dominated margin in the N, as a consequence of Jurassic-Cretaceous opening of the Alpine Tethys. These transform faults apparently offset oceanic units dextrally to the east, however, they have sinistral kinematics, as a result of the northward propagating opening of the Atlantic Ocean.

At the turn from the Early to the Late Cretaceous, the NCA of the external Austroalpine had already been affected by major nappe movements in the foreland of an intracontinental subduction that had initiated along sinistral, roughly E-striking intracontinental transform faults within the Adriatic microplate (Stüwe and Schuster, 2010). Thrusting had propagated across the Adriatic plate to its northern transform boundary (Ortner and Kilian, 2021 in press).

As a consequence, oceanic crust in the N neighboured continental crust S of a transform zone. When shortening resumed in the early Late Cretaceous, continental lithosphere was subducted and replaced by oceanic lithosphere. Thus, the foreland thrust belt became an accretionary wedge. Its surface subsided to bathyal depth, as the surface of oceanic crust is isostatically in a depth of about 4.5 km below sea level, and the surface of continental crust is typically near sea level (e.g., Kearey et al., 2009).

Synorogenic sediments were deposited throughout shortening. They were affected by (i) ongoing contraction associated with tear faulting on the local scale, (ii) thickening of the orogenic wedge by emplacement of thrust sheets on the regional scale, and (iii) subsidence of the thin-skinned wedge controlled by replacement of continental by oceanic lithosphere. Such a multi-scale explanation may solve the long-disputed question of the tectonic setting of the Cretaceous synorogenic sediments of the NCA.

References

Kearey, P., Klepeis, K.A., Vine, F.J., 2009. Global tectonics (3rd ed.). Wiley-Blackwell, Oxford.

Ortner, H., Kilian, S., 2021 in press. Thrust tectonics in the Wetterstein and Mieming mountains, and a new tectonic subdivision of the Northern Calcareous Alps of western Austria and southern Germany. Int. J. Earth. Sci. https://doi.org/10.1007/s00531-021-02128-3

Stüwe, K., Schuster, R., 2010. Initiation of subduction in the Alps: Continent or ocean? Geology, 38, 175-178. https://doi.org/10.1130/G30528.

How to cite: Ortner, H. and Sieberer, A.-K.: From foreland thrust belt to accretionary wedge: Synorogenic sediments monitor a changing geodynamic setting in the Northern Calcareous Alps of the European Eastern Alps, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11281, https://doi.org/10.5194/egusphere-egu22-11281, 2022.

EGU22-12281 | Presentations | TS7.2

The brittle-ductile transition signature in accretionary prism, insight from thermomechanical modeling. Application to Makran 

Sepideh Pajang, Laetitia Le Pourhiet, Nadaya Cubas, Mohammad Mahdi Khatib, and Mahmoudreza Heyhat

Long-term tectonics numerical modelling at accretionary margin scale is a powerful tool to retrieve the influence of many parameters such as the spatial variations of the frictional properties along a simplified interface and its feedback on the deformation. Despite significant analogue and numerical studies on the evolution of accretionary prism, none of them account for heat conservation or temperature-dependent rheological transitions. Since Makran is one of the thickest accretion prisms in the world, the contribution of heat to the rheology of the prism cannot be ignored. Here, we solve for advection-diffusion of heat with imposed constant heat flow at the base of the model domain to allow the temperature to increase with burial. We start with a simple setup of one décollement layer to capture how the brittle-ductile transition affects the structures and geometry of the accretionary prism.

Our results show that a mature brittle-ductile wedge forms four different structural segments that can be distinguished based on topographic slope and deformation. An initial purely frictional segment is characterized by an imbricated zone and active in-sequence thrusts faults at the toe of the wedge. Its topographic slope is controlled by the basal friction of the décollement and is consistent with the critical taper theory prediction. The presence of the smectite-illite transition (dehydration reaction) leads to a flat topographic slope by the drop of friction. This flat segment produces little internal deformation and appears during the early stage of the accretionary prism formation. The third segment is marked by an increase of the topographic slope that begins with the onset of internal distributed viscous deformation in between brittle structures. Viscous deformation appears once the base of the model reaches 180°C while the décollement remains brittle. We refer to that segment as the brittle-ductile transition where both brittle and ductile deformation co-exists within the wedge together with high internal deformation. The last segment of deformation corresponds to the onset of the ductile deformation along the décollement by reaching a temperature of 450°C with an approximate flat zone without effective internal deformation. The topographic slope is again consistent with the critical taper theory, considering that a viscous décollement is equivalent to a brittle décollement of extremely low friction.

Knowing the impact of temperature transitions, we include more complexity in our simulations to increase the relevance of the models with the Makran accretionary prism. We calibrate the basal heat flow from BSR visible along seismic profiles. An intermediate décollement, essential for underthrusting to occur at the rear of the wedge, is added to the simulations. We show that the onset of underthrusting is controlled by the brittle-ductile transition. As tomographic models on land indicate packages with a higher velocity at depth, seamount subduction is another hypothesis tested. We conclude that the subduction of large seamount is accompanied by deep-rooted listric normal faults, whose location migrates through time. Seamount subduction also permits the formation of a large thrust slice zone and lateral variation of basal-erosion which can be followed in seismic profiles of Nankai and Makran subduction zones.

How to cite: Pajang, S., Le Pourhiet, L., Cubas, N., Khatib, M. M., and Heyhat, M.: The brittle-ductile transition signature in accretionary prism, insight from thermomechanical modeling. Application to Makran, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12281, https://doi.org/10.5194/egusphere-egu22-12281, 2022.

EGU22-13531 | Presentations | TS7.2

Paleoproterozoic Cordilleran-Type Tectonics in central West Greenland 

Pierpaolo Guarnieri, Diogo Rosa, Kristine Thrane, Thomas F. Kokfelt, Erik V. Sørensen, and Nigel Baker

A new tectonic model is presented to explain the tectonostratigraphic evolution of the Paleoproterozoic Karrat Group in central West Greenland and the polyphase deformation, magmatism and metamorphism in the Rinkian orogen recorded in Paleoproterozoic rocks and Archaean complexes. The Karrat Group (from c. 71°00’ to 73°00’ N) formed in an intra-cratonic sag basin after c. 2000 Ma with basal quartzites of the Qaarsukassak and Mârmorilik formations unconformably overlaying Archaean gneisses of the Rae Craton. From 1950 to 1900 Ma a carbonate platform represented by the Mârmorilik Formation developed toward the south, while rift related alkaline volcanic rocks represented by the alkaline member of the Kangilleq Formation and syn-rift siliciclastic and volcaniclastic sediments of the Nûkavsak Formation were deposited to the north. The rifting was succeeded by a back-arc system, represented by the transitional member of the Kangilleq Formation. Concomitantly with development of the back-arc system, arc-related granitoids of the Prøven Intrusive Complex (PIC) intruded into and along the basal contact of the Karrat Group around 1900 Ma with major pulses at c. 1870 and c. 1850 Ma. The Karrat Group and the magmatic arc rocks underwent HT-metamorphism at c. 1830–1800 Ma during the collisional phase of the Rinkian orogen. The metamorphic grade increases from greenschist facies in the south, to granulite facies in the north, where the metamorphism is associated with migmatization and emplacement of the S-type Qinngua leucogranites. Extensive thrust emplacement and folding characterize the Rinkian orogen south of the PIC and the eastern boundary of the magmatic arc is reworked along a top to ESE shear zone post-dating the HT-metamorphism. The ESE-ward emplacement of allochthonous thrust sheets during an early stage of thin-skinned tectonics is followed by NE-ward emplacement of basement nappes and finally by a NW-SE compression stage resulting in tectonic inversion of basin normal faults.  The back-arc extension and Cordilleran-type magmatism were driven by eastward subduction of oceanic crust during the Trans-Hudson Orogeny resulting from the convergence of the Superior, Meta Incognita and Rae Archean cratons between 1870–1800 Ma. The Karrat Group north of the PIC together with the time-correlative Piling Group of Baffin Island (Canada) probably represented the passive margin succession of the Rae craton that evolved into a forearc setting during the Trans-Hudson Orogeny. The Rinkian orogen is an example of Cordilleran-type tectonics resulting from the deformation of the Rae continental margin intruded by magmatic arc granites during subduction, followed by HT-metamorphism in the upper plate and the structuring of a back-arc fold and thrust system antithetic to the subducting plate.

How to cite: Guarnieri, P., Rosa, D., Thrane, K., Kokfelt, T. F., Sørensen, E. V., and Baker, N.: Paleoproterozoic Cordilleran-Type Tectonics in central West Greenland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13531, https://doi.org/10.5194/egusphere-egu22-13531, 2022.

EGU22-127 | Presentations | TS7.3

Exhumation of Eocene high-pressure metamorphic rock by coaxial flattening below a Miocene Cycladic-style detachment 

Taylor Ducharme, David Schneider, Bernhard Grasemann, Iwona Klonowska, and Konstantinos Soukis

Structures that accommodate extension during orogenic relaxation significantly modify the crustal architecture of mountain belts. Discerning the tectonic significance of superimposed structures relating to extensional overprint of initially compressional features is therefore critical to the reconstruction of an orogen, and is easiest where the large-scale mechanical interactions between different crustal domains are exposed. In the Aegean region of Greece, low-angle detachment faults of early Miocene age were partially responsible for exhuming Eocene high-pressure, low-temperature (HP-LT) metamorphic rocks of the Cycladic Blueschist Unit (CBU). Extension in the Cyclades commonly occurred along multiple detachment branches at the kilometer scale, either due to arrest of older detachment planes by late Miocene plutonism, or because strain partitioning along multiple, simultaneously active structures was rheologically favourable. We document a third plausible mechanism whereby crustal attenuation is accomplished via distributed coaxial strain in the footwall of a major detachment, described previously in the Cyclades primarily for deep crustal fabrics contemporaneous with peak HP-LT conditions. This style of deformation is recorded below the basal contact of the CBU on the island of Evia, which delineates the boundary of a major tectonic window exposing an underthrust external carbonate platform known as the Basal Unit (locally Almyropotamos Unit). New structural observations, complemented by white mica 40Ar/39Ar and zircon (U-Th)/He ages, suggest that the upper structural levels of the Basal Unit accommodated flattening strain that coincided with Oligo-Miocene extension likely related to the overlying North Cycladic Detachment System. Vertical shortening, with extension in both other principal directions, is evinced by symmetric chocolate-tablet foliation boudinage and conjugate shear bands in the Basal Unit, alongside coeval type-3 refold structures in the overlying CBU. Pseudosection modelling results from Evia further corroborate a late greenschist-facies (320 ± 40 °C, 7 ± 1 kbar) paragenesis for the fabric associated with this extension that post-dates HP-LT metamorphism. Our observations indicate extrusion of the CBU and underlying Basal Unit was accomplished at least in part by coaxial vertical shortening, in contrast to the predominantly non-coaxial strain observed in the footwalls of other major Cycladic detachments.

How to cite: Ducharme, T., Schneider, D., Grasemann, B., Klonowska, I., and Soukis, K.: Exhumation of Eocene high-pressure metamorphic rock by coaxial flattening below a Miocene Cycladic-style detachment, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-127, https://doi.org/10.5194/egusphere-egu22-127, 2022.

EGU22-158 | Presentations | TS7.3

Low temperature geochronology and lithostratigraphy of Folegandros, Cyclades, Greece: relationship between low- and high-angle faults results in crustal mosaic 

Christina Bakowsky, David Schneider, Konstantinos Soukis, and Bernhard Grasemann

Miocene extension of the Aegean region was accommodated by bivergent low-angle crustal-scale detachment systems. Folegandros island, of the southern Cyclades, lies between the SW-directed West Cycladic and S-directed Santorini detachment systems. The NW-SE oriented island is 'peanut'-shaped, consisting of a northern structural dome that exposes the structurally lower Cycladic Blueschist Unit (CBU). The CBU is characterized by coarse-grained marbles intercalated with metabasites and micaschists with a strong greenschist facies overprint. Metabasite lenses locally preserve relict HP minerals, including glaucophane and lawsonite pseudomorphs. The CBU preserves Raman spectroscopy of carbonaceous material (RSCM) peak temperatures >400°C and possesses late Eocene-early Oligocene white mica 40Ar/39Ar ages. At the corset of the island, a discrete tectonic boundary separates the CBU from a less deformed, NE-dipping homocline of Early Cretaceous to early Eocene units in the south. At the base of this package of rocks, the Eleftherios unit consists of alternating low-grade, deformed fine-grained marble and subordinate quartzitic-phyllitic sequences. The uppermost Vighlitsa unit is restricted to the SE coast and is composed of ophiolite phacoids at the base of a deformed marble and quartzitic-phyllitic sequence overlain by a metaflysch with middle Cretaceous marble olistoliths. Dispersed 40Ar/39Ar dates from these lower grade units are Early Cretaceous to early Eocene, consistent with RSCM temperatures <350°C. Based on the lower peak temperatures and Cretaceous to Eocene chronostratigraphy in conjunction with regional lithostratigraphic correlation, we propose the structurally higher Eleftherios and Vighlitsa units are hitherto unacknowledged exposures of the stratigraphically uppermost Pelagonian zone (Mesoautochthonous unit). A strong N-S lineation is dominant across the island, and a ductile top-to-S low-angle detachment system is overprinted by brittle-ductile top-to-N faults and shear bands. The differences in Raman temperatures together with ductile shear sense indicators and lepidoblastic muscovite 40Ar/39Ar ages at the detachment between the CBU and Pelagonian rocks indicate a top-to-S extensional detachment was active during the early Miocene. Middle Miocene zircon and apatite (U-Th)/He ages are comparable from both the CBU and Pelagonian zone and likely reflect cooling (<200°C) attributed to top-to-N extension exhibited by the cooler brittle-ductile structures. A similar lithostratigraphic juxtaposition between the CBU and Pelagonian zone is observed on Thera. Unlike on Folegandros, however, the middle to late Miocene ductile top-to-S low-angle detachment is overprinted by brittle-ductile top-to-S high-angle faults. These new observations reveal persistant top-to-S low-angle extension in the western and southern Cyclades throughout the Miocene. Overprinting high-angle normal faulting preserves structurally higher tectonic units, such as the Pelagonian zone, in fault relay zones.

How to cite: Bakowsky, C., Schneider, D., Soukis, K., and Grasemann, B.: Low temperature geochronology and lithostratigraphy of Folegandros, Cyclades, Greece: relationship between low- and high-angle faults results in crustal mosaic, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-158, https://doi.org/10.5194/egusphere-egu22-158, 2022.

EGU22-967 | Presentations | TS7.3

Structure, strain partitioning and exhumation mechanism during the late stage oblique tectonic evolution of the Variscan Tanneron massif (SE France) 

Josselin Gremmel, Guillaume Duclaux, Michel Corsini, Abel Maillet, Anthony Jourdon, and Jerome Bascou

Oblique tectonic, including transpressional and transtensional movements, is a common feature observed at active plate boundaries. Despite being often inferred at the orogen scale, the interpretation of local structural observations in the context of oblique tectonic regimes remains challenging, especially in ductile terrains. During the last stage evolution of orogenic belts, obliquity is expected to play a key role in controlling strain partitioning and exhumation patterns of deep crustal rocks, as well as the development of brittle structures in the upper crust.

Here, we present new structural data and finite strain analyses of migmatitic rocks exposed in the Tanneron Massif in SE France. This massif, representing the most internal part of the Maures-Tanneron Variscan belt segment, was structured between 320 and 300 Ma during the late stage Variscan orogeny. This late-stage deformation, synchronous to partial melting of the middle crust, the large-scale folding of the migmatitic units and their exhumation has been interpreted to take place in a regional transpressive regime.

New detailed structural mapping carried on in two sectors of the massif highlight different strain patterns with dome-like structures in a migmatite unit to the East, and sub-vertical shear-zones with stretching lineation to the West. However, in these two sectors stretching is dominant and finite constrictional fabrics are ubiquitous. The regional lineation, corresponding to the maximum stretching direction of these L-tectonites is parallel to the large scale and local fold axes. In addition, narrow continental Carboniferous basins oriented roughly parallel to the main ductile fabric opened inside the massif contemporaneously to the exhumation of the L-tectonites. Therefore, our results suggest that local transtension might best describe the tectonic regime associated with the late-stage evolution of the massif. We will discuss these results for the Tanneron massif in the light of a series of preliminary 3D thermo-mechanical numerical models designed to investigate the horizontal and vertical partitioning of deformation in a hot orogen subject to regional oblique deformation.

How to cite: Gremmel, J., Duclaux, G., Corsini, M., Maillet, A., Jourdon, A., and Bascou, J.: Structure, strain partitioning and exhumation mechanism during the late stage oblique tectonic evolution of the Variscan Tanneron massif (SE France), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-967, https://doi.org/10.5194/egusphere-egu22-967, 2022.

EGU22-3129 | Presentations | TS7.3

Protolith and metamorphic ages of eclogites from the Eastern Alps: Implications for the Permian to Cretaceous Wilson cycle of the Austroalpine mega-unit 

Ruihong Chang, Franz Neubauer, Yongjiang Liu, Jnhann Genser, Sihua Yuan, Qianwen Huang, and Qingbin Guan

The Austroalpine mega-unit contains the type locality of eclogites (Haüy, 1822) but their protolith age is largely unknown except that of the Permian Bärofen eclogite, for which three Sm-Nd ages between 275 ± 18 and 275 ± 18 Ma have been reported (Thöni & Jagoutz, 1993, Geochim. Cosmochim. Acta 56, 347–368; Miller & Thöni, 1997, Chem. Geol. 137, 283–310). Therefore, we studied the non-gabbroic eclogites from the Saualpe-Koralpe and Sieggraben Complexes, which are considered to represent a previously coherent subducted and then exhumed fragment of a continental rift, which led to the formation of the late Middle Triassic Meliata oceanic basin. A combined zircon U–Pb and Hf isotopic study, whole-rock geochemistry of two complexes revealed a protolith age of 242.3 ± 2.6 Ma (Middle Triassic) in the Sieggraben Complex, and 283 ± 5 Ma, 255 ± 3 Ma (Early and Late Permian), 251 ± 3 Ma, and 241 ± 3 Ma (Early to Middle Triassic) in the Saualpe-Koralpe Complex. Magmatic zircons from the Sieggraben eclogites have 176Hf/177Hf ratios of 0.283067–0.283174, εHf(t) values of +15.7 to +19.4, and that from Saualpe-Koralpe eclogite have 176Hf/177Hf ratios of εHf(t) 0.282935–0.283090, εHf(t) values of +10 to +17.4 showing their juvenile mantle source rather than significant crustal assimilation. In both complexes, N-MORB geochemical characteristics are established. Associated ultramafic rocks of Sieggraben eclogites as part of oceanic or Permian subcontinental mantle lithosphere suggest a depleted mantle source and a deep subduction environment. Two zircon grains of Sieggraben eclogites with low Th/U ratios yield ages of 113 ± 2 Ma and 86 ± 4 Ma and represent the approximate age of eclogite metamorphism during the Cretaceous. A trondhjemite dike cutting through the eclogite gives a crystallization age of 82.19 ± 0.4 Ma and is formed by partial melting of likely eclogite during decompression. The host metasedimentary rocks of Sieggraben and Saualpe-Koralpe Complexes are interpreted as old continental crust close to the margin of the Meliata basin and were affected by Permian migmatitic metamorphism. Metamorphic zircons of one eclogite from the Saualpe-Koralpe Complex give an age of 87–93 Ma (peak at 91 ± 1.2 Ma). The results of this study combined with previous results are used to present a new model for the tectonic evolution of the distal Austroalpine unit associated with the Meliata Ocean in a Wilson cycle: The Austroalpine Sieggraben and Saualpe-Koralpe Complexes represent a location on the distal continental margin during Permian to Middle Triassic rifting. The mafic rocks are associated with numerous Permian and potential Triassic acidic pegmatites, whereas structurally separated thick Triassic sedimentary cover successions lack any magmatism, likely excluding the present-day eclogite-bearing units as Triassic basement of the sedimentary cover successions.

The now eclogite-bearing piece of continental crust adjacent to the Meliata oceanic lithosphere subducted during Early Cretaceous times to mantle depth. The subducted continental crust was then exhumed incorporating even ultramafic mantle rocks. During exhumation and decompression of mafic rocks, partial melting took place forming the trondhjemite dike in Late Cretaceous times.

Acknowledgment: The study is financially supported by NSFC (91755212).

How to cite: Chang, R., Neubauer, F., Liu, Y., Genser, J., Yuan, S., Huang, Q., and Guan, Q.: Protolith and metamorphic ages of eclogites from the Eastern Alps: Implications for the Permian to Cretaceous Wilson cycle of the Austroalpine mega-unit, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3129, https://doi.org/10.5194/egusphere-egu22-3129, 2022.

EGU22-4126 | Presentations | TS7.3

Orogenic evolution of Western Europe controlled by lithosphere evolution 

Frédéric Mouthereau, Paul Angrand, Anthony Jourdon, Sébastien Ternois, Naïm Celini, Abdeltif Lahfid, and Jean-Paul Callot

Processes driving orogenic styles and long-term isostatic versus dynamic support of the topography have been largely debated in domains of plate convergence. Tectonics of orogens reflect the interactions between mantle flow driving plates and the inherited rheology and composition of moving plates, which are however still strikingly ill-defined. A recent review of the evolution of the weak European lithosphere, based on geological, geophysical, petrological data, has shed lights on the role played by lithospheric mantle chemo-magmatic history and structure, which inherits past subduction/collision (e.g. Variscan) and rifting events (Tethys/Atlantic), on crust-mantle coupling, plate-mantle coupling, defining Alpine-type orogens. While the details of the Cenozoic topographic history of peri-Mediterranean orogens are understood to be controlled by the rheology and architecture of rifted margins combined with changing large-scale kinematic boundary conditions (e.g. Atlas, Betics, Pyrenees, Alps), their post-10 Ma, quaternary to current surface (Insar) and tectonic (seismic) evolution appears to illustrate increasing control by magmatism and flow at the asthenosphere-lithosphere limit as well as local thermal re-equilibration. We argue that isostatic processes in western Europe linked in part to long lithosphere evolution can be first-order drivers of the post-collisional evolution of the peri-Mediterranean orogenic belts and their still active surface and tectonic evolution.

How to cite: Mouthereau, F., Angrand, P., Jourdon, A., Ternois, S., Celini, N., Lahfid, A., and Callot, J.-P.: Orogenic evolution of Western Europe controlled by lithosphere evolution, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4126, https://doi.org/10.5194/egusphere-egu22-4126, 2022.

EGU22-4488 | Presentations | TS7.3

Early Carboniferous magmatism and metamorphism in the Schladming Complex, Eastern Alps: Constrain on the subduction of Rheic Ocean 

Qianwen Huang, Yongjiang Liu, Franz Neubauer, Johann Genser, Sihua Yuan, Ruihong Chang, Qingbin Guan, and Shengyao Yu

The Schladming-Seckau system as one part of Middle Austroalpine Unit experienced the Variscan event and overprinted by the Alpine orogeny, which is a key to reveal the tectonic evolution history of Easterrn Alps (Neubauer and Frisch, 1992). Recently, Cambrian-Ordovician magmatism and Permian-Triassic magmatism were reported in the Schladming Complex (Huang et al., 2021), they are related to the subduction of Proto-Tethys Ocean and opening of Meliata back-arc basin, respectively. Here, we present the whole-rock geochemistry, zircon U-Pb and Hf isotopic analysis of paragneiss and granitic rocks in the Schöder Valley to constrain the relationship between Schladming Complex and Variscan orogeny.

The biotite-plagioclase gneiss, hornblende-gneiss, mica-schists formed the main body of the Schladming Complex (Neubauer et al., 2018). The zircon age data of biotite-plagioclase gneiss show the peak age of 603 Ma and 487 Ma with dominated metamorphic age of 355 Ma, indicating the rocks mainly sourced from the Neoproterozoic and Ordovician rocks and suffered the strong Carboniferous metamorphism. Similar to the biotite-plagioclase gneiss, two Ordovician granitic gneisses (485Ma – 483 Ma) also comprise significance metamorphic age of 355 Ma. Their primitive mantle-normalized multiple elements patterns exhibit strong depleted in Nb, Ta, Ti, Zr, and Hf, showing a typical subduction-related features.

Not only the metamorphism shows the Carboniferous subduction event, but also two granites prove the existence of Carboniferous magmatism. These two granites have crystallization age of 353 Ma and 355 Ma, respectively. The zircon εHf(t) scatter between -1.29 and 6.04, suggesting the magma of granite derived from deplete mantle and mixed with the continent materials. Their geochemical data display subduction-related characteristics that depleted in HFSE (eg. Nb, Ta, Ti, Zr, and Hf) and enriched in LILE (eg. Ba, Th, K). The Carboniferous metamorphism and magmatism together showing the subduction of Rheic Ocean before Variscan orogeny in the Eastern Alps.

Acknowledgement: The study is financially supported by NSFC (91755212).

 

References

Huang, Q.W., Liu, Y.J., Genser, J., Neubauer, F., Chang, R.H., Yuan, S.H., Guan, Q.B., Yu, S.Y., 2021. Permian-Triassic A-type and I-type granites in the Schladming Complex, Austroalpine Unit: Constraints on subduction of Paleo-Tethys Ocean in the Eastern Alps, In: Li, S., Santosh, M. (Eds.), The 2021 Annual Convention of the International Association for Gondwana Research (IAGR) and the 18th International Symposium on Gondwana to Asia. Gondwana Research, China, Qingdao, pp. 21-22.

Neubauer, F., Frisch, W., 1992. Pre-Mesozoic geology of the Middle and Upper Austro-Alpine metamorphic basement east of the Tauern Window. 17-36.

Neubauer, F., Genser, J., Heberer, B., Etzel, A., Olive, S., 2018. Field Trip Post‐EX‐1 Transect across the Eastern Alps, XXI International Congress of the Carpathian Balkan Geological Association Salzburg, Austria, pp. 137-222.

How to cite: Huang, Q., Liu, Y., Neubauer, F., Genser, J., Yuan, S., Chang, R., Guan, Q., and Yu, S.: Early Carboniferous magmatism and metamorphism in the Schladming Complex, Eastern Alps: Constrain on the subduction of Rheic Ocean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4488, https://doi.org/10.5194/egusphere-egu22-4488, 2022.

EGU22-6002 | Presentations | TS7.3

The Mallorca stranded and extended foreland thrust belt, its missing hinterland and the tectonic evolution of the Western Mediterranean 

Guillermo Booth-Rea, Lluís Moragues, Patricia Ruano, Jose Miguel Azañón, Karoly Hidas, and Carlos Garrido

The Mallorca Foreland Thrust Belt (FTB) is stranded in the Western Mediterranean, isolated among deep basins from its corresponding hinterland domain. Here we integrate new structural data from Mallorca with preliminary detrital zircon data and previously published stratigraphic, paleontological, biogeographic and tectonic constraints, to provide a new tectonic evolutionary model for the Western Mediterranean. Mallorca underwent two Cenozoic rifting phases in the Oligocene and Serravallian, before and after the development of its FTB structure. The first Cenozoic extensional event produced Oligocene to Early Miocene semigrabens coeval to felsic volcanism in Mallorca and the Valencia trough (»29-19 Ma). The Oligocene extension affected a major part of the Western Mediterranean, opening the Liguro-Provençal and other back-arc basins after the collapse of the Palaeogene AlKaPeCa orogen, and Mallorca, its former hinterland. Continued plate convergence inverted the Oligocene back-arc basin, and onshore grabens during the Early-Middle Miocene (19-14 Ma), producing the Mallorca FTB and nucleating a new subduction system in the Westernmost Mediterranean. Renewed subduction probably initiated through the collapse of a NW-SE trending transform fault, inherited from the Mesozoic opening of the Tethys ocean. Development of the Mallorca WNW-directed FTB and subduction of the South-East Iberian passive margin occurred at this stage, individualizing the Betic-Rif slab that initiated its westward retreat. Moreover, detrital zircon age-population data show that the Betic and Mallorca foreland basins shared the same hinterland, equivalent to rocks of the Malaguide complex, located at the top of the AlKa orogenic domain. A later, second rifting event produced the extensional collapse of the Mallorca FTB during the Serravallian (»14-11 Ma), coeval to topographic uplift of the Island. This later rifting was polyphasic, with two orthogonal extensional systems, producing first NE-SW, and then NW-SE extension that favored the development of continental internal drainage basins. These basins shared common insular fauna with those overlying the Alboran domain in the Internal Betics, probably forming part of the same emerged archipelago, which is further supported by biogeographic data indicating a Middle Miocene common ancestry for several taxa now present in the Betics and Mallorca. Serravallian extension occurred at the northern edge of the subduction system coeval to the Algero-Balearic basin opening. Extension initiated towards the SW direction of slab tearing or detachment, and later rotated to a NW-SE direction, probably in response to flexural and isostatic rebound. This tectonic response propagated to the Betics between the Late Tortonian and Present. By these tectonic mechanisms, including slab retreat, edge delamination under continental FTB areas of the orogen and slab tearing, the Mallorca hinterland was driven towards the southwest, contributing to the present isolation of Mallorca from its Betic hinterland.

How to cite: Booth-Rea, G., Moragues, L., Ruano, P., Azañón, J. M., Hidas, K., and Garrido, C.: The Mallorca stranded and extended foreland thrust belt, its missing hinterland and the tectonic evolution of the Western Mediterranean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6002, https://doi.org/10.5194/egusphere-egu22-6002, 2022.

The İstanbul-Zonguldak Tectonic Unit (NW Turkey) is regarded as the unmetamorphosed continental fragment of Far East Avalonia in the Pontides. It is to the east of the Rhodope-Strandja Massif, which is a part of the metamorphosed section of Far East Avalonia, and is to the north and west of the Sakarya terrane. The Variscan orogeny in the Pontides defines as the collision of the Sakarya terrane with the İstanbul-Zonguldak Tectonic Unit during the early Carboniferous. But, the Late Carboniferous arc magmatism (c. 306-301 Ma) in the eastern sector of the İstanbul-Zonguldak Tectonic Unit rejects this view. Here, I present analytical data of basalt dykes in the western sector of the İstanbul-Zonguldak Tectonic Unit. Basalt dykes have porphyritic and holohyaline textures. Geochemically, they display calc-alkaline affinities and show depletion in Nb relative to Ce. They contain subduction components and are associated with the arc-related geodynamic setting. U–Pb dating on igneous zircons from two basalt dykes yielded Late Carboniferous ages of ca. 321.6 ± 1.6 and 311.4 ± 0.75 Ma (2σ), and their Pb-loss ages from the white spot in zircons calculated Early Permian ages of ca. 295.1 ± 1.1 to 285.0 ± 1.3 Ma and 295.5 ± 1.2 to 284.0 ± 1.4 Ma, respectively. In conjunction with the data from the literature, the Late Carboniferous arc magmatism (c. 321-311 Ma) in the western side of the İstanbul Zonguldak Tectonic Unit corresponds to the Late Carboniferous arc magmatism (c. 306-301 Ma) in the eastern side of the İstanbul Zonguldak Tectonic Unit, thus indicating that the Rheic Ocean continued to subduct under Far East Avalonia during the Carboniferous. As for the Pb-loss ages obtained from the Late Carboniferous arc basalt dykes, the earliest-latest Cisuralian ages (c. 295-285 Ma) correspond to regional deformation events at the Carboniferous-Permian boundary in the Rhodope-Strandja Massif (c. 298-296 Ma) and at the ending of the early Permian in the Sakarya terrane (c. 282-275 Ma), respectively. All in all, I suggest that the docking of Far East Avalonia, including the İstanbul-Zonguldak Tectonic Unit and Rhodope-Strandja Massif, with the Sakarya terrane formed during the early Permian instead of the early Carboniferous.

How to cite: Şen, F.: Early Permian deformational ages of Late Carboniferous basalt dykes in the İstanbul-Zonguldak Tectonic Unit: Implications for the Variscan orogeny in the Pontides, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6513, https://doi.org/10.5194/egusphere-egu22-6513, 2022.

EGU22-7350 | Presentations | TS7.3

Oblique exhumation of HP metaophiolite at the southern termination of the Western Alps (Italy). 

Laura Federico, Laura Crispini, Michele Locatelli, and Paola Cianfarra

The exhumation of high-pressure (HP), metaophiolitic terrains is a long-studied process, and many different models have been proposed so far, since the problem of how dense HP metamorphosed oceanic mafic and ultramafic rocks are exhumed from deep is crucial to understanding processes occurring at the plate interface and mantle wedge within subduction zones.

However, the exhumation process may obliterate peak-related structures and metamorphic associations at different degrees. In the Western Alps, one of the most studied orogen of the world, some HP terrains still preserve an almost complete stratigraphy of the oceanic lithosphere (e.g., the Monviso and Zermatt-Saas Massifs).

On the contrary, the Voltri Massif (VM), which crops out at the southern termination of the Alpine orogen (Ligurian Alps), is at places characterized by a high degree of disruption of the original stratigraphy.

The VM shows different features in the eastern and western sectors: in the eastern sector the high-pressure eclogitic-blueschist rocks are frequently embedded as bodies and lenses within serpentinite or metasediments, which act as a low strength “matrix” that accommodates most of the strain. This has led to the interpretation of the massif as a tectonic mélange, formed inside the subduction channel (Federico et al., 2007).

The western sector, on the contrary, contains relics of disrupted mélange associated to more coherent slices of metamorphic oceanic lithosphere.

Regarding the structural architecture, the VM eastern sector shows a steeply dipping foliation, steeply dipping blueschist to greenschist stretching lineation, high shear strain and prevalent structures typical of non-coaxial flow (Capponi and Crispini 2002). These structures are formed during the progressive exhumation from blueschist to greenschist facies conditions.

On the other side, the western part of the Massif is characterized by shallow-dipping fabrics and prevalent structures mostly dominated by strain flattening. Here structures related to the HP stage are better preserved and the greenschist-facies overprint is less pervasive and static at places.

Combination of new and reviewed structural data collected during several decades of fieldwork, geological mapping, PT-paths and geochronological data, points to a model of exhumation in which a non-coaxial transpressional zone played a fundamental role. Important rotation probably occurred at this stage, since the eastern high-strain zone is now perpendicular to the main orogen strike. This is likely due to the peculiar geodynamic position of the VM, at the tip of the alpine subduction zone and to the interference and lateral transition to the embryonic Apennine belt.

 

Capponi G., Crispini L. (2002) Structural and metamorphic signature of alpine tectonics in the Voltri massif (Ligurian Alps, North-Western Italy).

Federico L., Crispini L., Scambelluri M., Capponi G. (2007) Ophiolite mélange zone records exhumation in a fossil subduction channel Geology, 35/6; p. 499–502; doi: 10.1130/G23190A.1

How to cite: Federico, L., Crispini, L., Locatelli, M., and Cianfarra, P.: Oblique exhumation of HP metaophiolite at the southern termination of the Western Alps (Italy)., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7350, https://doi.org/10.5194/egusphere-egu22-7350, 2022.

EGU22-7989 | Presentations | TS7.3

Hydrothermal Manganese mineralization in a Triassic back-arc rift-related volcaniclastic succession of the Cycladic Blueschist Unit, Greece 

Christina Stouraiti, Stylianos Lozios, Konstantinos Soukis, Constantinos Mavrogonatos, Harilaos Tsikos, Panagiotis Voudouris, Hao Wang, Christoforos Zamparas, and Konstantinos Kollias

The Cycladic Blueschist Unit (CBU) of the Aegean (Greece) contains several occurrences of metamorphosed Manganese mineralization within a Triassic volcaniclastic sequence. The latter includes quartz-mica schists intercalated with bimodal metavolcanics and blue-grey marble layers. SHRIMP U-Pb zircon dating has documented the Triassic age (~242 Ma) of the volcanic rocks. Herein we revisit the Mn metallogenic system of the CBU through an extensive study of Mn mineralization at Varnavas area, Northern Attica, and a similar occurrence at central Andros Island (Mparades hill). Manganese mineralogy at both localities is manifested in a typical high-P metamorphic silicate assemblage dominated by piemontite, spessartine garnet, and minor pyroxmangite (rhodonite). At Andros, Mn-rich subdomains contain brecciated braunite micronodules. The preservation of similar nodular form is documented from Varnavas, comprising dominant todorokite, lesser hollandite, pyrolusite, and minor Mn-bearing hematite. The contrasting Mn oxide mineralogy at the two sites is tentatively interpreted as the result of locally incomplete reduction of precursor Mn(IV) phases during metamorphism. Common geochemical characteristics of the Mn-rich rocks include low transition metal concentrations; positive-sloping, PAAS-normalized REE spidergrams; positive Ce anomalies of variable magnitude across individual samples; and high As, Ba, Pb. The geochemical variability recorded is ascribed to the varying mixing of a hydrothermal-sourced, hydrogenous metalliferous component that precipitated penecontemporaneously with the deposition of the host tuffs. The primary Mn precipitates are thought to have been in the form of tetravalent Mn assemblages, which may locally be partially preserved through metamorphism, as appears to be the case in the Varnavas occurrence. All these reveal the interplay between the felsic/intermediate back-arc volcanism and associated hydrothermal activity and the Mn mineralization within the rift setting of the CBU domain.

How to cite: Stouraiti, C., Lozios, S., Soukis, K., Mavrogonatos, C., Tsikos, H., Voudouris, P., Wang, H., Zamparas, C., and Kollias, K.: Hydrothermal Manganese mineralization in a Triassic back-arc rift-related volcaniclastic succession of the Cycladic Blueschist Unit, Greece, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7989, https://doi.org/10.5194/egusphere-egu22-7989, 2022.

EGU22-8740 | Presentations | TS7.3

Discovery of sheath folds in the Adula nappe and implications for the tectonic evolution (Central Alps) 

Michele Perozzo, Matteo Maino, Filippo Schenker, and Silvio Seno

Orogenic deformation patterns show intricate overprinting and structural relations, variations of style and orientation of folds and sense of shear, which are traditionally interpreted as due to polyphase deformation, i.e. distinct deformation phases separated by periods of tectonic quiescence. The Adula nappe in the Central Alps displays exceptional exposures of complex internal structures involving heterogeneous rocks (meta-pelitic and meta-granitic gneiss, micaschists, amphibolites, eclogites, minor quartzites and limestones). The Adula structures are distinguished through the style and the orientation of folds, schistosity and the observation of refolded folds. Structural features show a great variability within the unit, making the structures along the nappe difficult to correlate. However, the Adula deformation patterns are classically interpreted as generated by multiple, distinct deformation phases (five deformation phases; D1-5), despite only one schistosity and lineation may be clearly recognized in the field. Kinematic indicators indicate dominant top-to-N sense of shear, although local top-to-S shear is interpreted as developed during the D3 backfolding phase (e.g.  Löw 1987; Nagel 2008). In this contribution, we show a first recognition of sheath folds from the central part of the Adula nappe, the largest high-pressure nappe of the Central Alps. We performed detailed geological mapping (scale 1:10’000) and structural characterization of the spectacular outcrops of the Piz de Cressim glacial cirque. Here a large antiform is described as the main structure associated with the D3 backfolding phase. We show that the meso/leucocratic heterogeneous rocks (orthogneisses, micaschists, migmatitic gneisses, amphibolitic lenses) form highly non-cylindrical folds. Sheath folds are highlighted by several centimetre to meters scale omega and elliptical eye-structures in cross sections perpendicular to the shear direction (y-z plane). All lithological units show one penetrative foliation and a related stretching lineation with variations in orientation. We suggest that the Cressim antiform formed during progressive top-to-N deformation accomplished within rheological heterogeneous rocks, rather than as the results of multiple distinct deformation phases.

How to cite: Perozzo, M., Maino, M., Schenker, F., and Seno, S.: Discovery of sheath folds in the Adula nappe and implications for the tectonic evolution (Central Alps), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8740, https://doi.org/10.5194/egusphere-egu22-8740, 2022.

EGU22-9976 | Presentations | TS7.3

Late to Post-Variscan tectonics in the Sardinia Einstein Telescope candidate site (Italy): insights from Structural Survey and Electrical Resistivity Tomography 

Giovanni Luca Cardello, Leonardo Casini, Domenico D'Urso, Vittorio Longo, and Giacomo Oggiano

In north-eastern Sardinia, due to the present-day geodynamic quiescence of the island and its very low seismicity and anthropogenic seismic noise, an area has been candidate for hosting the Einstein Telescope (ET). ET is the European third-generation underground interferometric detector of gravitational waves, whose functioning requires a rocky volume virtually devoid of permeable fractures ideally not crossed by main regional faults. Hereby, we present the structural and Electrical Resistivity Tomography (ERT) features of the most relevant brittle structures in the ET candidate site.

The late- to post-Variscan tectonics in Sardinia is accompanied by extensive magmatism giving way to the Corsica-Sardinia Batholith emplacement. This is followed by a dense dyke swarm of bimodal mafic-felsic composition. These dykes are hosted in the batholith and its host metamorphic basement, being their trends reflecting the stress field of the new-formed Variscan crust during early Permian. Field evidence, shows that a ductile to brittle fault network affects both the Variscan metamorphic basement and the late-Variscan plutons. Fault zones are generally NNW-, and WSW-striking and are associated with more altered bedrock and/or occasionally pseudotachylite-bearing cataclastic bands that have been locally injected by hydrothermal fluids, as testified by thick quartz veins and chlorite-rich selvedges. Near two new drilling sites (ca. 250 m total depth), ERT shows a stratified resistivity array, that consists of up to three electrolayers with variable distribution and thickness. As supported by field observation, we have interpreted the more conductive electrolayer as regolith and alluvial units associated with minor faults, while the most resistive electro-layers correspond with the less-fractured granitoids. Overall, the large deep conductive anomalies are bounded by suddenly graded resistivity drops tracing fault systems that are NNW-, N(NE)- and WSW-striking. Upscaling the local results, which provide an accurate estimate of satured fault geometry at depth, we recognize that: i)  the post-Variscan brittle structures mirror the trend of Permian dykes, sills and veins; ii) the main fault zones that underwent strike-slip reactivation were site of later hydrothermal circulation possibly related to Oligocene-Aquitanian tectonics. Further studies are needed to constrain the actual pattern of differential uplift to exclude the presence of neotectonics in the area. Thus, direct dating of faults and dykes and new Global Navigation Satellite System data acquisition could constrain the age of faulting and the differential uplift contribution into the eventual current reactivation of the inherited Variscan structures.

How to cite: Cardello, G. L., Casini, L., D'Urso, D., Longo, V., and Oggiano, G.: Late to Post-Variscan tectonics in the Sardinia Einstein Telescope candidate site (Italy): insights from Structural Survey and Electrical Resistivity Tomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9976, https://doi.org/10.5194/egusphere-egu22-9976, 2022.

EGU22-11228 | Presentations | TS7.3

Amorgos Unit: a long-lost fragment of the Pelagonian domain identified within the retro-wedge of the Oligocene Hellenic Subduction zone 

Sofia Laskari, Konstantinos Soukis, Daniel Stockli, Stylianos Lozios, and Alexandra Zambetakis-Lekkas

The Attic- Cycladic Crystalline Complex (Aegean Sea, Greece) is characterized by a complex history emanating from the interplay of geodynamic processes acted during successive stages of subduction zone underplating, early syn-convergence, and late extensional exhumation. Extensional tectonics strongly impacted the already formed orogenic buildup, leading to intensively denudated and locally preserved upper plate rocks that constitute the hanging walls of several detachment systems. The dominant Cycladic Blueschist Unit (CBU) and the structurally lowermost Cycladic Basement and Basal Units occupy the footwalls of these detachment systems, juxtaposed against the upper plate Pelagonian-derived fragments. Amorgos Unit is considered to occupy a structurally lower position and is correlated to the Basal Unit. This study utilizes tectonostratigraphic, detrital zircon provenance, and (U-Th)/He data to shed light on the paleogeographic and tectonic position of the Amorgos Unit in the Cycladic archipelago and potentially offer valuable insights for better understanding the architecture of the Hellenic subduction orogen.

Amorgos Unit presents a low-grade metamorphosed lithostratigraphy with a basal metaconglomerate, an intermediate carbonate sequence marked by various sedimentary facies of neritic and pelagic character, and an Eocene (meta)flysch, which preserves Nummulite fossils. The basal metaconglomerate has incorporated a metabasite block showing HP metamorphic conditions higher than the country rocks, which is either an olistolith or a tectonically incorporated slice. Detrital zircon U-Pb analysis of the basal metaconglomerate revealed a dominant Ediacaran age cluster and diverse basement rocks in the source area, including recycled Cadomian and Carboniferous affinities. MDA calculations yielded a Mid- Permian and Precambrian age for the matrix and the high-grade clasts, respectively. The metaflysch yielded Triassic- Jurassic MDAs and showed DZ distributions with a dominant Carboniferous input (Variscan affinities), suggesting Pelagonian-derived source areas. The structural evolution of Amorgos includes an early stage (Dn-Dn+1) internal tectonic imbrication in response to NW-ward advancing thrust sheets in the retro-wedge of the Late Eocene – Oligocene Hellenic subduction zone. The final structural history involves extensional low- and high-angle normal faulting (Dn+2/3) with top to SE kinematics. Zircon (U-Th)/He ages revealed exhumation below ~200 °C during the Early –Mid Miocene (18-14 Ma). Significant similarities in lithostratigraphy, structural-exhumation history, and structural position between Amorgos Unit and the Pelagonian hanging wall of the Santorini Detachment System on Santorini island suggest their close spatial relationship. From all the above, we conclude that Amorgos Unit is part of the Pelagonian upper plate, structurally above the Cycladic Blueschist Unit, and paleogeographical located at the southern Pelagonian margin.

How to cite: Laskari, S., Soukis, K., Stockli, D., Lozios, S., and Zambetakis-Lekkas, A.: Amorgos Unit: a long-lost fragment of the Pelagonian domain identified within the retro-wedge of the Oligocene Hellenic Subduction zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11228, https://doi.org/10.5194/egusphere-egu22-11228, 2022.

EGU22-11567 | Presentations | TS7.3

3D geomodelling of multiphase ductile and brittle deformations: a unique tool for quantifying structural relationships and tectonic evolution (Penninic units of the NW Alps) 

Gloria Arienti, Davide Bertolo, Andrea Bistacchi, Giorgio Vittorio Dal Piaz, Giovanni Dal Piaz, and Bruno Monopoli

The North-Western Alps represent the better-known orogenic playground worldwide, exposing the stack of the Western Austroalpine, Penninic, and Helvetic metamorphic nappes, separated by ophiolitic sutures. However a modern and detailed 3D structural model, including the complexity of polyphase ductile and brittle structures, does not exist, and the reference 3D model is still the Argand’s (1911) block diagram.

Here we present preliminary results of a new 3D structural model of a large area (1300 km2) running along the Italian-Swiss boundary ridge, from the Helvetic Mont Blanc massif to the Penninic Monte Rosa nappe, including all main Penninic and Austroalpine units.

Input data are represented by structural surveys and detailed geological mapping, representing a truly 3D dataset thanks to a difference in elevation, from valley floors to mountain summits, of 3-4 km.

Our modelling workflow is based on a first step of conceptual modelling in vertical cross-sections, based on classical and sound structural concepts, followed by interpolation with implicit surface algorithms: advanced geomathematical tools allowing to model, under some conditions, complex structures such as those arising from multiphase ductile and brittle deformations.

This project aims at improving our understanding and our capacity to quantify some fundamental processes of Alpine tectonics. In addition to better representing and quantifying structures that were already qualitatively known, we have finally solved some problems that could not be solved in 2D.

For instance, we will present the solution to a long-lasting debate on a structure, known as the “Accident Col de Bard-Saint Nicolas”, that has been discussed for 25 years. Supported by field work, we demonstrated that the “Accident” is a brittle normal fault that represents the Miocene western continuation of the Aosta-Ranzola normal fault. This also solves problems of correlation within the Grand St-Bernard, since the “Accident” juxtaposes the highest nappe of the system (Mont Fort, to the N) to the lowermost (Ruitor) with tectonic elision of intermediate units.

A similar debate has been solved about the Aouillette ophiolitic unit, a portion of the Combin Nappe, from which it is separated by a graben limited by Oligocene and Miocene normal faults.

Another important outcome of the 3D model is the clear distinction between sections of the orogenic wedge characterized by different tectonic styles, namely (i) an inner Austroalpine-Upper Penninic domain with sub-horizontal nappes, eclogitic and greenschist peak metamorphism, and both Oligocene and Miocene brittle normal faults; (ii) an intermediate sector represented by the Grand St-Bernard nappe system, with blueschist peak metamorphism and prevailing Miocene brittle faults; and (iii) an outer system with low-T greenschist peak metamorphism, younger thrusts and no Miocene or Oligocene normal faults.

In addition, a quantitative and detailed 3D model is invaluable as a basis for applications, such as those related to the circulation and storage of deep water resources hosted in the bedrock, including geothermal fluids. We feel confident that this kind of application could result in a renewed interest for fundamental studies in tectonics and structural geology in the circum-Mediterranean Variscan and Alpine belt.

How to cite: Arienti, G., Bertolo, D., Bistacchi, A., Dal Piaz, G. V., Dal Piaz, G., and Monopoli, B.: 3D geomodelling of multiphase ductile and brittle deformations: a unique tool for quantifying structural relationships and tectonic evolution (Penninic units of the NW Alps), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11567, https://doi.org/10.5194/egusphere-egu22-11567, 2022.

EGU22-65 | Presentations | TS7.4

Middle Permian calc-alkaline basalts and ferroan rhyolites in the Istanbul Zone, NW Turkey: Evidence for Permo-Triassic subduction 

Cumhur Babaoğlu, Gültekin Topuz, Aral Okay, Serhat Köksal, Jia-Min Wang, and Fatma Köksal

Middle Permian bimodal volcanic rocks exposed in the Kocaeli Peninsula represent the first igneous event in the entire Paleozoic record of the Istanbul Zone together with coeval acidic intrusions reported from other parts of the zone. These volcanic rocks crop out as intercalations at the lower horizons of Permian-Earliest Triassic fluvial sedimentary rocks and mainly include basalts and rhyolites with subordinate andesites and rhyolitic tuffs. The basalts were derived from 1-3% partial melting of spinel peridotite in the lithospheric mantle; their high Mg-numbers (Mg# = 63-68) along with Ni (85-136 ppm) and Cr (198-240 ppm) concentrations point to derivation from near-primary mantle melts with minor fractionation. These rocks did not undergo low-pressure plagioclase crystallization based on the lack of a Eu anomaly (Eu/Eu* = 0.95-0.99). Their vesicles are filled by secondary calcite, epidote, pumpellyite, albite and chlorite due to hydrothermal alteration under subgreenschist facies conditions whereby temperatures ranged between 250-300°C. The rhyolites are ferroan [FeO*/(FeO*+MgO) = 0.87-0.96], characterized by high Zr concentrations (279-464 ppm) and compositionally similar to A2-type granitic magmas. Incompatible trace element ratios, rare earth element patterns, initial εNd isotopic data along with temperatures of the rhyolitic melts and absence of inherited zircons in the rhyolites collectively suggest that the rhyolites were derived from fractional crystallization of some basaltic melts in a crustal magma chamber with plagioclase fractionation and minor crustal contamination while the basalts were directly derived from the lithospheric mantle and reached the surface with negligible fractionation. Both volcanic rocks display diagnostic features of subduction-zone melts such as (i) medium- and high-K calc-alkaline affinity and (ii) enrichment in large-ion lithophile elements (LILE) but depletion in high-field strength elements (HFSE) (e.g., Nb-Ta troughs). U-Pb dating of zircon grains extracted from one rhyolite sample yielded a concordia age of 262.7 ± 0.7 Ma (2σ) (Capitanian). The observation that the rhyolites occur near the base of the associated sedimentary rocks places a tight constraint on the age of deposition of these deposits. The bimodal nature of the volcanic rocks, A2-type signature of the rhyolites, local stratigraphic record and data from regional geology (e.g., possible correlation with Late Permian-Early Triassic A-type rift-related granites in Carpathians and Balkans) all indicate an extensional event in the region which started in Middle Permian and resulted in the deposition of Early Triassic quartz sandstones. This extension seems to have taken place above a subduction zone developed in response to a Late Paleozoic-Triassic ocean floor (Paleo-Tethys) dipping northward beneath Laurasia, as evidenced by Permo-Triassic accretionary melanges restricted to Sakarya Zone. In conclusion, geochronological, geochemical and regional data provide additional evidence that the Paleo-Tethys Ocean was subducting northward beneath Laurasia during Permian time.

How to cite: Babaoğlu, C., Topuz, G., Okay, A., Köksal, S., Wang, J.-M., and Köksal, F.: Middle Permian calc-alkaline basalts and ferroan rhyolites in the Istanbul Zone, NW Turkey: Evidence for Permo-Triassic subduction, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-65, https://doi.org/10.5194/egusphere-egu22-65, 2022.

EGU22-322 | Presentations | TS7.4

Paleozoic development of OIB and see-mounts in the Turkestan Ocean within the Khaidarkan and Ulug-Too deposits, South Tianshan (STS) 

Baiansuluu Terbishalieva, Oleh Hnylko, Larysa Heneralova, and Johanne Rembe

The study area is situated in the Ulug-Tau and Khaidarkan gold-antimony-mercury deposits in the South Tienshan (STS). Together with Khadamzhai, Chauvai, and Abshyr deposits, they can be grouped into one ore province. The STS consists mainly of middle and late Paleozoic marine sedimentary rocks, which were deposited in the Turkestan Ocean and on the adjacent continental margins. They crop out along with subordinate metamorphic rocks, arc-related and intraplate volcanic suites, and ophiolites. Various lithologies were juxtaposed together in an accretionary prism during the late Carboniferous - early Permian closure of the Turkestan Ocean.

In the investigated area, Late Silurian to Devonian limestones of the Aktur carbonate platform cover both the shales of the Pulgon Formation (Fm.) (Zarhar-Say) and the basalts with gabbro bodies. Gabbro specimens were sampled for absolute age determination by amphibole 40Ar/39Ar geochronology. Volcanic rocks related to the basement of the Silurian-Carboniferous Akturian carbonate platform, part of the regional nappes of Osh-Uratyube, have been studied by Biske et al., (2019) and our group. The nappe sits on top of basaltic rocks of the Chonkoy Fm. and andesites, tuffs, and carbonate rocks of the Dedebulak Fm. In the latter unit, the volcanic suite forms the lower member which is overlain by Cambrian limestone and dolomite with intercalations of radiolarite (upper member). The volcanic rocks at the base of the Aktur carbonate platform succession indicate the Early Paleozoic geodynamic situation in the Turkestan Ocean as well as about the structure of the Khaidarkan and Ulug-Too gold-antimony-mercury deposits. The Ulug-Tau orefield is situated along the mélange zone at the base of the Aktur nappe.

Results of geochemical and geochronologic analyses (in progress) show that the basalts and basaltic andesites of the lower member of the Dedebulak Fm. formed in an island-arc setting. These volcanic rocks confirm the existence of Early Paleozoic island arcs in the Turkestan Ocean. In a later stage, those arcs possibly died out and were overlapped by carbonate platforms. For the Aktur carbonate platform, it can be assumed that it was detached from the Cambrian island arc basement during the Late Carboniferous and was added to the accretionary prism as the Aktur Nappe. The Cambrian island arc basement (Dedebulak Fm.) formed another thrust-sheet unit as part of the accretionary prism. Plastic Silurian shales and other sediments, primarily located between the Aktur carbonate platform sediments and the Cambrian island arc volcanic rocks, were incorporated into the polymictic mélange.

 

How to cite: Terbishalieva, B., Hnylko, O., Heneralova, L., and Rembe, J.: Paleozoic development of OIB and see-mounts in the Turkestan Ocean within the Khaidarkan and Ulug-Too deposits, South Tianshan (STS), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-322, https://doi.org/10.5194/egusphere-egu22-322, 2022.

EGU22-394 | Presentations | TS7.4

Origin of the metamorphic flysch sequence of the Strandja Massif (NW Turkey) in the Tethyan Realm: insights from new age and structural data 

Ali Akın, Gürsel Sunal, Boris Alexeevich Natal'in, and Namık Aysal

The Strandja Massif is a key location for understanding the Paleozoic and Mesozoic tectonic evolution of the Tethyan Realm in the NW Turkey. Some researchers have suggested that the Strandja Massif is a part of the Cimmerian continent, but others consider it as a section of the southern passive continental margin of the Eurasia. Traditionally the massif is divided into two tectono-stratigraphic units: 1) Pre-Permian crystalline basement and 2) Mesozoic sedimentary cover. However, the ages of the lithostratigraphic units have been significantly revised following the recent geochronological studies. Structural relations between these units are not simple and should be re-examined carefully. Our previous studies have shown that the crystallization time of the magmatic rocks and sedimentation ages of the rocks range from late Proterozoic to Permian especially at the east of the Strandja Massif. In this study, the Serves metagreywacke sporadically containing metabasic rocks and Kumlukoy quartz-rich metasandstones are investigated at the north of the Kıyıköy town, in order to check the first studies that assigned them to the Jurassic and Cretaceous cover deposits. These units stretch along the Black Sea coast and reveal significant differences with units that are exposed to the south. Particularly the Serves unit consists of alternation of lithic metasandstones, schists, and phyllites whereas metaconglomerate layers, marble and dolomite bodies are common among Jurassic rocks exposed in the south. Detrital zircon studies carried on the metasandstone reveal that the sedimentation should be younger than Visean-Serpukhovian, because the youngest U-Pb zircon age population obtained are between ~338 and 327 Ma. Considering widespread late Carboniferous magmatism (~312-306 Ma) in the Strandja Massif and bereft of such magmatics constrain deposition of this unit between ~327 and 312 Ma (early-middle Pennsylvanian). In contrast, the Kumlukoy Unit has quartz-rich metasandstones and it has lower metamorphic degree than the Serves Unit. The detrital zircons of these metasandstones, which were considered as Cretaceous in the previous studies, indicate that the sedimentation interval of the unit is younger than latest Permian (~256 Ma). According to the detrital ages obtained the Kumlukoy metasandstone represent a higher stratigraphical position than the Serves metagreywacke. The Kumlukoy metasandstone is most probably the equivalent of the Triassic metaclastics reported in the cover units of the NW Strandja Massif. Whereas the age and petrography of the Serves metagraywacke are similar to the Mahya Complex and Yavuzdere Arc which was interpreted as a paired magmatic arc-accretionary prism unit. Another interpretation is that the Serves Unit predates the Mahya Complex and Yavuzdere Arc and all of them represents a long-lasting subduction and accompanying accretion events in the late Paleozoic history of the Strandja Massif, namely the Silk-road Arc.

How to cite: Akın, A., Sunal, G., Natal'in, B. A., and Aysal, N.: Origin of the metamorphic flysch sequence of the Strandja Massif (NW Turkey) in the Tethyan Realm: insights from new age and structural data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-394, https://doi.org/10.5194/egusphere-egu22-394, 2022.

EGU22-452 | Presentations | TS7.4

A new set of overprinting slip-data along Manisa Fault in Aegean Extensional Province, Western Anatolia 

Taner Tekin, Taylan Sançar, and Bora Rojay

Interplay between the dynamic effects of the northward subduction of the African plate beneath the Aegean continental fragment and the North Anatolian dextral strike slip fault to the north caused a complex large-scale extensional crustal deformational domain, named Aegean extensional province.

The Gediz-Alaşehir Graben (GAG), being in that large scale extensional terrain, is a NW-SE trending extensional basin developed to the north of K. Menderes Graben (KMG). NW-SE trending Manisa fault is one of the important elements of the GAG, displaying active fault geomorphology.

The slip data were collected from the high angle normal faults, Manisa fault, controlling the Quaternary configuration and faults that are cutting through the Miocene sequences. Angelier’s reverse inversion method (WinTensor) was carried out to differentiate the deformational phases acting on the Manisa fault, based on σ1 - σ3 relation and θ ratio.

The Manisa fault is a high angle normal and dipping towards NE where the final dip-slip motion overprinted onto strike-slip motion. The analysis of the fault slip data simply implies an almost NNW-SSE and NE-SW, two extensional periods acted in the region possibly following Early Miocene contractional period since post-Oligocene. The Plio-Quaternary NNW-SSE extension overprinted onto almost ENE-WSW compression (dextral strike-slip data) which is finally overprinted by the NE-SW to NW-SE multi-directional extension in Aegean region.

To sum up; final phase of the intermittent extensional deformation, NE-SW to NW-SE multi-directional extension, superimposed on the older contractional systems, evolved under the control of North Anatolian strike-slip shear in north and southern Aegean subduction in the south with a cumulative regionwide 30° counterclockwise rotation of western Anatolia since latest Miocene or the contractional data might be possibly inherited from a strike slip structure at depth (“İzmir-Balıkesir transfer zone or Tear”) or else might be evolved along the edges of block boundaries of rotated fault domains.

Key words: Aegean extensional province, Manisa fault, normal faulting, strike-slip faulting.

How to cite: Tekin, T., Sançar, T., and Rojay, B.: A new set of overprinting slip-data along Manisa Fault in Aegean Extensional Province, Western Anatolia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-452, https://doi.org/10.5194/egusphere-egu22-452, 2022.

EGU22-568 | Presentations | TS7.4

Arabia-Eurasia Collision and The Geodynamic Models for Plateau Uplift in Turkish-Iranian Plateau 

Uğurcan Çetiner, Jeroen van Hunen, Oğuz Göğüş, Mark Allen, and Andrew Valentine

Orogenic plateaux, the broad high elevation regions of Earth, are mainly formed by plate convergence/shortening and in some cases, there is (hot) mantle support for their formation. Two major examples at present are the Tibetan and Turkish-Iranian plateaux. For instance, Turkish-Iranian plateau, is a consequence of the continental plate collision between Arabia and Eurasia, which began at ~34-25 Ma and continues to the present day. The plateau can be regarded as two distinct entities, with a boundary at roughly the political border between Turkey and Iran. While there have been studies to explain the uplift history, lithospheric/crustal structure and associated magmatism, currently, the mechanisms behind the plateau growth are not well understood. The western region, also known as the East Anatolian Plateau, has a tectonic plate structure with a near-normal crustal thickness (~35-40 km) and a markedly thinned mantle lithosphere (a few 10s of km in thickness). This suggests that, to achieve its regional elevation of ~2 km there is likely considerable support from the underlying hot asthenospheric mantle. In the east, the crust of most of Iran is thicker, up to ~65 km, and it is underlain by a variable but thicker mantle lithosphere (commonly >100 km thick). It is intriguing why these two regions have similar surface elevations (2-3 km on average) and regional geomorphology, despite predicted lithospheric structures. This study will apply new class of geodynamic models to understand how such plateaux form in response to plate collision/convergence and possible mantle upwelling/support. By comparing models with different setups (varying lithospheric thicknesses, strength profiles etc.) suggested by the natural case studies, this study will provide a more general assessment of controls on plateau growth with 2-D and 3-D perspectives in the context of Arabia-Eurasia collision. Further, the study will also help to explain the role of the forces that generate dynamic topography in the evolution of such geologic structures.

How to cite: Çetiner, U., van Hunen, J., Göğüş, O., Allen, M., and Valentine, A.: Arabia-Eurasia Collision and The Geodynamic Models for Plateau Uplift in Turkish-Iranian Plateau, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-568, https://doi.org/10.5194/egusphere-egu22-568, 2022.

EGU22-765 | Presentations | TS7.4

Fracture networks in a Late Jurassic Arab-D reservoir outcrop analogue, Upper Jubaila Formation, Saudi Arabia. 

Yuri Panara, Pankaj Khanna, Viswasanthi Chandra, Thomas Finkbeiner, and Volker Vahrenkamp

Fracture networks are responsible for channeling flow in subsurface reservoirs (hydrocarbon or geothermal) and markedly impact well productivity and ultimate recovery. Yet, methods to provide fracture (network) distribution at sufficiently high resolution are still lacking – mainly because subsurface data do not adequately capture natural fractures at the mesoscale (cm to m in size) beyond the well bore. In this study we utilize an outcrop analogue to bridge this scale gap.  Over the last decades 3D digital photogrammetry drastically improved in terms of measurement amount and quality enabling the collection of large data sets over wide outcrops. Such data provide critical insights on depositional and structural heterogeneities that may then be utilized for reservoir analogue simulations. Subject of this study is an outcrop in Wadi Laban located in SW Riyadh, Saudi Arabia, along the Mecca-Riyadh highway. We constructed a reliable 3D Digital Outcrop Model (DOMs) at high resolution of the Late Jurassic (Kimmeridgian) Upper Jubaila Formation following a ~800m long escarpment without any occlusion or bias. In particular we reconstruct a colorized dense point cloud using the high-quality setting of Agisoft Metashape© software. We investigated DOMs with CloudCompare© software (CloudCompare, 2021) to map the visible fractures 3D exposure and infer general fractures pattern. Four fracture sets are evident in the data: the predominant sets 1 and 2 are roughly E-W oriented, while sets 3 and 4 are roughly NNE-SSW oriented. Most fractures are strata bound and sub-vertical in nature. Fracture intensity (P21) analysis along the entire outcrop enables us to describe and quantify lateral and vertical variability. Laterally natural fractures are concentrated in corridors with a spacing of few tens of meters. Vertically, fracture intensity is heterogeneous. Furthermore, we found a strong correspondence between fracture intensity on the outcrop and a porosity log acquired on core samples from a well drilled only a few meters behind the outcrop. The outcome of this study provides a step forward for the comparison of outcrop and subsurface fractures, and expand the application of outcrop data to generate high resolution and fidelity reservoir analogue models.

How to cite: Panara, Y., Khanna, P., Chandra, V., Finkbeiner, T., and Vahrenkamp, V.: Fracture networks in a Late Jurassic Arab-D reservoir outcrop analogue, Upper Jubaila Formation, Saudi Arabia., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-765, https://doi.org/10.5194/egusphere-egu22-765, 2022.

EGU22-1162 | Presentations | TS7.4

Subsidence and Sedimentation Rates of the Beni Suef Basin, Egypt: Insights From the Burial and Thermal History Modeling 

Ahmed Yousef Tawfik, Robert Ondrak, Gerd Winterleitner, and Maria Mutti

The Beni Suef Basin, a rift basin in north-central Egypt, was formed in response to the NeoTethys and Atlantic oceans opening and the associated tectonic motion between Africa and Eurasia during the Early Cretaceous. It is bisected by the Nile Valley into the East and West of the Nile Provinces (EON and WON) and comprises a mixed siliciclastic-carbonate succession ranging from the Albian to the Oligocene.

Burial and thermal history modeling was performed to investigate the subsidence and sedimentation rates in the context of the tectonic evolution of the basin. Tareef-1x well from the EON and Fayoum-1x well from the WON were selected for this study, where the input data and the boundary conditions were incorporated based on the available well reports and literature.

The results show that during the Albian syn-rift phase, sedimentation was initiated slightly later with low burial rates of about 33 m/My in the EON compared with high sedimentation rates of about 210 m/My in the WON. The post-rift phase was characterized by rapid thermal subsidence accompanied by relatively moderate sedimentation rates of around 117 m/My in the EON and 97 m/My in the WON. By the Late Cretaceous, an erosional uplift occurred and culminated through the entire Paleocene resulting in the removal of some parts of the Late Cretaceous Khoman Formation from both sides of the basin. Subsidence had resumed during the Eocene due to extensional tectonics with elevated average sedimentation rates of approximately 145 m/My in the EON compared with relatively low sedimentation rates of approximately 74 m/My in the WON. These phases are interrupted by a hiatus period during the Late Eocene-Oligocene in the EON, while the WON has continued subsiding and resulted in the deposition of the Oligocene Dabaa Formation. The Miocene thermal uplift represents the last tectonic phase, which led to significant erosion from the Eocene Apollonia Formation in the EON and the Oligocene Dabaa Formation in the WON.

The implications on the hydrocarbons potentiality were also investigated through the thermal history modeling, where we found that the Turonian Abu Roash “F” source rock exists in the early oil window with a transformation ratio of about 20 % across the entire basin. While the Lower Kharita shale source rock, which is only deposited in the WON, has reached the late oil window with a transformation ratio of approximately 70 %.

In summary, sedimentation began slightly later in the EON (Middle to Late Albian) compared with the WON (Early Albian), where the paleo basement high has hindered the deposition of the Early Albian Lower Kharita shale in the EON compared with the WON, thus caused a delay at the beginning of the deposition. The different sedimentation rates across the basin could be attributed to various factors such as the amount of sediment supply, climate conditions, different slopes across the basin, and /or lithology, which need to be addressed in further research.

How to cite: Tawfik, A. Y., Ondrak, R., Winterleitner, G., and Mutti, M.: Subsidence and Sedimentation Rates of the Beni Suef Basin, Egypt: Insights From the Burial and Thermal History Modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1162, https://doi.org/10.5194/egusphere-egu22-1162, 2022.

EGU22-1319 | Presentations | TS7.4

Assessing the geometry of the Main Himalayan thrust in central Nepal: Insights from thermokinematic modelling 

Suryodoy Ghoshal, Nadine McQuarrie, Delores M. Robinson, Katherine Huntington, and Todd A. Ehlers

The 2015 Gorkha earthquake reignited an existing debate about whether geometric barriers on faults play a role in containing the propagation of ruptures. Models suggest that the extent of the Gorkha earthquake rupture, and of other historical earthquakes were controlled by the locations of ramps in the Main Himalayan thrust (MHT), notably on the western edge of the rupture. The existence of such a pronounced lateral boundary to the west of the Gorkha epicenter is supported by an offset in the surface trace of the Main Central thrust (MCT), closely followed by an offset in the distribution of young (<5 Ma) muscovite 40Ar/39Ar (MAr) ages. However, the zircon (U-Th)/He (ZHe) and apatite fission track ages show more linear east-west distributions over the same region, as does Physiographic Transition 2 (PT2). We explore the formation of these relationships by combining forward-modeled balanced cross-sections through the Marsyangdi, Daraundi, and Budhi Gandaki valleys in central Nepal, and investigate the continuity of active structures across the western portion of the Gorkha rupture. The sequential kinematics of each of these sections are combined with a thermokinematic model (PECUBE) to evaluate the exhumation and cooling histories of the rocks exposed at the surface. We gauge the validity of these models by comparing their predicted cooling ages to measured ages, discarding those that do not match the measured distribution of cooling ages.

Our 3D models show that the offset in the surface geology along the Daraundi is due to a shorter (by 1/3) Trishuli thrust sheet, that has been completely translated to the south of the modern ramp and folded by the Lesser Himalayan duplex. Similarly, the southern extent of the reset MAr ages is also controlled by these relationships requiring observed surface offsets to be the result of changes in the hanging wall rocks translated over the ramp, rather than changes in the geometry of the modern ramp. Notably, the continuity and location of the modern MHT ramp is evidenced by the linear distribution of the youngest ZHe and AFT ages, which are most sensitive to the location of the active ramp. Additionally, the out-of-sequence thrust responsible for PT2 soles directly into the modern ramp during its proposed period of activity at ~1.2 Ma, resulting in the highly linear trace of PT2, running parallel to the location of the ramp. These linear relationships and their reproducibility in thermo-kinematic models argue strongly against any geometric offsets in the modern MHT ramp that have been proposed to limit rupture propagation in central Nepal.

How to cite: Ghoshal, S., McQuarrie, N., Robinson, D. M., Huntington, K., and Ehlers, T. A.: Assessing the geometry of the Main Himalayan thrust in central Nepal: Insights from thermokinematic modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1319, https://doi.org/10.5194/egusphere-egu22-1319, 2022.

EGU22-1665 | Presentations | TS7.4

Coeval volcanism and rotation of Neotethyan oceanic crust in the Oman ophiolite – fact or fiction? 

Antony Morris, Anita Di Chiara, Mark Anderson, Chris MacLeod, Louise Koornneef, James Hepworth, and Michelle Harris

The upper crustal volcanic section of the Oman suprasubduction zone ophiolite is divided into an older V1 sequence, overlain by slightly younger V2 lavas and (in places) a final V3 sequence. Paleomagnetic data from the V1 and V2 sequences of the northern massifs of the ophiolite have been used previously to infer that clockwise rotation of the Oman lithosphere began while the upper crust was actively accreting, with V1 lavas apparently more rotated than the overlying V2 units. This inference has been largely accepted by the geological community and has influenced models for the spreading history and geodynamic evolution of the Oman ophiolite.

Here we present new paleomagnetic data from well-exposed and structurally well-constrained volcanic sequences in the Salahi and Fizh massifs of the ophiolite that discredit this interpretation. In contrast to previous studies that employed standard structural tilt corrections, we use a net tectonic rotation approach to determine rotation parameters, taking confidence limits on input variables into account using Monte Carlo modelling. Importantly, we correct the magnetization direction and structural orientation of the older V1 lavas for the effects of the net tectonic rotation of the younger V2 lavas prior to calculating rotation parameters for the older units. Results demonstrate that both massifs rotated ~120° clockwise around steeply-plunging rotation axes after eruption of the V2 lavas. This rotation occurred during roll-back of the Neotethyan subduction zone in response to impingement of the Arabian margin with the trench. Early rotation of the Salahi V1 lavas around shallowly-plunging, broadly ridge-parallel axes indicates only simple tilting between eruption of the V1 and V2 sequences, and no early rotation of the Fizh V1 lavas is required at all. These new constraints on the evolution of the ophiolite therefore provide no evidence of vertical axis rotation during accretion of the Oman volcanic sequences.

How to cite: Morris, A., Di Chiara, A., Anderson, M., MacLeod, C., Koornneef, L., Hepworth, J., and Harris, M.: Coeval volcanism and rotation of Neotethyan oceanic crust in the Oman ophiolite – fact or fiction?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1665, https://doi.org/10.5194/egusphere-egu22-1665, 2022.

The northern extent of the supercontinent Gondwana in the late Neoproterozoic-Cambrian is not well defined. In most localities the continental margin is covered by thick sedimentary successions, formed following the successive rifting of Tethyan Oceans that episodically detached continental terranes from the edge of the supercontinent. East of the Mediterranean, despite the continental continuity between the Arabian-Nubian-Shield (ANS) and the Tauride block (a Cadomian terrane), the original transition between the two crustal domains is inaccessible and remains obscured. In Israel, investigations of Late Ediacaran, late-stage igneous intrusions of the ANS in the South, together with granulite xenoliths from the lower crust in the North, allow us to probe into the North-Gondwana edge in the late Neoproterozoic and envisage its transition towards the peri-Gondwana Cadomian realm, as well as the evolution of the North Gondwana crust subsequently to the Neoproterozoic. Geochronology and isotopic geochemistry of alkaline intrusions in the Amram massif (southern Israel) as well as doleritic intrusions in the late Neoproterozoic Zenifim Formation (subsurface of south-central Israel) has revealed an igneous and thermal imprint at ca. 550 Ma recorded by the reset of apatite U-Pb ages, together with additional apatite U-Pb dates taken to represent crystallization. Nd and Hf isotopes in apatite, zircon and whole rock also show the ca. 550 Ma intrusions are isotopically distinct from the ANS and resemble Cadomian magmatism in the Taurides. Granulite xenoliths from the lower crust under the lower Galilee (North Israel) contain abundant zircons of distinct U-Pb-Hf properties. These include detrital grains remnant of Neoproterozoic sediment that was subducted and relaminated to the lower crust, late Carboniferous zircons (peaking at 300 Ma) with contrasting εHf(t) signatures, some of which represent syn-Variscan magmatism, and zircons with the age of the host Pliocene basalt. We demonstrate that the Cadomian (ca. 550 Ma) igneous and thermal imprint on the North ANS may have been driven by proto-Tethys subduction that brought about sediment relamination to the North Gondwana lower crust in the latest Neoproterozoic. The late Carboniferous ages recorded in the xenoliths involve both the reworking of depleted ANS basement as well as the relaminated sediment in the means of metamorphism and minor magmatism. Carboniferous thermal disturbance was associated with the formation of continental scale basin and swell architecture across present-day N Africa, Arabia and Iran, and the development of ‘Hercynian unconformities’ in these areas, that were located at the time south of the passive(?) margin of Paleo-Tethys.

How to cite: Abbo, A., Avigad, D., Gerdes, A., and Morag, N.: The Cadomian and Variscan record of the Gondwana margin in Israel: Protracted Crustal Evolution between the Arabian-Nubian Shield and multiple Tethyan Oceans, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1777, https://doi.org/10.5194/egusphere-egu22-1777, 2022.

The Tethys-derived Semail Ophiolite had formed during the Cenomanien-Turonian. Along with deep-sea sediments, it was obducted onto the Arabian Plate as it was still young, hot and buoyant. Thrusting and loading triggered the formation of the Aruma Foreland system consisting of a foredeep, a forebulge and a backbulge basin.

The studied succession represents the uppermost part of the Permo-Mesozoic shallow marine shelf sequence of the Arabian Platform, which is blanketed at an angular unconformity by shales of the Late Cretaceous Muti Formation of the Aruma (foreland) Group. The structural position of the succession is on the forebulge which is characterized by eroded Cretaceous and Jurassic shelf formations of the Arabian Platform (Wasia-Aruma Break).    

We identified two forebulge successions. Both display repetitive lithofacies, beginning with (1) shallow subtidal massive/poorly bedded bioclastic wackestones to floatstones, followed by (2) peloidal grainstones, (3) ferruginous crusts and (4) shallow marine ferruginous oolites. From base to top, both successions record an overall shallowing-up trend. At the same time, the relative sedimentation rate decreases in the same direction. The coarse-grained massive facies may have been deposited on a regular slope which was well-supplied with bioclasts. The finer grained grainstone facies and their peloids indicate a lower sedimentation rate, reflecting the transition form a regular slope to a forebulge on which in the next step sediment condensation occurred (crusts) and chemical precipitation of ferruginous material (crusts and oolites). Each forebulge succession is capped by clayey material.

The similar facies development of the two successions suggests repetitively similar depositional and tectonic conditions. As both sequences occur at the same site, two vertical forebulge developments are concluded.

The ferruginous crusts formed under at least slightly reducing conditions, associated with minor water-deepening events. Both oolites contain chlorite, hematite, quartz, calcite and apatite. The nuclei of the ooids are often chlorite or hematite fragments, having most-likely derived from preexisting ferruginous crusts. Iron oxyhydroxides and clinochlore of the oolites reflect bathymetric changes to more oxidizing aqueous conditions, associated minor water-shallowing events.

Fe-rich anoxic to sub-oxic sea water of the marine foredeep was the Fe source for the crusts and oolites, coinciding with (1) a high rate of global Cretaceous oceanic crust production, (2) related hydrothermalism and (3) the regional proximity of an active spreading axis. Fe was likely stabilized in ocean water as Fe colloids and organic Fe complexes.

How to cite: Mattern, F., Pracejus, B., Scharf, A., Frijia, G., and Al-Salmani, M.: Two Cretaceous forebulge successions in the Oman Mountains, triggered by the obducted Semail Ophiolite, identified by the facies analysis of limestones, ferruginous crusts and ferruginous oolites, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2123, https://doi.org/10.5194/egusphere-egu22-2123, 2022.

EGU22-2493 | Presentations | TS7.4

Seismic structure of a Tethyan back-arc: transdimensional ambient noise tomography of the Black Sea lithosphere 

Laura Petrescu, Felix Borleanu, and Anica Placinta

The Black Sea is the largest European back-arc basin connected to the subduction and final closure of the Tethys ocean. Its origin and type of crust are widely debated, with contrasting views suggesting it is either a relic of Paleotethys or a rifted back-arc basin formed within the thick and cold Precambrian lithosphere. To investigate the structure of this atypical intra-continental basin, we constructed the highest resolution seismic tomography of the region using the latest techniques of probabilistic inversion of ambient noise data recorded at seismic stations around the sea. Our results indicate the presence of thinned continental crust beneath the basin, likely of Precambrian lithospheric origin, thus invalidating the existence of either a relic Paleotethys fragment or younger oceanic crust. Extension and rifting probably exploited pre-existing sutures, but the rheologically strong lithosphere resisted transition to seafloor spreading. Seismic anisotropy shows complex paleo-deformational imprints within the crust and upper mantle related to the closure of Tethys. Extension caused by subduction roll-back generated anisotropic lithospheric fabric parallel to the rifting axis within the thinnest sections of the crust in the western basin. The eastern part developed on a distinct lithospheric domain that preserves paleo-extension anisotropy signatures in the form of lower crustal viscous deformation. Further south, anisotropy orients along the Balkanide-Pontide collisional system that records the final stages of Neotethys closure. Our results place key constraints on the type of deformations that occurred throughout the Tethyan realm, with fundamental implications for the development and evolution of back-arc basins and continental break-up. 

How to cite: Petrescu, L., Borleanu, F., and Placinta, A.: Seismic structure of a Tethyan back-arc: transdimensional ambient noise tomography of the Black Sea lithosphere, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2493, https://doi.org/10.5194/egusphere-egu22-2493, 2022.

EGU22-3985 | Presentations | TS7.4

Thermal overprinting of Mesozoic shelfal limestones on Jabal Akhdar, Oman 

Bernhard Pracejus, Andreas Scharf, and Frank Mattern

The Jabal Akhdar Dome of the Hajar Mountains (northern Oman) has long been considered to have had no significant thermal overprinting since the start of its doming (Eocene, ~40 to 30 Ma). Only the Semail Ophiolite, obducted during the Late Cretaceous, metamorphosed the overridden sedimentary rocks at its base. However, this is stratigraphically well above the positions of the rocks discussed here. Our findings describe the first evidence for an increased metamorphic alteration of Late Permian, Jurassic and Lower Cretaceous shelfal limestones. Two independent sites were identified, where calcite was either replaced by wollastonite or sulfides. 

 

The calc-silicates, which occur southeast of the Saiq Plateau (stratigraphically above the plateau), contain up to centimeter-sized wollastonite crystals. The conversion into marble has been interrupted, as indicated by relict fossils and ooliths of Jurassic and Lower Cretaceous limestones. So far, the outcrop has been mapped over a length of ~1.2 km. It is dissected by several NW-striking dextral faults in a difficult terrain and, thus, the occurrence may be significantly wider. Wollastonite concentrates in sub-horizontal to gently SE-dipping limestone layers, neighbouring strata may be almost void of it. In places, strong and coarse-grained dolomitisation coincides with decreased wollastonite content. The area is cross-cut by irregular quartz-wollastonite-rich veins.

 

Adjacent to the outcrops are younger quartz-siderite veins, which have almost completely replaced limestone layers (encased wollastonite-carrying limestone relicts). Distal to the mineralisations, the limestones contain decimeter-sized chert nodules. This entire silica-dominated system must have reached 450 ºC in order to form the well crystallised wollastonite. The mostly oxidising character of the environment during overprinting is reflected by fine euhedral hematite grains throughout the examined profile. However, slightly reducing settings promoted the formation of very rare and tiny crystals of erdite (NaFeS2·2H2O) in two places.

 

Sulfides in finely laminated Permian carbonates, which contain fine as well as very coarse-grained black carbonates, occur on the northwestern side of the Saiq Plateau in no longer accessible excavation materials. So far, the search for another outcrop failed, due to the sub-vertical wadi walls near-by. The strongly dominating pyrite is accompanied by trace amounts of sphalerite and less galena. Collectively, sulfides replaced carbonate laminae with fine crystalline impregnations and concentrated in up to decimeter-large lensoid concretionary shapes. Dark carbonaceous laminae and recrystallised coarse-grained materials contain finest graphite flakes. This again indicates temperatures of ~450 ºC, at which the graphite formation started during decarbonisation, also promoting a reducing regime (the sulfides show no signs of oxidation).

 

Our working hypothesis is that the thermal overprint (>450 ºC) coincided with the late Eocene to Oligocene doming event, leading to multiple mafic intrusions. Similar intrusions are known from the Muscat and Batain area and have the same age.

How to cite: Pracejus, B., Scharf, A., and Mattern, F.: Thermal overprinting of Mesozoic shelfal limestones on Jabal Akhdar, Oman, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3985, https://doi.org/10.5194/egusphere-egu22-3985, 2022.

EGU22-4246 | Presentations | TS7.4

Implications for the pre-Alpine evolution of the Eastern Alps – a U/Pb zircon study on the Austroalpine Schladming Nappe 

Isabella Haas, Walter Kurz, Daniela Gallhofer, and Christoph Hauzenberger

The Schladming Nappe, as a part of the Silvretta-Seckau Nappe System of the Eastern Alps, comprises pre-Alpine remnants of crystalline basement rocks which give important information for reconstructing the Variscan and even pre-Variscan history of the Alps.

The Schladming Nappe mainly consists of paragneisses being intruded by subsequently overprinted granitoids. U-Pb zircon ages were acquired through LA-MC-ICPMS to determine the magmatic emplacement of the metagranitoids and constrain the tectono-metamorphic history of the Schladming Nappe.

Within these meta-granitoids, several intrusive events can be distinguished: (1) a Cambrian event with 206Pb/238U zircon mean ages between 496±6.5 and 501±7 Ma, (2) a Late Devonian/Early Carboniferous event with zircon mean ages between 350±5 Ma and 371±5 Ma and (3) a Permian event with zircon mean ages between 261±3 Ma and 263±3.5 Ma. The youngest age group is only found in metagranitoids from the southeastern part of the Schladming Nappe. The tectonic contact to the metapelites of the Wölz Nappe system and therefore the affiliation of these Permian granitoids to the Schladming Nappe, however, is still enigmatic.

The various age groups can also be differentiated by their whole rock geochemistry. While all of the metagranitoids are peraluminous, the Cambrian age group exhibits higher SiO2 values compared to the Late Devonian age group. The Late Devonian age group shows higher contents of CaO, MgO, FeO, Al2O3, as well Sr and Ba and can be further divided into two subgroups, with one depicting a distinct negative Eu-anomaly (EuN/Eu*=0.44-0.69) and the other subgroup lacking one (EuN/Eu*=0.82-1.08). The Permian age group often displays high contents of K2O, Nb and Y.

The Late Cambrian to Early Ordovician metagranitoids can be classified as part of a magmatic arc system, probably belonging to the northern Gondwana margin. The early Variscan granitoids can also be interpreted as part of an active margin. The Permian granitoids show a within plate granite affiliation and can further be interpreted as A-type granitoids, probably related to post-Variscan lithospheric extension.

How to cite: Haas, I., Kurz, W., Gallhofer, D., and Hauzenberger, C.: Implications for the pre-Alpine evolution of the Eastern Alps – a U/Pb zircon study on the Austroalpine Schladming Nappe, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4246, https://doi.org/10.5194/egusphere-egu22-4246, 2022.

Situated between Africa and Eurasia in the eastern Mediterranean, the island of Cyprus has developed on the northern margin of the southern Neotethys by the accretion of three terrains, the Mamonia complex, the Troodos ophiolite, and the Kyrenia terrane. The Kyrenia terrane comprises a tectonic stack of Triassic to Eocene rock units interleaved with basic and acid volcanics and minor metamorphic inliers, alongside an Oligocene-Miocene flysch. Our U-Pb-Hf detrital zircon investigation in the Kyrenia Triassic to Eocene section reveals a large amount of Neoproterozoic zircons (950-600 Ma), alongside Silurian (∼430 Ma), Carboniferous (∼300 Ma), Triassic (∼240 Ma), and Upper Cretaceous (∼85 Ma) zircons. The Precambrian age profile of all three studied units resembles that of Paleozoic sandstones of the Tauride Block, as well as that of Paleozoic and Mesozoic sandstones found across North Africa. It is interpreted as reflecting the reworking of Paleozoic sandstone units from the Taurides or other peri-Gondwanan source. The presence of a substantial proportion of ~300 Ma zircons, as early as in Triassic sediments of the Kyrenia, is of significant interest because Carboniferous magmatism is confined to the Paleotethyan realm which is traced north of the Taurides. Deposition of the Kyrenia sequence closer to a Northern Tethyan province would better fit its detrital zircon signal. The detrital signal of the Kyrenia, indicative for Eurasian terranes north of the Mediterranean, also differs significantly from that of the Mamonia Complex (SW Cyprus) in which only Afro-Arabian sources are distinguished. Thus, in view of its unusual detrital zircon content, the Kyrenia sequence stands out in the Eastern Mediterranean as an exotic rock pile that cannot be straightforwardly correlated with its neighboring geologic environment.

How to cite: Glazer, A., Avigad, D., Morag, N., Güngör, T., and Gerdes, A.: Detrital zircon evidence for exotic elements in the southern Neotethys: A provenance study of Triassic-Eocene rock units in the Kyrenia terrane, Northern Cyprus, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5391, https://doi.org/10.5194/egusphere-egu22-5391, 2022.

EGU22-6471 | Presentations | TS7.4

Formation and contractional reactivation of the NW Sulu Sea (SE Asia) 

Patricia Cadenas and César R. Ranero

Located in SE Asia in between the Palawan and the Philippine islands, the lozenge-shaped Sulu Sea corresponds to a marginal sea that displays a complex seafloor morphology. The NE-SW trending Cagayan Ridge separates a southeastern deep-water domain, which is bounded by the Sulu Trench towards the east, from a shallower and narrower northwestern domain. Interpretations of low-resolution 2D streamer datasets, ODP Leg 124 drilling results, magnetic, geochemical, and geochronological studies, and gravity inversion results led to distinctive tectonic models, with contrasting basin formation mechanisms, and ages of opening and subsequent contractional reactivation. The debates remain because the structure of most of the Sulu Sea and its along-strike structural variability remain underexplored to date.

We focus on this work on the first detailed analysis of the structure and seismo-stratigraphy of the NW Sulu Sea. Based on the reprocessing, calibration of the Silangan-1 exploration borehole, and interpretation of > 5384 km of 2D seismic data along 19 regional profiles of an irregular grid that covers the whole NW Sulu Sea, we identify, map and interpret the seismo-stratigraphic horizons and units, major structures, and rift-related and syn-orogenic depocenters and structural domains. We define six seismo-stratigraphic units in the NW Sulu Sea, consisting of Quaternary to Paleogene sediments, which developed during an early phase of Paleogene to early Miocene extension, a following early to Middle Miocene phase of contraction, and a late Miocene to Quaternary stage of relative tectonic quiescence. While transpressional faults core uplifted basement areas, strike-slip, high-angle and low-angle oblique extensional faults crosscut continental crystalline basement of variable thickness and bound pull-apart basins, half-grabens and sags respectively. The distribution and trend of rift-related depocenters describe a strong structural segmentation and vary along NW-SE and NE-SW oriented zones. Thrust-cored anticlines, inverted transtensional and transpressional faults and mud diapirs deform the sediment pile and control the geometry of syn-orogenic depocenters distinctively across the NW Sulu Sea.

Normal and oblique trending sets of faults controlled the extension and compartmentalized the NW Sulu Sea. Subsequent contractional reactivation differentiated NE and SW basement and sedimentary domains, separated by the NW Sulu Break Elevation. These domains show a contrasting overall architecture, basement thickness, contractional structures and distribution of rift-related and syn-orogenic depocenters. Rift segmentation, and particularly, basement thickness variations, may have conditioned the type and distribution of contractional deformation.

How to cite: Cadenas, P. and R. Ranero, C.: Formation and contractional reactivation of the NW Sulu Sea (SE Asia), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6471, https://doi.org/10.5194/egusphere-egu22-6471, 2022.

EGU22-7096 | Presentations | TS7.4

Geodynamics of long-term continental subduction and Indian indentation at the India-Eurasia collision zone 

Kai Xue, Wouter P. Schellart, and Vincent Strak

India-Eurasia convergence velocities have dropped significantly from ~18 cm/yr in the Late Cretaceous-earliest Eocene to ~4-5 cm/yr since ~50 Ma. The mechanisms of convergence deceleration, continued convergence since ~50 Ma, long-term continental subduction and long-term Indian indentation into Eurasia still remain controversial. Many previous studies consider an external driving force for the long-term convergence, continental subduction and Indian indentation, and the initial India-Eurasia collision as the trigger for the deceleration. In this study, we investigate the mechanism(s) of the abrupt deceleration, the continued convergence, the long-term continental subduction and long-term Indian indentation using buoyancy-driven analog experiments. We conduct three large-scale experiments to simulate the subduction and collision process at the convergent boundary with different boundary conditions at the 660-km discontinuity, including an infinite viscosity step (the lower-upper-mantle viscosity ratio (ηLMUM) is infinitely high), no viscosity step (ηMUM =1) and an intermediate viscosity step. The experiment with infinite ηLMUM shows a deceleration when the slab tip reaches the 660-km discontinuity, while the other two experiments show a deceleration at the onset of continental subduction. Our experiments show that a higher ηLMUM favors a lower velocity drop at the onset of continental subduction, lower convergence velocities, reduced continental subduction and a higher indentation amount, and vice versa. Furthermore, our models suggest that in nature, with an intermediate-high ηLMUM, the negative buoyancy force of both upper and lower mantle slab segments is the main driver of long-term convergence, continental subduction and Indian indentation.

How to cite: Xue, K., Schellart, W. P., and Strak, V.: Geodynamics of long-term continental subduction and Indian indentation at the India-Eurasia collision zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7096, https://doi.org/10.5194/egusphere-egu22-7096, 2022.

EGU22-7993 | Presentations | TS7.4

Petrology and Geochemistry of intrusive igneous rock from the Inthanon zone, Northwestern Thailand 

Srett Santitharangkun, Christoph Hauzenberger, Daniela Gallhofer, and Etienne Skrzypek

Large plutons are common within the Inthanon Zone in Northwestern Thailand. These igneous rocks are also known as Central Granitoids Belt in mainland Southeast Asia. They are interpreted to be part of the suture zone between Sibumasu and Indochina and were emplaced mainly in the Upper Triassic.

Here, we present new petrological and geochemical data for the Central Granitoids Belt.  A geochronological study on selected samples will follow.  The sampled granitoids can be separated into three groups: (1) biotite granite, (2) hornblende granite, (3) syenite/monzonite. The samples consist of various light colored to dark grey granitoids due to the type and amount of mafic minerals (biotite or hornblende) present. The general mineral assemblage of all the intrusive igneous rocks is quartz + plagioclase + K-feldspar + biotite + apatite + zircon ± allanite ± titanite ± ilmenite. The biotite granites are mostly composed of biotite aggregates associated with accessory minerals: zircon, ilmenite, and apatite. The syenite/monzonite group usually contains additional clinopyroxene and hornblende. Plagioclase and hornblende of the syenite/monzonite group commonly exhibit a sieve texture.

The biotite granite group is typically peraluminous and belongs to the high-K calk-alkaline to shoshonitic series. The hornblende granite group is mostly peraluminous and of predominantly shoshonitic affinity. The syenite/monzonites are typically metaluminous but also belong to the shoshonitic series. The chondrite normalized rare earth element (REE) patterns are quite similar for all igneous rocks with elevated LREE, pronounced negative Eu anomaly and a flat HREE segment. The granite tectonic discrimination plots after Pearce et al. (1984) classify most samples as syn-collision granites (syn-COLG) and when using the Batchelor and Bowden (1985) discrimination diagram as syn-, late, and post-collisional.

The intrusive igneous rocks from Northwestern Thailand were presumably emplaced in a syn- to post-collisional setting when the Sibumasu block collided with the Sukhothai terrane and was eventually amalgamated to the Indochina block. This led to the closure of the Palaeotethys along the eastern area of the Sibumasu block.

Batchelor, R.A. and Bowden, P. (1985) Petrogenetic Interpretation of Granitoid Rock Series Using Multicationic Parameters. Chemical Geology, 48, 43-55.

Julian A Pearce, Nigel BW Harris, Andrew G Tindle (1984). Trace element discrimination diagrams for the tectonic interpretation of granitic rocks. Journal of Petrology, 25, 956-983.

 

How to cite: Santitharangkun, S., Hauzenberger, C., Gallhofer, D., and Skrzypek, E.: Petrology and Geochemistry of intrusive igneous rock from the Inthanon zone, Northwestern Thailand, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7993, https://doi.org/10.5194/egusphere-egu22-7993, 2022.

EGU22-9219 | Presentations | TS7.4 | Highlight

Mapping the extent of seismoturbidites near the southern Dead Sea Fault in the Gulf of Aqaba 

Matthieu Ribot, Sigurjón Jónsson, Yann Klinger, Ulaş Avsar, and Zeynep Bektaş

Despite multiple research efforts since the late 1950’s, many questions regarding the earthquake activity of the Dead Sea Fault (DSF) remain, in particular for its southernmost portion in the Gulf of Aqaba. This is due to its offshore location and little-known interactions with the Red Sea rift system. The emergence of the NEOM city-project in northern Saudi Arabia and the planned King Salman road crossing across the Gulf of Aqaba have made it important to find answers for these questions related to the earthquake hazard of the region. The last major earthquake in the Gulf of Aqaba occurred in 1995 along one of the main strike-slip fault segments in the gulf, bringing both extremities of the fault rupture closer to failure. Studies of the DSF have found that large events along the entire DSF cluster during relatively short active seismic periods lasting about 100-200 years, separated by longer quiescent periods of about 350-400 years. From a tectonic point of view, the time gap between 1995 and the previous major earthquake in AD1588 conforms to this scheme and suggests that the DSF might be ripe for a new earthquake sequence, with the 1995 earthquake as the starter. That said, new results from GPS and InSAR observations have pointed to possible fault creep in the southern part of the gulf, which would significantly decrease the seismic hazard in the area. To explore this possible creep and to test the clustering model, we investigate new sub-bottom profiling data acquired in December 2019 in the Gulf of Aqaba. We aim to map the extent of sand layers present in the different sub-basins of the gulf and to correlate them with seismoturbidite layers found in sediment cores collected in 2018. By looking at the geographic extent of these sand layers, we also aim to define the source of the coarse deposits, or at least, to determine whether they are related to the regular sediment influx or linked to turbidites generated by slope failures during large earthquakes. Our preliminary results indicate that the sub-bottom profiling data allow us to map sand layers up to a depth of about 8 meters. Considering a sedimentation rate in the gulf between 0.2 - 0.4 mm/year, we could be able to gain an overview of the sediment infill of the Gulf of Aqaba over the last 20 ky or more. Even if the resolution of the sub-bottom profiling data is lower than that of the sediment cores, and the assumptions made for the correlation of the sand layers, due to the scattered grid, do not help to constrain properly the source of the deposits, we can still propose a longer-term overview of the earthquake activity and discuss the temporal organization of the large events in the area.

How to cite: Ribot, M., Jónsson, S., Klinger, Y., Avsar, U., and Bektaş, Z.: Mapping the extent of seismoturbidites near the southern Dead Sea Fault in the Gulf of Aqaba, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9219, https://doi.org/10.5194/egusphere-egu22-9219, 2022.

EGU22-9365 | Presentations | TS7.4

Asymmetrical lithospheric necking of Red Sea rift 

Thamer Aldaajani, Hany Khalil, Philip Ball, Fabio Capitanio, and Khalid Almalki

The Red Sea rift exhibits two distinct rifting styles: in the north, the rifting is magma-poor, the crust is hyperextended and the lithospheric necking is asymmetric, in the south, rifting rapidly localized atop a symmetric lithospheric necking. One of the long-standing questions is what drives such different lithospheric necking style? We ran 2D high-resolution thermomechanical numerical simulations of lithospheric rifting to address the northern and southern Red Sea extensional end members and validate the models’ deformation patterns by comparing them against 2D data-driven structural models. The modelling investigates (a) the effect of rotational extension by varying extension velocities along the Red Sea, and (b) the thermal structure of the southern Red Sea due to plume impingement, while the analysis of the outcomes focuses on the early rifting stage, which involves normal rifting and dike intrusion. We find that asymmetrical lithospheric necking in the central and northern Red Sea is potentially driven by the velocity boundary conditions and inherited structures, mainly the Sirhan rift. The decoupling between the upper portion of the lithosphere and the asymmetrical lithospheric necking, which plays an essential role in the observed deformation patterns in the Arabian margin, is likely controlled by the lower crustal rheology and thickness. Furthermore, we find that the Afar plume near the southern Red Sea, which introduced in our models in form of thermal anomaly, promotes rifting localization.

How to cite: Aldaajani, T., Khalil, H., Ball, P., Capitanio, F., and Almalki, K.: Asymmetrical lithospheric necking of Red Sea rift, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9365, https://doi.org/10.5194/egusphere-egu22-9365, 2022.

The eastern Mediterranean Sea preserves crust that was trapped during the collision of Africa with Eurasia and the closure of the Neo-Tethyan Ocean. Thick sedimentary blanketing (10 to 15 km) complicates our ability to assess the nature of the crust, and therefore it has remained one of the least understood regions of the collision belt. In this presentation, I review recent marine geophysical observations (surface and deep-tow magnetics, high-resolution bathymetry and seismic reflection data) and discuss their geodynamic implications. The surface total field and vector magnetic anomalies from the Herodotus Basin reveal a sequence of long-wavelength NE-SW lineated anomalies that straddle the entire basin suggesting a deep two-dimensional magnetic source layer. The magnetic vector data indicate an abrupt transition from a 2D to a 3D magnetic structure along the eastern edge of the Herodotus Basin and west of the Eratosthenes Seamount, where a prominent gravity feature is found. These findings indicate that the Herodotus Basin preserves remnants of oceanic crust accreted along a mid-ocean ridge system that spread in an NW-SE direction. The African Plate's continuous northward and counterclockwise motion during the Paleozoic and Mesozoic allow predicting the crustal remanent magnetization directions, which dictate the shape of the present-day magnetic anomalies. The shape of the Herodotus anomalies best fit Carboniferous magnetization directions. The combination of surface and deep-tow magnetic data, as well as thermal and magnetic forward modeling, suggest that spreading was slow (~25 km/myr half spreading rates) and that the upper oceanic crust has been entirely demagnetized, probably due to the heating effect induced by the thick sedimentary coverage.

 

The stretched continental crust of the Levant Basin, found east of the Herodotus Basin, preserves a series of horsts and grabens that generally orient in an orthogonal direction relative to the spreading direction, suggesting that they may have formed concurrently with the initial opening of the Herodotus Basin. Earthquake data and long NW-SE bathymetric scars found within the northern edge of the Nile deep-sea fan suggest that an active fault belt transfers the motion from the Gulf of Suez toward the northern convergence boundaries. This fault belt is directed toward, and merges with, the continental-ocean boundary that straddles the eastern Herodotus Basin. This observation may indicate that the mechanical transition from the rather weak and stretched continental crust of the Levant to the relatively strong oceanic Herodotus crust has guided the location of the western boundary of the Sinai Microplate, formed during the Oligocene by the fragmentation of the African Plate.

How to cite: Granot, R.: Trapped remnant of the Tethyan realm: the influence of ancient tectonics on the present-day geodynamics of the eastern Mediterranean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9408, https://doi.org/10.5194/egusphere-egu22-9408, 2022.

EGU22-11305 | Presentations | TS7.4

The Neotethyan Arabian necking zone exposed at the SE Oman mountains: field evidence and consequences 

Maxime Ducoux, Emmanuel Masini, Andreas Scharf, and Sylvain Calassou

The Late Cretaceous Oman Mountains are generally assumed to result from obduction followed by the inversion of the mid-Permian- to Triassic Neotethyan rifted margin. However, the key rift-related crustal features, such as a necking zone or hyper-extended rift domains remain inferred and poorly described so far. In this study, we investigate the tectono-stratigraphic record of the eastern part of the Oman Mountains where the exposed Tonian (Neoproterozoic) crystalline basement outcrops together with the pre- to syn-obduction sedimentary record in the Ja’alan massif area. The description of these units together with subsurface data enables to describe the former Arabian necking zone. The Ja’alan massif itself and the Arabian platform to the southwest represent the former proximal margin domain. It is characterized by the eroded basement sealed by post-obduction continental to shallow marine sediments. In contrast, the north-eastern side of the massif is flanked by Permian-Mesozoic deep marine post-rift sediments (Batain Group) equivalent to the Hawasina thrust sheet in the Oman Mountains. These two endmember paleogeographic units are separated by a major N20 dipping top-to-the-NE normal fault with dip-slip kinematics (slikensides with striae, S/C-fabric). The damage zone of this fault is characterized by a cataclastic and a gouges fault zone, overlain by slope facies with syn-kinematic polymictic mega-breccias reworking the adjacent basement. The breccias are grading finer upwards, contain conglomerate and sandstone interbeds interpreted as to slope-environment turbiditic channel deposits. This exhumation and rift-related record is unconformably covered by the post-obduction sequence affected by a late Cenozoic E/W-directed low-amplitude shortening. The intensity of shortening is increasing toward the NW leading to reactivate the Arabian Necking zone as a ramp for the Hawasina thrust system. Based on these observations, we propose a new geodynamic model showing that the final stage of the obduction result from the inversion of the former Arabian necking zone with significant impacts on the evaluation of (1) the shortening rates accommodated and (2) the former architecture of the Arabian Tethyan rifted margin. As the belt never recorded a mature continent-continent collision, we think that the Oman study case could significantly help to investigate the dynamics of hyper-extended rifted margins inversion at an early orogenic stage.

How to cite: Ducoux, M., Masini, E., Scharf, A., and Calassou, S.: The Neotethyan Arabian necking zone exposed at the SE Oman mountains: field evidence and consequences, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11305, https://doi.org/10.5194/egusphere-egu22-11305, 2022.

EGU22-11791 | Presentations | TS7.4

Geomorphology of the Mabahiss Deep area, Northern Red Sea: New insights from high-resolution multibeam bathymetric mapping 

Margherita Fittipaldi, Daniele Trippanera, Nico Augustin, Froukje M. van der Zwan, Alexander Petrovic, Dirk Metz, and Sigurjon Jónsson

The Red Sea is a unique place to study a young oceanic rift basin and the interplay between magma and tectonics at a young divergent plate boundary. The spreading rate of the Red Sea rift changes from ~17 mm/yr in the south to ~7 mm/yr in the north, and so does the morphology. The southern Red Sea is a continuous and well-developed oceanic rift, whereas the so-called deeps characterize the central portion with oceanic crust separated by shallower inter-trough zones, and the northern part contains more widely spaced deeps with extensive areas covered by sediments in between. While the central Red Sea morphology has been extensively studied, the structure of the northern Red Sea and its link to the central Red Sea are less clear. Indeed, the northern Red Sea rift, marked at its southern end by Mabahiss Deep, is offset by about 60 km to the central Red Sea axis by the still poorly understood Zabargad Fracture Zone.

Here we aim to improve the understanding of the volcano-tectonic setting of the Mabahiss Deep area with new high-resolution bathymetric data from multiple multibeam surveys with R/V Thuwal and R/V Pelagia. Our results show that the 15 km long, 9 km wide, and 2250 m deep Mabahiss Deep, and the 800 m high and 5 km wide central volcano, are the most prominent structures of the area. The deep is bordered by a series of Red Sea parallel normal faults on both sides, forming a graben-like structure and thus suggesting a rift-like morphology. The central volcano has a 2 km wide summit caldera containing several volcanic cones. Several normal faults cut its southern flank, and radial fractures are present on its summit. In the multibeam backscatter data, several recent lava flows (<10 kyrs) are visible on the northern and southern flanks of the volcano. Even if the ocean floor outside the deep is mainly covered by salt flows, limiting structural analysis of the surrounding areas, the Mabahiss Deep area and the central Red Sea have similar rift-like structures with stable axial MORB-volcanism, showing typical features found at other (ultra-)slow-spreading ridges, such as magma focusing on the segment centers. This suggests that although the Mabahiss Deep appears to be offset from the central Red Sea rift, the same processes are probably taking place in this area.

Our new high-resolution bathymetric mapping allows a more precise structural and geomorphological analysis of the Mabahiss Deep area that represents a starting point for understanding the overall structure of the poorly studied northern Red Sea.

How to cite: Fittipaldi, M., Trippanera, D., Augustin, N., van der Zwan, F. M., Petrovic, A., Metz, D., and Jónsson, S.: Geomorphology of the Mabahiss Deep area, Northern Red Sea: New insights from high-resolution multibeam bathymetric mapping, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11791, https://doi.org/10.5194/egusphere-egu22-11791, 2022.

EGU22-11825 | Presentations | TS7.4

The Norian magmatic rocks of Jabuka, Brusnik and Vis Islands (Croatia) and their bearing on the evolution of Triassic magmatism in the Adria Plate 

Matteo Velicogna, Marko Kudurna Prasek, Luca Ziberna, Angelo De Min, Valentina Brombin, Fred Jourdan, Paul R. Renne, and Andrea Marzoli

The magmatic bodies of Jabuka, Brusnik, and Vis Islands of the Adriatic Sea are located in the easternmost part of the Adria Plate (Adriatic Unit according to Slovenec & Šegvić, 2021), close to the External Dinarides (Pamić and Balen, 2005). The magmatic rocks on the islands are, from West to East, intrusive bodies on Jabuka, sub-intrusive on Brusnik, and effusive rocks on Vis.

Feldspar separates from Jabuka and Brusnik Islands yielded mini-plateau 40Ar/39Ar ages of 229.0 ± 5.4 Ma and 221.5 ± 2.5 Ma indicating that this magmatism is Carnian-Norian in age. The whole-rock geochemical compositions (major and trace elements, Sr-Nd isotopes) indicate that the magmatic rocks of the Croatian Islands range from tholeiitic to calc-alkaline, yielding a subduction signature. This signature is also shared by coeval magmas from the Adria Plate and may be related to crustal components subducted during the Hercynian orogeny and recycled within the mantle source(s) of this anorogenic magmatism.

How to cite: Velicogna, M., Prasek, M. K., Ziberna, L., De Min, A., Brombin, V., Jourdan, F., Renne, P. R., and Marzoli, A.: The Norian magmatic rocks of Jabuka, Brusnik and Vis Islands (Croatia) and their bearing on the evolution of Triassic magmatism in the Adria Plate, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11825, https://doi.org/10.5194/egusphere-egu22-11825, 2022.

Continental collision succeeds long term subduction of oceanic lithosphere into the earth's mantle whereby the negative buoyancy of the downgoing oceanic lithosphere (slab) provides the principal driving force for plate motions. Previous studies have shown that subduction-induced mantle flow could drive overriding plate shortening and orogenesis, and the arrival of the positively buoyant lithosphere at the trench affects the dynamics of the overriding plate and plate motions. The subsequent slab detachment at the subducted continent-ocean margin removes the driving force in the system and eventuates in cessation of subduction (Cloos, 1993)  and plate convergence. The India-Eurasia subduction-collision system has multiple inferred slab break-off episodes (Replumaz et al., 2010), yet convergence is still ongoing. Here, we present 2D-cartesian buoyancy-driven numerical models of continental collision after subduction of a long oceanic plate (~6000 km) in a whole mantle reservoir (2880km), investigating the dynamics of such systems in the presence of detached slabs. These models’ wide aspect ratio (6:1) allows for exploring deep subduction of oceanic slabs and detached slab(s), approximately at the centre of the domain, thereby minimising the effect of free slip sidewalls on obtained slab morphology in the mantle and associated mantle flow. Our results indicate that poloidal mantle flow induced by the sinking of the detached slab sustain long term convergence in collisional settings. Although 2D models lack the 3D components of mantle flow, these models can be used to understand the dynamics of the centre of >4000km wide subductions zones and facilitate interpretation in light of tomographic and plate reconstruction studies.

 

References:

Cloos, M. (1993). Lithospheric buoyancy and collisional orogenesis: Subduction of oceanic plateaus, continental margins, island arcs, spreading ridges, and seamounts. Geological Society of America Bulletin, 105(6), 715-737.

Replumaz, A., Negredo, A. M., Guillot, S., & Villaseñor, A. (2010). Multiple episodes of continental subduction during India/Asia convergence: Insight from seismic tomography and tectonic reconstruction. Tectonophysics, 483(1-2), 125-134.

How to cite: Laik, A., Schellart, W., and Strak, V.: Convergence at continental collision zones: Insights from long-term 2D geodynamic models buoyancy-driven subduction and collision., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12441, https://doi.org/10.5194/egusphere-egu22-12441, 2022.

The Eocene Lower and Middle members of Rus Formation are exposed at the King Fahd University of Petroleum and Minerals (KFUPM) campus and contain 'odd' structural features. Previously, such structures were overlooked or misinterpreted by other researchers. In this study, we interpret these structures as hydroplastic kinematic indicators in the basal part of the Middle Rus Member. Their occurrence is related to the Rus soft-sediment detachment, a major displacement zone at the boundary/interface between the Lower and Middle Rus. The structures are fist-sized vugs coupled with carrot- or comet-trail imprints (VCT structures), previously translated calcite geodes. VCT structures demonstrate NNW (345°) transport/slip and are found on flat to low-dipping surfaces characterized as Y, R, and P shears according to the Rus detachment orientation. The Andersonian transtension stress regime is indicated by palaeostress analysis, but it was not enough to activate the Rus soft-sediment detachment. The negative effective principal stress σ3' and the exceptionally low frictional coefficient generated by fluid pressure resulted in detachment activity. Because it reveals the Arabian platform's instability in the larger area of the Dammam Dome during the Late Eocene, the soft-sediment Rus detachment can be considered a 'sensitive stress sensor' for the Zagros collision. The beginning of the Zagros collision, which was previously thought to occur during the Oligocene based on the well-known pre-Neogene unconformity, is credited with this instability.

How to cite: Osman, M. and Tranos, M.: New hydroplastic structures of the Eocene Rus Soft-sediment Detachment (Eastern Saudi Arabia) and their contribution to the dating of the Zagros Collision, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13058, https://doi.org/10.5194/egusphere-egu22-13058, 2022.

EGU22-13597 | Presentations | TS7.4

Mineralogy, structure and tectonic significance of quartz veins from the northern Saih Hatat Dome (eastern Oman Mountains) 

Andreas Scharf, Frank Mattern, Bernhard Pracejus, Ivan Callegari, Robert Bolhar, Sobhi Nasir, Saja Al-Wahaibi, Laila Al-Battashi, Marwa Al-Hadhrami, Thuraiya Al-Harthi, and Safiya Al-Suqri

The rocks of the Saih Hatat Dome (SHD) formed during and after two major geological events shaping Arabia: 1) Subduction of continental rocks in the course of the Late Cretaceous Semail Ophiolite obduction onto the Arabian Plate and 2) Exhumation of >16 km and high deformation/folding in the northeastern part of the SHD. The latter resulted in a ~20 km wide recumbent fold (Saih Hatat Fold Nappe). The sub-horizontal fold axis of this fold trends NNE in the northern SHD. The core of the SHD and the recumbent fold consist of dark Neoproterozoic meta-shales and meta-sandstones, while its margin (and upper/lower limbs of the recumbent fold) consist of Permian cliff-forming carbonates.

Within the northern SHD, numerous milky quartz veins occur. We structurally and mineralogical analyzed >500 of these veins, covering an area of ~200 km2. The veins vary in width from one centimeter to a few meters, while the length ranges between several decimeters to several decameters. Associated with the predominant milky quartz, are calcite, siderite, chlorite, albite, anorthite, actinolite, rutile, hematite, goethite, and pyrrhotite. Rare molybdenite aggregates seem to replace carbonate, in which it occurs exclusively. Quartz microstructures include bulging (BLG) recrystallization, sub-grain rotation (SGR) recrystallization, and undulose extinction. Sub-grains and triple junctions in quartz are common. The mineralogy and quartz microstructures indicate maximum peak temperature conditions of ~400-500°C.

At least two sets of veins can be distinguished. Both vein sets occur mostly in clusters and partly form vein swarms. The mineralogy and quartz microstructure of both vein sets is similar. The older set 1 has been folded by the Saih Hatat Fold Nappe. Thus, vein formation predates 76-70 Ma. Furthermore, veins of set 1 are often sub-parallelly oriented to the main foliation of the host rocks, and they may be boudinaged. They may form complicated vein structures. We assume that this vein set initially formed during the Permian Pangean/Tethys rifting. The second vein set is abundant, sub-vertically and strikes consistently E/W to ESE/WNW. These veins cut the overall moderately NW-dipping bedding surfaces of the ambient rocks. Set 2 veins either formed during exhumation of the dome (Late Cretaceous to early Eocene and late Eocene to Oligocene) or they are part of the NW-striking sinistral Hajar Shear Zone, which affected the entire eastern Oman Mountains during the Oligocene to early Miocene. Ongoing U-Pb dating of carbonates and further field survey will further contribute to the understanding of their age and tectonic setting.

How to cite: Scharf, A., Mattern, F., Pracejus, B., Callegari, I., Bolhar, R., Nasir, S., Al-Wahaibi, S., Al-Battashi, L., Al-Hadhrami, M., Al-Harthi, T., and Al-Suqri, S.: Mineralogy, structure and tectonic significance of quartz veins from the northern Saih Hatat Dome (eastern Oman Mountains), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13597, https://doi.org/10.5194/egusphere-egu22-13597, 2022.

EGU22-1896 | Presentations | GD8.1

Asthenospheric Flow through the Izanagi-Pacific Slab Window and its Influence in East Asia 

Hamish Brown, Lorenzo Colli, and Hans-Peter Bunge

The tectonics of East and Southeast Asia are notoriously complex. Consisting of an intricate patchwork of microplates and accreted terrains, even the recent (i.e Cenozoic) tectonic history of the region remains controversial; and many differing reconstructions have been proposed. While the exact kinematics remain poorly constrained, it is generally accepted that the region has been characterised by a long history of subduction and downwelling. However, numerous geological and geophysical observations, at a first glance, appear to lie in stark contrast to this history. For example, regions of present-day dynamic uplift inferred from residual topography studies, the observation of seismically slow anomalies in numerous tomography models, and the widespread intraplate volcanism in East Asia since the latest Paleogene are all at odds with the expected cold upper mantle and downwelling associated with a history of subduction. Here, we propose a solution to this problem, in which hot asthenospheric material flows from the Pacific domain into East Asia—passing through the slab window opened by the subduction of the Izanagi-Pacific ridge during the early Cenozoic. To investigate this hypothesis, we compare several independent geological observations to the asthenospheric flow predicted by a suite of recently published 3D global mantle convection models.  Firstly, we compare observations linked to uplift and erosion to the changes in dynamic topography induced by this influx of hot material. These include the widespread late Eocene–Oligocene sedimentary hiatus in far eastern China and the regional erosion of southeastern China since the Miocene inferred from Apatite Fission Track Thermochronology (AFT) studies. Secondly, the timing and location of intraplate volcanism is compared with the predicted distribution of hot material through time. We find the westward influx of asthenospheric material to be a robust feature in the models, being predicted under all considered tectonic reconstructions.  Nevertheless, the influence of this material is significantly affected by differing implementations of the Philippine Sea Plate (PSP) history, which allows us to distinguish between these reconstructions based on their correlations with the evidence considered. A larger PSP is found to predict dynamic subsidence in regions where uplift and erosion is present, such as the East China Sea Shelf Basin and the Cathaysia Block, while also predicting large-scale mantle downwelling in regions where intraplate OIB-type magmatism has been recorded. A smaller PSP and the consequent existence of the hypothesised 'East Asian Sea' slabs instead allows the hot asthenospheric material to predominate over a larger region, providing a better fit to the spatial distribution of regional-scale erosional episodes and OIB-type magmatism.

How to cite: Brown, H., Colli, L., and Bunge, H.-P.: Asthenospheric Flow through the Izanagi-Pacific Slab Window and its Influence in East Asia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1896, https://doi.org/10.5194/egusphere-egu22-1896, 2022.

EGU22-2130 | Presentations | GD8.1

Reconstruction of the Cenozoic deformation of the Bohai Bay Basin, North China 

Yinbing Zhu, Shaofeng Liu, Bo Zhang, Michael Gurnis, and Pengfei Ma

A well-constrained plate deformation model may lead to an improved understanding of sedimentary basin formation and the connection between subduction history and over-riding plate deformation. Building quantitative models of basin kinematics and deformation remains challenging often due to the lack of comprehensive constraints. The Bohai Bay Basin (BBB) is an important manifestation of the destruction of the North China Craton, and records the plate kinematic history of East Asia during the Cenozoic. Although a number of interpretations of the formation of the BBB have been proposed, few quantitative basin reconstruction models have been built to test and refine previous ideas. Here, we developed a quantitative deformation reconstruction of the BBB constrained with balanced cross-sections and structural, stratigraphic, and depositional age data. Our reconstruction suggests that the basin formation process was composed of three main stages: Paleocene-early Eocene (65-42 Ma) extension initiation, middle Eocene-early Oligocene (42-32.8 Ma) extension climax, and post-Oligocene (32.8-0 Ma) post-extensional subsidence. The deformation of the BBB is spatially heterogeneous, and its velocity directions rotated clockwise during the basin formation process. The reconstruction supports the interpretation that the BBB formed via strike-slip faulting and orthogonal extension and that the basin is classified as a composite extensional-transtensional basin. We argue that the clockwise rotation of the basin velocity field was driven by the counter-clockwise rotation in the direction of Pacific Plate subduction. The kinematics of the BBB imply that the Pacific Plate may have been sufficiently coupled to the over-riding East Asian Plate during the critical period of Pacific Plate reorganization. The new reconstruction provides a quantitative basis for studies of deformation processes not only in the vicinity of the BBB but more broadly throughout East Asia.

How to cite: Zhu, Y., Liu, S., Zhang, B., Gurnis, M., and Ma, P.: Reconstruction of the Cenozoic deformation of the Bohai Bay Basin, North China, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2130, https://doi.org/10.5194/egusphere-egu22-2130, 2022.

EGU22-2715 | Presentations | GD8.1

When will the marginal sea grow up? 

Huizi Jian, Ting Yang, and Peng Guo

The back-arc marginal sea is a small ocean basin located between the volcanic arc and the continental crust. This area is not only an important gathering place for natural resources, but also an important place for plate interaction. Therefore, clarifying the origin and evolution of marginal seas can produce a huge boost for us to explore natural resources and improve the plate interaction mechanism. At present, the back-arc marginal sea with the largest opening rate of the Earth is the Lau Basin, and most marginal seas are generally in a state of medium-to-low-speed opening, such as the Mariana Trough, the Aegean Sea and the Caribbean Sea, and a small amount of marginal seas are even shortening, such as the Sea of Japan. What caused the marginal seas to open at different speeds?  In order to answer this question systematically and give a unified model for the origin and evolution of the marginal seas of the Earth, we must first figure out when the marginal sea will grow up. Therefore, we run 2-D and 3-D numerical experiments to test the possible effects of different factors on the evolution of the marginal sea. The results of our dynamic models can not only fit the evolution of the global marginal sea well, but also come to a robust conclusion: when the subducting plate stagnate in the transition zone, the opening rate of the marginal sea may decrease; but the marginal sea that stopped opening may still grow up again under special conditions. Furthermore, we explain the diversity of the current marginal sea evolution, which provides more theoretical foundations for the discipline of plate tectonics.

 

How to cite: Jian, H., Yang, T., and Guo, P.: When will the marginal sea grow up?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2715, https://doi.org/10.5194/egusphere-egu22-2715, 2022.

EGU22-5668 | Presentations | GD8.1 | Highlight

Quantifying the contributions of Pacific Plate motion change and hotspot drift to the formation of Hawaiian-Emperor Bend 

Jiashun Hu, Michael Gurnis, Johann Rudi, Georg Stadler, Dietmart Müller, and Jie Zhang

The Hawaiian-Emperor Seamount Chain changed its strike by 60° around 47 Ma, causing the Hawaiian-Emperor Bend (HEB). Both a change in Pacific Plate motion and a change in plume dynamics have been proposed to account for the HEB, but vigorous debates remain on their relative contribution. In order to have a better understanding, we build high–resolution global mantle convection models and test alternative plate reconstructions of North Pacific to quantify the contribution of each mechanism. For the contribution of Pacific Plate motion change, we find that Izanagi Plate subduction, followed by demise of the Izanagi–Pacific ridge and Izu–Bonin–Mariana subduction initiation alone, is incapable of causing a sudden change in plate motion, challenging the conventional hypothesis on the mechanisms of Pacific Plate motion change. Instead, with the alternative intra-oceanic subduction model, the Paleocene slab pull from Kronotsky subduction in North Pacific exerts a northward pull on the Pacific Plate, with its demise causing a sudden 30-35° change in plate motion. We further quantify the Hawaiian Hotspot drift using global mantle convection models with both the traditional and the alternative plate reconstructions. We find both models yield a fast southward drifting Hawaiian plume due to the push of slabs on the edge of the Pacific LLSVP. In the end, we discuss the combinational effects of Pacific Plate motion change and Hawaiian hotspot drift on the formation of HEB under different scenarios to gain insights on the possible history of North Pacific since the Late Cretaceous.

How to cite: Hu, J., Gurnis, M., Rudi, J., Stadler, G., Müller, D., and Zhang, J.: Quantifying the contributions of Pacific Plate motion change and hotspot drift to the formation of Hawaiian-Emperor Bend, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5668, https://doi.org/10.5194/egusphere-egu22-5668, 2022.

EGU22-5762 | Presentations | GD8.1

Tectonic activity at Mangatolu Triple Junction and the Fonualei Rift and Spreading Center: breaking apart the intra-oceanic Niuafo’ou-Tonga microplate, Lau Basin, South West Pacific Ocean 

Anouk Beniest, Michael Schnabel, Udo Barckhausen, Anke Dannowski, Florian Schmid, Michael Riedel, Anna Jegen, and Heidrun Kopp

 The Mangatolu Triple Junction (MTJ) and the Fonualei Rift and Spreading Center (FRSC) are two prominent bathymetric features in the northern Lau Basin in the southwest Pacific Ocean. We present the results of six W-E running Multi-Channel Seismic (MCS), magnetic and sediment echo sounding profiles acquired during the ARCHIMEDES-I expedition. These profiles cover the MTJ, the FRSC and the region just south of the FRSC to investigate the tectonic history and current tectonic activity of the Lau Basin. 

On all MCS profiles, we observe a heavily faulted basement on both sides of the MTJ and FRSC with faults that are covered with sediments, confirmed by the sediment echo sounding data. We consider these buried faults inactive today. We also observe faults that reach the seafloor. These faults are generally located closer to the MTJ and the FRSC and they correlate well with seismic activity recorded in the region. We thus consider these faults currently active. Seismically transparent bodies are observed on most profiles as well. We have interpreted those as volcanic intrusions, i.e. sills, or as volcanoes that pierce through the stratigraphy, especially closer to the volcanic arc. 

The two sets of faults, the notion that extension rates are higher at the MTJ (32 mm/yr) than at the southern tip of the FRSC (8 mm/yr) and the results from our newly acquired and interpreted magnetic data, have led to the interpretation that an earlier rift phase accommodated extension in a wide rift tectonic setting between 2.15 Ma and 0.85 Ma at the MTJ and 2.15 and 1.61 Ma at the FRSC. Today, the extension is accommodated in a narrow rift tectonic setting close to the MTJ and FRSC with a higher extension rate at the MTJ than at the southern tip of the FRSC. These findings suggest that the MTJ and FRSC are one, single intra-plate extension zone that is in the process of breaking apart the overriding Niuafo’ou-Tonga microplate along the MTJ and FRSC.

How to cite: Beniest, A., Schnabel, M., Barckhausen, U., Dannowski, A., Schmid, F., Riedel, M., Jegen, A., and Kopp, H.: Tectonic activity at Mangatolu Triple Junction and the Fonualei Rift and Spreading Center: breaking apart the intra-oceanic Niuafo’ou-Tonga microplate, Lau Basin, South West Pacific Ocean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5762, https://doi.org/10.5194/egusphere-egu22-5762, 2022.

EGU22-6749 | Presentations | GD8.1 | Highlight

Stratigraphic record of dynamic topography in the Andean foreland basin, South America 

Brian K. Horton

Variations in subduction configuration and mantle dynamics can be detected in retroarc foreland basins.  Modern and ancient examples from western South America show how discrete geodynamic mechanisms drive regional unconformity development in the Andean foreland basin.  Positive dynamic topography in the basin, fold-thrust belt, and broader convergent plate margin can be generated by (1) flat slab subduction, (2) slab window formation, (3) slab breakoff, (4) elevated intraplate (in-plane) stress, or (5) mantle flow variations.  A survey of long duration (>1–20 Myr) unconformities considers these and alternative mechanisms, including (6) local shortening-induced uplift in the frontal thrust belt and proximal foreland, (7) growth and advance of a broad flexural forebulge in the distal foreland, (8) uplift of intraforeland basement blocks along crustal-scale reverse faults, (9) tectonic quiescence with regional isostatic rebound, and (10) diminished accommodation or sediment supply due to changes in sea level, climate, erosion, or sediment transport.  These contrasting mechanisms can be readily observed in the modern foreland, particularly in the case of increased interplate coupling during active flat slab subduction and slab window generation associated with subduction of an active oceanic spreading ridge.  In the ancient record, the operative geodynamic mechanisms can be distinguished on the basis of the spatial distribution, stratigraphic position, paleoenvironmental context, and duration of foreland unconformities within the Cretaceous to Quaternary geodynamic framework of the Andean orogenic system.

How to cite: Horton, B. K.: Stratigraphic record of dynamic topography in the Andean foreland basin, South America, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6749, https://doi.org/10.5194/egusphere-egu22-6749, 2022.

EGU22-6764 | Presentations | GD8.1

Exploring the Cascadia slab structure coupling 3D thermomechinal and CPO modeling. 

Menno Fraters, Magali Billen, John Naliboff, Lydia Staisch, and Janet Watt

The Cascadia Subduction Zone is characterized by young subducting lithosphere, its isolation from other subducting slabs, and its ability to produce megathrust earthquakes (M>9.0) and devastating tsunamis. Due to its high potential hazard and risk, it is also a well-studied subduction zone where modern, diverse and detailed observational datasets are available through the USGS and initiatives like GeoPrisms and EarthScope. These datasets include high quality GPS, onshore and offshore geophysical imaging, magmatic and seismic anisotropy data. These datasets present an opportunity to gain insight into slab structure, tectonic evolution, and present-day seismic hazards. Still, many questions remain about the physical processes that can self-consistently explain all the observations, and better estimate seismic hazards. For example, for the slab, geologic and geophysical data suggest that there may be one or two prominent slab gaps or tears, while tomographic data does not fully constrain the depth extent of the slab. Furthermore, the overriding plate is composed of several different terranes and contain numerous active and slowly moving faults, complicating efforts to accurately constrain variations in the overriding plate present-day stress and deformation rates.

In this study we test whether comparison of observations to model predictions can distinguish between different slab geometries for the Cascadia Subduction Zone. To this end, we have created regional 3D geodynamic models of Cascadia including the Cascadia slab based on the Slab 2.0 dataset. The model setup is built with the Geodynamic World Builder and, and the models are run using the mantle convection and lithospheric dynamics code ASPECT. During the evolution of these models we track the development of the CPO (Crystal Preferred Orientation), so we can compare it against seismic anisotropy data of the region. Our presentation will focus on the preliminary results of these models and demonstrate workflows for linking the model results to surface tectonics.

How to cite: Fraters, M., Billen, M., Naliboff, J., Staisch, L., and Watt, J.: Exploring the Cascadia slab structure coupling 3D thermomechinal and CPO modeling., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6764, https://doi.org/10.5194/egusphere-egu22-6764, 2022.

It is widely accepted that the subduction system along an active continental margin has significant impacts on continental motions and deformation. The longest strike-slip fault in East Asian, the Tan-Lu Fault extends through the lithosphere and parallels the East Asian margin trench could be recognized as weak zone and left more significant geological information of plate tectonics than surrounding areas ( Collettini et al., 2019 ). Previous studies have gained some common sense about the motion of the East Eurasia continent margin from the Tan-Lu fault in the Late Mesozoic. The Tan-Lu fault experienced two phases sinistral strike-slip motion under compression with a striking-length about 150~200 km ( Zhu et al.,2005, 2009; Zhao et al.,2016 ), one stage is the Late Jurassic of the obtained age of 162~150 Ma and the other stage is the Early Cretaceous of the gained age of 143Ma~132Ma ( Zhu et al.,2005, 2010, 2018; Zhang and Dong, 2008 ). However, the formation mechanism of the large strike motion is still in doubt. Zhu et al., (2018) suggest that the Mesozoic tectonism of the Tan-Lu fault zone is dominated by paleo-Pacific plate subduction and thus can reflect its subduction history, while some others think the geodynamics of the Tan-Lu fault is controlled by the combined influences of the collision between the Tibetan blocks and Eurasia and the paleo-Pacific plate subduction ( Zhang et al., 2010 ).

 

To understand whether the paleo-Pacific subduction could have a dominant impact on the tectonic activities along the Tan-Lu fault and how does it influence the overriding plate, we perform 3-D numerical simulations of oceanic-continental subduction with a weakened fault zone simulating the Tan-Lu Fault. The results indicate that the motion and deformation of the East Asian continental plate can be strongly influenced by the interaction between the paleo-Pacific plate and East Asia, especially by the coupling degree between the subduction plate and the overriding plate. The coupling degree could significantly improve when there is micro-continent from subduction plate collide with overriding plate and the overriding plate would undergo compression. The collision between micro-continents with East Eurasia continent in Late Jurassic and Early Cretaceous has been observed ( Li et al.,2020; Charvet,2013 ). From the plate reconstructions ( Müller et al.,2016 ), in the Late Mesozoic had a northward component with an average velocity 40~50 mm/yr. In our numerical model, the generation of large sinistral strike-length could explained by strong coupling caused by collision of micro-continents with Eurasia plate.

How to cite: Zhou, M., Yang, T., Deng, L., and Guo, P.: Strike-slip motion in the Late Mesozoic on the East Asian continental margin: Insight from 3-D numerical models with the Tan-Lu fault, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6782, https://doi.org/10.5194/egusphere-egu22-6782, 2022.

EGU22-7368 | Presentations | GD8.1

Late Cretaceous Sevier and Laramide orogenies in Wyoming-Utah-Colorado, USA: Insight from basin subsidence history 

Danya Zhou, Shaofeng Liu, Lianbin Wang, and Neng Wan

The spatial and temporal variations of basin subsidence could potentially provide critical information for investigating the history of orogeny and deep mantle processes. However, due to the complexity of the formation mechanism of the Western Interior Basin, the factors controlling the basin subsidence has long been debated. Here, by reconstructing a high-resolution chronostratigraphic framework for the Upper Cretaceous strata and restoring the subsidence history of the basin, we analyze the control of the Sevier and Laramide orogenies on the Late Cretaceous evolution of the basin in the Wyoming-Utah-Colorado, and reveal the contemporary migration pattern of long-wavelength dynamic subsidence. During Cenomanian to Santonian time, thrusting events were active on the western margin of the basin, along which NS-trending long-wavelength subsidence center developed. By early Campanian (ca. 82 Ma), thrusting events developed into NW trend, and the center of long-wavelength subsidence shifted in the same orientation and gradually migrated to the center of the basin. Starting in the Maastrichtian (ca. 72 Ma), the NW-trending thrusting events migrates northeastward, roughly consistent with coeval long-wavelength subsidence center. Our results show that the former thrust event is related to Sevier orogeny, while the latter should be related to the Laramide orogeny. The initial timing of the Laramide deformation could start at as early as 82 Ma. This finding suggests that migrations of both long-wavelength subsidence center and Laramide deformation are driven by changes of Farallon subduction direction from eastward to northeastward and subduction angle from deep to flat. Our work shows how the subsidence history precisely records the timing and trajectory of Sevier and Laramide orogenies and dynamic topography, providing valuable insights for future three-dimensional modeling of dynamic subsidence in the Western Interior Basin.

How to cite: Zhou, D., Liu, S., Wang, L., and Wan, N.: Late Cretaceous Sevier and Laramide orogenies in Wyoming-Utah-Colorado, USA: Insight from basin subsidence history, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7368, https://doi.org/10.5194/egusphere-egu22-7368, 2022.

EGU22-10560 | Presentations | GD8.1 | Highlight

First views from assimilation of a new ‘tomographic’ circum-Pacific plate reconstruction into mantle circulation models 

Jonny Wu, Yi-An Lin, Lorenzo Colli, Yi-Wei Chen, Spencer Fuston, and Tsung-Jui Jeremy Wu

One of the greatest challenges of modeling the plate tectonic history of Earth during the Mesozoic and Cenozoic eras lies in reconstructing the Pacific Ocean and its predecessor ocean, Panthalassa.  A major reason for the plate tectonic uncertainty in this region is extensive subduction, which has consumed most (>95%) of the Pacific-Panthalassan ocean lithosphere formed since 150 Ma (Törsvik et al., 2019) and recycled it into the mantle, destroying the information on past plate motions recorded by seafloor magnetic lineations.  Consequently, many circum-Pacific margin plate tectonic models, including the popular GPlates models (e.g. Matthews et al., 2016; Müller et al., 2019), necessarily extrapolate 1000’s of km of subducted seafloor (i.e. synthetic seafloor isochrons).  Given the limited constraints, it is understandable that such models also prefer more straightforward solutions with a smaller number of larger plates, avoiding the complexities of modeling intra-oceanic subduction despite geological evidence from accreted circum-Pacific oceanic terranes.

Here we build the first topologically-closed, global plate tectonic model of the circum-Pacific using structurally-restored slabs from mantle seismic tomography as our primary constraint.  We use the numerical code TERRA to assimilate three variants of our ‘tomographic’ global plate model into mantle circulation forward models and assimilate the default GPlates model as a reference.  We show our preliminary geodynamic modeling results and test our model predictions against observed mantle structure, Earth’s geoid, and oceanic realm dynamic topography. 

All cases favor plate models that incorporate intra-oceanic subduction within Pacific-Panthalassa, particularly within the northern Pacific.  We find robust support for significant slab lateral advections (i.e. non-vertical slab sinking) under NW Pacific basin.  We discuss similarities and differences between our new ‘tomographic’ plate models and the GPlates model, which has been used for almost all geodynamic studies of the circum-Pacific to date. 

How to cite: Wu, J., Lin, Y.-A., Colli, L., Chen, Y.-W., Fuston, S., and Wu, T.-J. J.: First views from assimilation of a new ‘tomographic’ circum-Pacific plate reconstruction into mantle circulation models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10560, https://doi.org/10.5194/egusphere-egu22-10560, 2022.

EGU22-11229 | Presentations | GD8.1

The Horizontal Slab Beneath East Asia and Its Subdued Surface Dynamic Response 

Bo Zhang, Shaofeng liu, Pengfei Ma, and Michael Gurnis

The kinematics of plate tectonics, deformation, and dynamic topography are strong indicators of coupling between plates and the mantle. East Asia is characterized by the presence of an unusually large horizontal slab that lies within the mantle transition zone. How this feature evolved and is linked to plate tectonics, deformation, and topography is poorly understood. Here, we show four-dimensional geodynamic modeling results constrained by a new deforming plate reconstruction that fits mantle architecture inferred from seismic tomography. We find that the subducted western Pacific slab was progressively torn by the Philippine Sea plate rotating clockwise during the Miocene and that northwestward mantle flow contributed to shaping the horizontal slab during subduction, leading to dynamic subsidence along the East Asia margin. The rather subdued change in dynamic topography, predicted from those models that fit the horizontal slab in the mantle, is consistent with the variation in residual topography, recorded in the stratigraphy, within only about +/- 200 m over the last 50 Myr during a period of no large marine inundation or retreat. The tectonics and topography of East Asia strongly contrast with those of Southeast Asia and are reflective of slabs ephemerally stagnating in the mantle below East Asia while avalanching into the lower mantle below Southeast Asia.

How to cite: Zhang, B., liu, S., Ma, P., and Gurnis, M.: The Horizontal Slab Beneath East Asia and Its Subdued Surface Dynamic Response, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11229, https://doi.org/10.5194/egusphere-egu22-11229, 2022.

Decoding tectonic and climatic signatures from continental successions has become important in basin analysis. However, tectonic and climatic signatures can still be difficult to discriminate from each other. The late Mesozoic Xuanhua basin in the western Yanshan fold‑and‑thrust belt represents a representative intramontane basin and allows detailed stratigraphic, sedimentological, and provenance analyses. The work entailed an analysis of alluvial fan, fluvial, lake‑delta, and lacustrine systems in the Tuchengzi Fm. Lateral correlation of sedimentary columns reveals two large‑scale upward‑coarsening cyclothems each 80-240m thick, with prominent vertical changes from lacustrine through deltaic and fluvial to alluvial fan deposits. Two intervals of thrust‑related growth strata identified in the Tuchengzi Fm suggest that the cyclothems were controlled by tectonic uplift and accommodation change related to the Likouquan and the Mapu thrusting. In the lower upward‑coarsening cyclothem, stacking of small‑scale (3-16 m thick) upward‑fining cyclothems was revealed and argued to have been generated by alternating wet‑dry cycles. The wet half‑cycle started with discharge and deposition of flood‑generated mass‑flows into the lake and ended with accumulation of lacustrine mudstones as lake level rose. The lake deposits include the maximum flooding during the wet half‑cycle. The dry half‑cycle was characterized by continued lacustrine deposits, but with increased evidence of subaerial exposure indicated by rooting, paleosols and mudcracks resulting from falling of the lake level under dry conditions.

How to cite: Lin, C., Liu, S., and Steel, R.: Tectonic and climatic controls on the Late Jurassic-Early Cretaceous stratigraphic architecture of the Xuanhua basin, North China, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13356, https://doi.org/10.5194/egusphere-egu22-13356, 2022.

EGU22-13514 | Presentations | GD8.1

Two-stage rifting of Jiaolai Basin, Eastern China, decoding from the source-to-sink reconstruction 

Bo Zhang, Shaofeng Liu, Chengfa Lin, and Pengfei Ma

The basin is an essential window for exploring tectonic evolution, which preserves the information of regional extension, subsidence, uplift, and denudation. The Jiaolai Basin, located on the northern the Sulu Orogenic Belt, records the extension events of East Asia and the post-orogenic evolution of the Sulu Orogenic Belt during the Cretaceous. Multiple provenance analyses were used in the study to reconstruct the source-to-sink system of the Laiyang Group in the Jiaolai Basin. The results show that the Jiaolai Basin has a two-stage evolution history. In the early Early Cretaceous (ca. 135-122Ma), the Zhucheng sag and Gaomi sag in the south developed firstly. Subsequently, in the late Early Cretaceous (ca. 121-113Ma), the Laiyang Sag in the north developed. Moreover, these sags undergone independent, multi-stage source-sink system evolution in their early stages, and shared similar provenance supply systems at the end of Laiyang Group (ca. 113Ma). The provenance analysis results show that at ~121 Ma, ultra-high pressure (UHP) rock undergone a rapid exhumation in the northern section of the Sulu orogenic belt, whereas, for the southern section, The UHP may not be exposed until ca.113Ma. The two-stage extension in Eastern Asia with the change in direction and magnitude, recorded in the Jiaolai basin, suggests the trench retreat and subduction direction Change of the Izanagi plate should be the first-order drive force of the extension events of Eastern Asia during the Cretaceous. Our results indicate that the change of the Izanagi subduction direction may be ~121 Ma.

How to cite: Zhang, B., Liu, S., Lin, C., and Ma, P.: Two-stage rifting of Jiaolai Basin, Eastern China, decoding from the source-to-sink reconstruction, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13514, https://doi.org/10.5194/egusphere-egu22-13514, 2022.

EGU22-13552 | Presentations | GD8.1

Dynamic origin of anomalous subsidence of Jurassic Ordos basin 

Neng Wan, Shaofeng Liu, Guangting Liu, and Xueyan Li

The Jurassic Ordos basin is generally considered an intracontinental basin characterized by rapid subsidence rate along western margin and slow subsidence rate within basin interior. However, the formation mechanism of Ordos basin was not yet well understood. Flexural backstripping of stratigraphic record spanning from 174-153Ma, along three well sections perpendicular to the western margin of Ordos basin clearly demonstrates that there were long wavelength anomalous subsidence components, termed residual subsidence, in addition to those induced by thrust loads and sediment loads. Flexural components exhibit similar spatial and temporal trends along three sections. Simulations demonstrates that the foredeep is only 80-100 km wide, corresponding to effective thickness of 15-20 km. Contribution by flexural component relative to cumulative subsidence decreases from 50-60% to -15% within foredeep from thrust front towards basin interior, while residual subsidence could account for 40-50% of cumulative subsidence for areas outboard extent of foredeep. From 174-153 Ma, residual subsidence increases from ~150 m to ~330 m, ~200 m to ~390 m, ~180 m to ~480 m in southern, middle and northern section respectively. Our results indicate that thrust loads could act as the dominant driver for subsidence of foredeep while other mechanism needs to be raised to explain the basin-wide anomalous residual subsidence. The general agreement regarding both magnitude and trends along all three sections between dynamic topography predicted by geodynamic models and residual subsidence separated from flexural modeling, indicates that the anomalous subsidence component might be of dynamic origin, related to subduction of paleo-Pacific plate initiated from latest Early Jurassic.

How to cite: Wan, N., Liu, S., Liu, G., and Li, X.: Dynamic origin of anomalous subsidence of Jurassic Ordos basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13552, https://doi.org/10.5194/egusphere-egu22-13552, 2022.

EGU22-382 | Presentations | GD5.2

Correlation slab heterogeneity and volcanism in Kamchatka arc 

Olga Bergal-Kuvikas

The correlation of subducted plate parameters with generated volcanism was studied along the Kamchatka arc. Increased slab age controls dip angle (25-45o) and length of the seismic zone (200-700 km slab depth)  from the north (~530N) to the south (~490N) of the Kamchatka arc. All listed above parameters generate various aged volcanic belts with different parameters of volcanism. The natural boundary between various aged slabs is on ~530N, on the extension Avachinsky transform fault. It divides the Kamchatka arc on Southern Kamchatka with slab age ~ 103-105 Ma and Eastern volcanic belt, Central Kamchatkan Depression with slab age ~ 87-92 Ma. Complicated evolution and various ages of the slab control magmatism along the Kamchatka arc. Basic-intermediate magma compositions dominantly characterized Quaternary-Pliocene volcanoes in Central Kamchatkan Depression. In contrast, Neogene-Quaternary volcanism on Southern Kamchatka represents by strong explosions of acidic magmas (Gordeev, Bergal-Kuvikas, 2022).

Monogenetic volcanism marked a Malko-Petropavlovsk zone of transverse dislocations (MPZ), which is located on the extension Avachinsky transform fault. Monogenetic cinder cones in MPZ are randomly distributed along to these long-lived rupture zones. Here I present new geochemical and isotopic results of monogenetic volcanism in MPZ. Based on whole rock and trace element geochemistry, Pb-Sr-Nd isotopic ratios of monogenetic cinder cones magmas were shown to tap the enriched mantle source (low 143Nd/144Nd isotopic ratios (0.512959-0.512999), as variated 87Sr/86Sr (0.703356-0.703451) and 206Pb/204Pb (18.30-18.45), 208Pb/207Pb (38.00-38.12) isotopic ratios).  High Nb/Yb and La/Yb ratios, without significant inputs of the slab`s components (the lowest Ba, Th contents), indicate decompression melting predominately (Bergal-Kuvikas et al., 202X). Therefore, a combination of geophysical and geochemical methods enable us to conclude that monogenetic volcanism in MPZ   mark a natural boundary between various aged slab on Avachinsky transform fault. Various aged slabs under Southern Kamchatka and the Eastern volcanic belt generate volcanism with different magma compositions and ages of volcanoes.

This research was supported by Russian Science Foundation (grant number 21-17-00049,https://rscf.ru/project/21-17-00049/).

References

Bergal-Kuvikas O.V., Bindeman I.N., Chugaev A.V., Larionova Yu. O., Perepelov A.V., Khubaeva O.R. Pleistocene-Holocene monogenetic volcanism at Malko-Petropavlovsk zone of transverse dislocations on Kamchatka: geochemical features and genesis // Pure and Applied Geophysics. Special Issue: Geophysical Studies of Geodynamics and Natural Hazards in the Northwestern Pacific Region (in review)

Gordeev, E.I., Bergal-Kuvikas O.V. (2022). Structure of subduction zone and volcanism on Kamchatka. Doklady of the Earth Sciences. 2. 502. P. 26-30. 10.31857/S2686739722020086

 

 

 

How to cite: Bergal-Kuvikas, O.: Correlation slab heterogeneity and volcanism in Kamchatka arc, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-382, https://doi.org/10.5194/egusphere-egu22-382, 2022.

EGU22-1293 | Presentations | GD5.2

The maximum depth of the subduction channel in modern subduction zones 

Hans-Joachim Massonne

The subduction channel is located directly above a downgoing oceanic plate and forms by dehydration of this plate. The ascending water-rich fluids react with the mantle to hydrous minerals such as chlorite and amphibole. This process rheologically weakens the mantle and reduces its density so that an upwards-directed mass flow is continuously generated as long as the oceanic plate is subducted. However at great depth, the fluids ascending from the subducting plate do not produce hydrous minerals anymore due to too high pressure-temperature (P-T) conditions. Thus, the question arises how high can these conditions become in order to still generate such hydrous minerals in the mantle. To answer this question, thermodynamic modelling was undertaken with PERPLE_X using different data sets of Holland and Powell (1998, 2011), corresponding solid-solution models for relevant minerals, and the bulk-rock composition of a common lherzolite + 2.5 wt% H2O. In addition, results of experiments at high pressure on the P-T stability of hydrous minerals such as chlorite were considered.

Under the assumption of a relatively steeply and fast dipping oceanic plate, the geothermal gradient at the interface between this plate and the overlying mantle wedge should be below 7.5 °C/km (100 km = 3.2 GPa). At such low gradients, that are common in modern subduction zones, chlorite is the only (nominally) hydrous mineral in the lherzolite considered because amphibole shows an upper pressure limit, for example 2.3 GPa using model cAmph(G), in the calculation results. Calculations with the data set of Holland and Powell (1998) lead to results at pressures >3 GPa, which are, due to the used equation-of-state for minerals, incompatible with experimental results, whereas the results produced with the more recent data set (Holland and Powell, 2011) are compatible. Along gradients of 7.5, 5, and 3.5 °C/km, chlorite decomposes to form garnet in lherzolite at about 740 (3.15 GPa), 660 (4.3 GPa), and 570 °C (5.3 GPa), respectively. These temperatures are 60-80 °C lower than calculated for the reaction of chlorite + enstatite = forsterite + pyrope + H2O in the system MgO-Al2O3-SiO2-H2O.

The aforementioned P-T conditions limit the subduction channel towards great depths, which should be less than 160 km (5.2 GPa) even at very low thermal gradients, and are compatible with peak P-T conditions of many eclogites exhumed in the subduction channel from the surface of the downgoing oceanic plate. A few exceptions were reported which suggest exhumation of eclogite from depths > 200 km (e.g., Ye et al., 2000). The reason for these greater depths could be another exhumation mechanism. However, a misinterpretation of so-called exsolution lamellae in eclogitic minerals, taken as evidence for unusual mineral compositions and, thus, depths > 200 km, is more likely (see Liu and Massonne, 2022).

Holland, T.J.B., Powell, R., 1998. J. Metamorph. Geol. 16, 309-343.

Holland, T.J.B., Powell, R., 2011. J. Metamorph. Geol. 29, 333–383.

Liu, P., Massonne, H.-J., 2022. J. Metamorph. Geol., doi: 10.1111/jmg.12649

Ye, K., et al., 2000. Nature 407, 734–736.

How to cite: Massonne, H.-J.: The maximum depth of the subduction channel in modern subduction zones, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1293, https://doi.org/10.5194/egusphere-egu22-1293, 2022.

EGU22-2400 | Presentations | GD5.2

Segmentation of subducting oceanic plates by brittle-ductile damage 

Taras Gerya, David Bercovici, and Thorsten Becker

Subducting oceanic plates experience intense normal faulting during bending that accommodates the transition from horizontal to downward motion at the outer rise at subduction trenches. We investigated numerically the consequences of the plate bending on the mechanical properties of subducting slabs using 2D subduction models in which both brittle and ductile deformation, as well as grain size evolution, are tracked and coupled self-consistently. Numerical results suggest that pervasive brittle-ductile slab damage and segmentation can occur at the outer rise region and under the forearc that strongly affects subsequent evolution of subducting slabs in the mantle. This slab-damage phenomenon explains the subduction dichotomy of strong plates and weak slabs, the development of large-offset normal faults near trenches and the occurrence of segmented seismic velocity anomalies and interfaces imaged within subducted slabs. Furthermore, brittle-viscously damaged slabs show a strong tendency for slab breakoff at elevated mantle temperatures that may have destabilized continued oceanic subduction and plate tectonics in the Precambrian (Gerya et al., 2021).

Gerya, T.V., Bercovici, D., Becker, T.W. (2021) Dynamic slab segmentation due to brittle-ductile damage in the outer rise. Nature, 599, 245-250.

How to cite: Gerya, T., Bercovici, D., and Becker, T.: Segmentation of subducting oceanic plates by brittle-ductile damage, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2400, https://doi.org/10.5194/egusphere-egu22-2400, 2022.

EGU22-3822 | Presentations | GD5.2

Subduction dynamics through the mantle transition zone in the presence of a weak asthenospheric layer 

Nestor Cerpa, Karin Sigloch, Fanny Garel, Rhodri Davies, and Arnauld Heuret

Plate kinematics in the vicinity of subduction zones, as well as seismic tomography provide insights into the deep dynamics of subducting slabs. Velocities at which subducting plates are consumed at the trench (the subduction velocities) typically exceed 3–4 cm/yr at present-day. Absolute trench velocities (relative to a lower-mantle reference frame) are lower, between -2 and 2 cm/yr [Heuret and Lallemand, 2005]. This implies that the “accommodation space” created by the slab rollback associated with lateral trench migration is not nearly sufficient for accommodating the length of incoming slab in the horizontal dimension. In the vertical dimension, even the fastest estimates for slab sinking rates over long time scales amount to only a fraction of 3–4 cm/yr [Butterworth et al. 2014, van der Meer et al. 2010, Sigloch & Mihalynuk 2013]. Hence the rates at which the lithosphere typically subducts cannot be accommodated by fast vertical sinking either. Seismic tomography confirms the “traffic jam” conditions for slabs in the mantle that are implied by these numbers, with slab thickening imaged in and beneath the mantle transition zone (MTZ). These highly visible, thickened, slabs have been interpreted as the result of folding [Ribe et al., 2007], and their relative localization (massive,  near-vertical “slab walls”) supports the notion of near-stationary trenches over long time scales [Sigloch and Mihalynuk, 2013]. 

Buoyancy-driven analog and numerical models of subduction have commonly produced subduction and trench velocities that differ from the first-order observations above. Their subduction velocities typically drop below 1-2 cm/yr once the modelled slab enters the high-viscosity lower mantle, and their trench migration velocities remain almost equal to subduction velocities, thus accommodating the slab mainly in the horizontal direction. In addition, these models tend to produce trench retreat and slab “rollback” , unless the latter is very weak and/or the overriding plate is very strong [Goes et al., 2017]. These modelling results have led to the conclusion that near-vertical slab sinking and folding at the MTZ is an end-member regime restricted to very specific subduction set-ups. 

We have added a weak asthenospheric layer to typical 2-D thermo-mechanical models of subduction zones with a complex rheology [e. g., Garel et al., 2014], which partly reconciles the models and the observations. A weak asthenosphere appears as an intuitive candidate for increasing subduction velocity because a reduced mantle drag at the base of the subducting plate lowers the mantle’s resistance to the plate’s trench-ward motion. We further found that the models with a weak asthenospheric layer lessens the trench motion and thus tend to produce prominent vertical folding of slabs at the MTZ. Subduction velocities remain higher than trench velocities long after the slab reaches the MTZ, so that 300-to-400-km wide “slab walls” are continuously produced in the lower mantle over a relatively wide range of model parameters. The presence of a weak asthenosphere has often been speculated to explain seismic properties beneath oceanic plates, but seldom modelled. This study contributes to a quantification of its potential effects on subduction dynamics. 

How to cite: Cerpa, N., Sigloch, K., Garel, F., Davies, R., and Heuret, A.: Subduction dynamics through the mantle transition zone in the presence of a weak asthenospheric layer, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3822, https://doi.org/10.5194/egusphere-egu22-3822, 2022.

EGU22-4233 | Presentations | GD5.2

Global compilation of double seismic zones and their dependence on the intraslab stress field 

Christian Sippl, Timm John, Stefan Schmalholz, and Armin Dielforder

Double seismic zones (DSZs), parallel planes of intermediate-depth earthquakes inside oceanic slabs, have been observed in a number of subduction zones and may well be a ubiquitous feature of downgoing oceanic plates. Early focal mechanism observations from Japan and Alaska have shown downdip compressive events in the upper and downdip extensive events in the lower plane of the DSZ, which was interpreted as a signature of plate unbending at these depths. Such a pattern of compressive over extensive events has become a hallmark of DSZ seismicity, and some models of DSZ seismogenesis explicitely rely on an unbending-dominated intraslab stress field as a mechanism for deep slab hydration.

In this study, we show that the intraslab stress field in the depth range of DSZs is much more variable than previously thought. Compiling DSZ locations and mechanisms from literature, we observe that the “classical” pattern of compressive over extensive events, as in NE Japan, is only observed at about half of the DSZ locations around the globe. The occurrence of extensive mechanisms across both planes accounts for most other regions, whereas a “bending signature” of extensive over compressive events is not widely observed at all. To obtain an independent estimate of the (un)bending state of slabs at intermediate depths, we compute (un)bending estimates from slab geometries taken from the slab2 compilation of slab surface depths. We find no clear prevalence of slab unbending at intermediate depths, and the occurrence of DSZ seismicity does not appear to be limited to regions of slab unbending. Taking high-resolution focal mechanism information from the Northern Chile subduction zone as an example, we conclude that the intraslab stress field in subduction zones is primarily a superposition of (un)bending stresses and downdip extensive in-plane stresses. Depending on the sign (bending or unbending) and the relative contributions of these two principal stresses, an unbending signature as in NE Japan or a purely extensive pattern of focal mechanisms as in Northern Chile can emerge. We also consider possible additional contributing stresses that may further modify the intraslab stress field, such as friction along the plate interface and volume loss due to metamorphic phase changes.

How to cite: Sippl, C., John, T., Schmalholz, S., and Dielforder, A.: Global compilation of double seismic zones and their dependence on the intraslab stress field, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4233, https://doi.org/10.5194/egusphere-egu22-4233, 2022.

EGU22-4261 | Presentations | GD5.2

3D numerical modeling of suction-induced subduction initiation at passive margins 

Marzieh Baes, Stephan Sobolev, Andrea Hampel, and Anne Glerum

Conversion of a passive margin, which is the transition between oceanic and continental lithosphere formed by sedimentation above an ancient rift, into an active converging plate boundary is still ambiguous. According to the Wilson Cycle (Wilson, 1966), which describes the repeated opening and closing of the oceans, the collapse of a passive margin is a key factor in the closing phase of the Wilson Cycle. However, the lack of any Cenozoic examples of conversion of passive margins into subduction zones and the existence of old oceanic plates along Atlantic passive margins indicate the difficulty of subduction initiation at passive margins. Due to lack of observational evidence, modeling studies play a key role in understanding the kinematics and dynamics of transforming a passive into active margin. During the last decades, they proposed several facilitating mechanisms to collapse a passive margin such as sediment loading (Cloetingh et al., 1982), water weakening (Regenauer-Lieb et al., 2001), STEP faults (Subduction-Transform-Edge-Propagator; Govers and Wortel, 2005) near passive margins (Baes et al., 2011), mantle suction forces derived from detached slabs and/or neighboring subduction zones (Baes and Sobolev, 2017), convergence forces induced from neighboring plates (Zhong and Li, 2019) and propagation of subduction along passive margins (Baes and Sobolev, 2017; Zhou et al., 2020).

 In this study, we extend the work of  Baes and Sobolev (2017) by using 3D models. As breaking a 3D lithosphere is more difficult than a 2D plate, 3D numerical models may lead to different conclusions than those of 2d ones. To study the effect of mantle suction flow on the destabilisation of passive margins, we set up 3D models, using the ASPECT finite element code (Kronbichler et al., 2012). We investigate the effect of different parameters such as the magnitude, spatial size and location of suction flow, the age of oceanic lithosphere and the existence of a STEP (Subduction-Transform-Edge-Propagator; Govers and Wortel, 2005) fault near margin. Our preliminary results show over-thrusting of continental crust from the earliest stage of deformation. This continued over-thrusting along with suction force, which imposes shear stresses below the lithosphere, causes breaking of the oceanic plate and its sinking into the mantle and eventually subduction initiation at the passive margin. The time of subduction initiation, which depends on several factors such as magnitude and location of the suction force, is more than 30 Myr indicating difficulty in the converting passive margins into converging plate boundaries. We believe that subduction initiation at some Atlantic passive margins such as those in the north of the South Sandwich subduction zone, southwest of the Iberia and north of the Caribbean region, where considerable suction forces induced by sinking slabs or neighboring subduction zones are available, will occur in a few tens of million years.

 

References:

Baes et al., 2011. Geophys. J. Int.

Baes, and Sobolev, 2017. Geochem. Geophys. Geosyst.

Cloetingh et al., 1982. Nature.

Govers and Wortel, 2005, Earth Planet. Sci. Lett.

Kronbichler et al., 2012, Geophys. J. Int.

Regenauer-Lieb et al., 2001. Sci.

Wilson, 1966, Nature

Zhou et al., 2020. Sci. Adv.

Zhong and Li, 2019. Geophys. Res. Lett.

 

How to cite: Baes, M., Sobolev, S., Hampel, A., and Glerum, A.: 3D numerical modeling of suction-induced subduction initiation at passive margins, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4261, https://doi.org/10.5194/egusphere-egu22-4261, 2022.

EGU22-4399 | Presentations | GD5.2

Fluid migration, deep dehydration, and melt generation in the Lesser Antilles subduction zone 

Lidong Bie, Stephen Hicks, Andreas Rietbrock, Saskia Goes, Jenny Collier, Catherine Rychert, Nicholas Harmon, and Benjamin Maunder and the VoiLA Consortium

Volatiles play a pivotal role in subduction zones dynamics, associated geological hazards and mineralization, yet their pathways remain partially understood. The Lesser Antilles subduction zone can yield insights to volatile recycling as a global end-member, where old oceanic lithosphere formed by slow spreading slowly subducts. Here we use seismograms from local earthquakes recorded by a temporary deployment of ocean-bottom seismometers in the fore- and back-arc during the VoiLA (Volatile Recycling in the Lesser Antilles) experiment to characterize the 3-D properties of the slab, back-arc and mantle wedge in the north-central Lesser Antilles subduction zone. Along the top of the slab, defined by the underlying Wadati-Benioff seismicity, we find low P-wave velocity extending to 130–150 km depth, deeper than expected for magmatic oceanic crust. The deep low velocities together with high Vp/Vs at 60–80 km and 120–150 km depth are consistent with a significantly tectonised and serpentinised slab top, as expected for lithosphere formed by slow spreading. The most prominent high Vp/Vs anomalies in the slab correlates with two projected fracture zones and the obliquely subducting boundary between Proto-Caribbean and Equatorial Atlantic lithosphere, indicating these structures enhance hydration of the oceanic lithosphere and subsequent dehydration when subducted. Deep dehydration of slab mantle serpentinite is evidenced by high Vp/Vs anomalies in the back-arc offshore Guadeloupe and Dominica. Right above the slab, the asthenospheric mantle wedge is imaged beneath the back-arc as high Vp/Vs and moderate Vp feature, indicative for fluids rising from the slab through the overlaying cold boundary layer. The fluids might be dragged down with the subducting slab before rising upwards to induce melting further to the west. The variation in seismic properties along the subducting slab and in the back-arc mantle wedge shows that the changes in hydration of the incoming plate govern the dehydration processes at depth. The highest Vp/Vs anomaly in the back-arc west of Dominica at depth greater than 120 km, together with the anomaly at 60–80 km depth on the slab east of the island, appear to track the source and path of excess volatiles that may explain the relatively high magmatic output observed on the north-central islands of the Lesser Antilles arc.

How to cite: Bie, L., Hicks, S., Rietbrock, A., Goes, S., Collier, J., Rychert, C., Harmon, N., and Maunder, B. and the VoiLA Consortium: Fluid migration, deep dehydration, and melt generation in the Lesser Antilles subduction zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4399, https://doi.org/10.5194/egusphere-egu22-4399, 2022.

Intermediate-depth earthquakes in many subduction zones occur in two distinct layers, forming an upper and a lower seismic zone separated vertically by an aseismic or weakly seismic region. These Double Seismic Zones (DSZs) have been related to dehydration reactions in the downgoing crust and mantle lithosphere. Notably, intermediate-depth seismicity in Northern Chile shows a pattern of intraslab seismicity which is quite different from a conventional DSZ. Here, two parallel seismicity planes are present in the updip part of the slab, but at a depth of ∼80–90 km, there is a sharp transition to a highly seismogenic volume of 25–30 km thickness, which corresponds to a closing of the gap between the two seismicity planes.

While such an observation is unique to Northern Chile, understanding the processes behind the formation of this feature should provide important constraints on the mineral processes that govern seismicity in DSZs as well as the role and involvement of fluids. As seismic velocities contain important information about mineralogy and fluid content, we aim at a high-resolution characterization of the seismic wavespeeds of the Northern Chile subduction zone, mainly focusing on the downgoing Nazca slab. We use the seismicity catalog of Sippl et al. (2018) that contains >100,000 earthquakes and 1,200,404 P- and 688,904 S-phase picks for the years 2007 to 2014 to perform local earthquake tomography using the FMTOMO algorithm (Rawlinson et. al., 2006). Data from the seismic stations of the permanent IPOC (Integrated Plate boundary Observatory Chile) deployment in the Northern Chile forearc form the backbone of the dataset, but are complemented by several temporary deployments that span shorter time sequences.

We will present first 3D models of P- and S-wavespeeds from the Northern Chile forearc between about 19°S and 23°S, using a subset of the earthquake catalog mentioned above, as well as images of ray coverage, relocated seismicity and synthetic resolution tests.

The presented seismic velocity distribution will eventually be compared with theoretical wavespeeds that are forward calculated assuming different mineralogical compositions in order to narrow the range of possible reactions that may be occurring at depth.

How to cite: Hassan, N. and Sippl, C.: Towards imaging dehydration reactions in the downgoing Nazca plate with local earthquake tomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4461, https://doi.org/10.5194/egusphere-egu22-4461, 2022.

EGU22-4774 | Presentations | GD5.2 | Highlight

Subduction invasion of the Atlantic by Mediterranean subduction zones 

João C. Duarte, Nicolas Riel, Boris J.P. Kaus, and Filipe M. Rosas

Subduction invasion has been referred to as the process by which subduction zones from a subducting ocean invade or trigger subduction initiation in a contiguous ocean. This can, in principle, happen in different ways that can vary from a direct migration by rollback along an oceanic corridor connecting the two oceans (e.g., the Gibraltar Arc into the Atlantic) or by polarity reversal across a narrow continental land bridge, potentially involving the collision of an ocean plateau with the pre-existent trench (the Scotia and the Caribbean arcs). This process is important because new subduction zones are difficult to start in the present plate tectonics context and most known examples of initiation seem to be forced by pre-existent subduction zones. The problem is that in internal Atlantic-type oceans there are no pre-existent subduction zones, and therefore, they must be introduced from the outside. Luckily, the Atlantic seems to be just passing through a phase of invasion, as evidenced by the three referred examples. But while the Caribbean and the Scotia arcs are already two fully formed Atlantic-subduction systems, the Gibraltar Arc is currently in the process of migrating between oceanic basins. In the future, the Arc can evolve according to two different scenarios. In the first, the Gibraltar Arc is stuck between Africa and Iberia and the subduction is waning. In the other scenario, after a period of quiescence, the arc manages to go through and invade the Atlantic. In order to understand which is more feasible, we have developed 3D numerical models using the code LaMEM to gain some insights into how this system may evolve. We have simulated the development of the Mediterranean arc-back-arc system, with rollback and the retreat of the subduction zones in a fully dynamic framework (no active kinematic boundaries). Our model shows that under the studied parameters, the Gibraltar subduction zone manages to invade the Atlantic, even in the cases of a very narrow oceanic corridor. However, this led to a very significant decrease in the subduction velocity, suggesting that in the natural prototype, a period of quiescence is expected before the Mediterranean subduction zone manages to go through and invade the Atlantic.

J.C. Duarte and F.M. Rosas acknowledge financial support by FCT through the project UIDB/50019/2020 – Instituto Dom Luiz (IDL)

How to cite: Duarte, J. C., Riel, N., Kaus, B. J. P., and Rosas, F. M.: Subduction invasion of the Atlantic by Mediterranean subduction zones, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4774, https://doi.org/10.5194/egusphere-egu22-4774, 2022.

EGU22-4810 | Presentations | GD5.2

Modelling ridge jumps in back-arc basins at different scales 

Valentina Magni, Nicholas Schliffke, Jeroen van Hunen, Frédéric Gueydan, Mark Allen, John Naliboff, Manel Prada, and Carmen Gaina

The structure of oceanic back-arc basins reflects the dynamics of the subduction zone they are associated with. Often, the basement of these basins is not only composed of oceanic crust, but also of exhumed mantle, fragments of continental crust, intrusive magmatic bodies, and a complex mid-ocean ridge system characterised by distinct relocations of the spreading centre. These features are a direct consequence of the transient nature of subduction zones. Here, we show results from different types of numerical models that aim at understanding how back-arc basins are shaped by subduction dynamics.

We present 3D numerical models of back-arc spreading centre jumps evolving naturally in a homogeneous subduction system surrounded by continents without a trigger event (Schliffke et al., 2022). We find that jumps to a new spreading centre occur when the resistance on the boundary transform faults enabling relative motion of back-arc and neighbouring plates is larger than the resistance to break the overriding plate closer to trench. Time and distance of spreading centres jumps are, thus, controlled by the ratio between the transform fault and overriding plate strengths. We also present results from 2D numerical models of lithospheric extension with asymmetric and time-dependent boundary conditions that simulate multiple phases of extension due to episodic trench retreat (Magni et al., 2021). We show that multiphase extension can result in asymmetric margins, mantle exhumation and continental fragment formations. We find that the duration of the first extensional phase controls the final architecture of the basin. Finally, we show that our models can explain many features observed in present-day and extinct back-arc basins.

Magni, V., Naliboff, J., Prada, M., & Gaina, C. (2021). Ridge Jumps and Mantle Exhumation in Back-Arc Basins. Geosciences, 11(11), 475.

Schliffke, N., van Hunen, J., Gueydan, F., Magni, V., & Allen, M (2022). Episodic back-arc spreading centre jumps controlled by transform fault to overriding plate strength ratio. Accepted for publication in Nature Communications.

 

 

How to cite: Magni, V., Schliffke, N., van Hunen, J., Gueydan, F., Allen, M., Naliboff, J., Prada, M., and Gaina, C.: Modelling ridge jumps in back-arc basins at different scales, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4810, https://doi.org/10.5194/egusphere-egu22-4810, 2022.

EGU22-4976 | Presentations | GD5.2

Plume-induced sinking of the intracontinental lithosphereas a fundamentally new mechanism of subduction initiation. 

Sierd Cloetingh, Alexander Koptev, Istvan Kovacs, Taras Gerya, Anouk Beniest, Ernst Willingshofer, Todd Ehlers, Nevena Andric-Tomasevic, Svetlana Botsyun, Paul Eizenhofer, Thomas Francois, and Fred Beekman

Although many different mechanisms for subduction initiation have been proposed, few of them are viable in terms of agreement with observations and reproducibility in numerical experiments. In particular, it has recently been demonstrated that intra-oceanic subduction triggered by an upwelling mantle plume could contribute greatly to the onset and functioning of plate tectonics in the early Earth and, to a lesser extent, in the modern Earth. In contrast, the onset of intracontinental subduction is still underestimated. Here we review 1) observations demonstrating the upwelling of hot mantle material flanked by sinking proto-slabs of the continental mantle lithosphere, and 2) previously published and new numerical models of plume-induced subduction initiation. Numerical modelling shows that under the condition of a sufficiently thick (> 100 km) continental plate, incipient down thrusting at the level of the lowermost lithospheric mantle can be triggered by plume anomalies with moderate temperatures and without significant strain and/or melt-induced weakening of the overlying rocks. This finding is in contrast to the requirements for plume-induced subduction initiation in oceanic or thin continental lithosphere. Consequently, plume-lithosphere interactions in the continental interior of Paleozoic-Proterozoic (Archean) platforms are the least demanding (and therefore potentially very common) mechanism for triggering subduction-like foundering in Phanerozoic Earth. Our findings are supported by a growing body of new geophysical data collected in a variety of intracontinental settings. A better understanding of the role of intracontinental mantle downthrusting and foundering in global plate tectonics and, in particular, in triggering "classic" oceanic-continental subduction will benefit from further detailed follow-up studies.

How to cite: Cloetingh, S., Koptev, A., Kovacs, I., Gerya, T., Beniest, A., Willingshofer, E., Ehlers, T., Andric-Tomasevic, N., Botsyun, S., Eizenhofer, P., Francois, T., and Beekman, F.: Plume-induced sinking of the intracontinental lithosphereas a fundamentally new mechanism of subduction initiation., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4976, https://doi.org/10.5194/egusphere-egu22-4976, 2022.

EGU22-5045 | Presentations | GD5.2

Depressed 660-km seismic discontinuity beneath cold subduction zones caused by akimotoite-bridgmanite phase transition 

Artem Chanyshev, Takayuki Ishii, Dmitry Bondar, Shrikant Bhat, Eun Jeong Kim, Robert Farla, Keisuke Nishida, Zhaodong Liu, Lin Wang, Ayano Nakajima, Bingmin Yan, Hu Tang, Zhen Chen, Yuji Higo, Yoshinori Tange, and Tomoo Katsura

The 660-km seismic discontinuity (D660) is the boundary between the Earth’s lower mantle and transition zone and is commonly interpreted as the dissociation of (Mg,Fe)2SiO4 ringwoodite to (Mg,Fe)SiO3 bridgmanite plus (Mg,Fe)O ferropericlase (post-spinel transition). Prominent features of D660 are significant depressions to 750 km and multiplicity beneath cold subduction zones. Previous high-pressure experiments provided negative but gentle Clapeyron slopes (−1.3 to −0.5 MPa/K) of the post-spinel transition. Thus, the post-spinel transition cannot interpret the D660 depression. Therefore, another phase transition with a steep negative slope is required, and the akimotoite−bridgmanite transition in (Mg,Fe)SiO3 is one candidate.

In the current study, we determined the boundaries of the post-spinel (RBP) and akimotoite−bridgmanite (AB) phase transitions in the MgO-SiO2 system over a temperature range of 1250–2085 K using advanced multi-anvil techniques with in situ X-ray diffraction. We judged a stable phase assemblage by observing relative increase/decrease in the ratio of coexisting high- and low-pressure assemblages at spontaneously and gradually decreasing pressure and a constant temperature from diffraction intensities. Since this strategy is strictly based on the principle of phase equilibrium, it excludes problems in determining phase stability caused by sluggish kinetics and surface energy.

We found that the RBP boundary has a slightly concave curve, whereas the AB boundary has a steep convex curve. The RBP boundary is located at pressures of 23.2–23.7 GPa in the temperature range of 1250–2040 K. Its slope varies from −0.1 MPa/K at temperatures less than 1700 K to −0.9 MPa/K at 2000 K with an averaged value of −0.5 MPa/K. The slope of the AB boundary gradually changes from −8.1 MPa/K at low temperatures up to 1300 K to −3.2 MPa/K above 1600 K. Based on these findings, we predict that, beneath cold subduction zones, ringwoodite should first dissociate into akimotoite plus periclase, and then akimotoite transforms to bridgmanite with increasing depth; these successive transitions cause the multiple D660. Moreover, the steep negative boundary of the AB transition should result in cold-slab stagnation due to significant upward buoyancy. Our predictions are supported by the seismological observations beneath cold (e.g., Tonga, Izu-Bonin) subduction zones.

How to cite: Chanyshev, A., Ishii, T., Bondar, D., Bhat, S., Kim, E. J., Farla, R., Nishida, K., Liu, Z., Wang, L., Nakajima, A., Yan, B., Tang, H., Chen, Z., Higo, Y., Tange, Y., and Katsura, T.: Depressed 660-km seismic discontinuity beneath cold subduction zones caused by akimotoite-bridgmanite phase transition, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5045, https://doi.org/10.5194/egusphere-egu22-5045, 2022.

EGU22-5283 | Presentations | GD5.2

Sulfur transfer along a metasomatized serpentinite-metagabbro contact in the Voltri Massif, Italy 

Esther Schwarzenbach, Linus Streicher, Besim Dragovic, Maria Rosa Scicchitano, Uwe Wiechert, Emmanuel Codillo, Frieder Klein, Horst Marschall, and Marco Scambelluri

Subduction zones provide a key link between the surficial biogenic, atmospheric and hydrospheric geochemical cycles with the Earth’s internal reservoirs. Sediment compaction and dehydration of variably altered oceanic lithosphere during subduction release volatile species (containing e.g., S, H, C, N) to the overlying mantle wedge. In particular, sulfur plays a key role in the formation of porphyry ore deposits and has a major control on redox processes in subduction zones, given it occurs in variable oxidation states from oxidized sulfate (S6+) to reduced sulfide (S2-). Here we studied samples from a contact between serpentinite and partly metasomatized eclogitic metagabbros in the Voltri Massif (Italy). We determined the bulk rock and in situ sulfur isotope composition of pyrite grains and combined this with detailed mineralogic and petrologic investigations. Along the serpentinite-metagabbro contact, the metagabbros are metasomatized to actinolite-chlorite schists and metagabbros rich in epidote and Na- and Na-Ca amphiboles. The serpentinites as well as the actinolite-chlorite schists along the serpentinite-metagabbro contact have very low sulfide contents and provide evidence for the oxidation of sulfides, including formation of Fe-oxides. Sulfur input from the serpentinite-metagabbro contact towards the less metasomatized eclogitic metagabbros is observed. This sulfur input is reflected by bulk rock δ34S values that increase from initially around +1.5‰ in samples distant from the contact to +7.3 to +12.5‰ in samples near the contact. This trend correlates with a general increase in the in situ δ34S values from core to rim of individual pyrite grains. Distinct Co and Ni growth zones in pyrite and variations in the in situ δ34S values indicate multiple phases of pyrite growth during subduction and exhumation of these rocks, with the last stage of pyrite growth clearly related to Mg-metasomatism along the serpentinite-metagabbro contact. Thus, this study provides new insight into processes of sulfur migration during metasomatism of gabbroic rocks within the subducting slab and at the slab–mantle interface.

How to cite: Schwarzenbach, E., Streicher, L., Dragovic, B., Scicchitano, M. R., Wiechert, U., Codillo, E., Klein, F., Marschall, H., and Scambelluri, M.: Sulfur transfer along a metasomatized serpentinite-metagabbro contact in the Voltri Massif, Italy, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5283, https://doi.org/10.5194/egusphere-egu22-5283, 2022.

EGU22-5284 | Presentations | GD5.2

Variability of the shortening rate in Central Andes controlled by subduction dynamics and interaction between slab and overriding plate. 

Michaël Pons, Stephan Sobolev, Sibiao Liu, and Derek Neuharth

The nature of the shortening of the Central Andes has been a matter of debate. The South American plate is advancing westwards forcing the subducting Nazca plate to roll back and the trench to retreat. But as the trench slowed its retreat the Andean mountain belt formed. This decrease of trench velocity has been attributed to the anchoring of the slab, but this process cannot explain the observed pulsatile behaviour of the shortening rate. Indeed, whereas the formation of the Central Andes started ~50 Ma ago, most of the shortening and elevation growth, including the formation of the Altiplano-Puna plateau, took place in two pulsatile steps at 15 Ma and 7 Ma as recognized from geological data. Thus we hypothesize that the deformation of the Central Andes is controlled by the subduction dynamics and a complex interaction between the overriding and subducting plates.

We used the FEM geodynamic code ASPECT to develop a self-consistent subduction E-W-oriented 2D high-resolution geodynamic model along the Altiplano-Puna plateau (21°S). This model incorporates the flat slab subduction episode at 35 Ma and follows the evolution of the lithospheric deformation. Our model results reproduced the observed spatial and temporal variations of tectonic shortening in Central Andes.

Three main conditions related to the plate interaction are of key importance to explain the observed shortening rate evolution in Central Andes. Firstly, the subduction dynamics affects the trench migration: each episode of slab steepening is followed by the blocking of the trench. The steepening occurs after the flat slab and at the end of two slab-buckling instabilities at 15 Ma and at 7 Ma. The second relevant process is the weakening of the overriding plate. This is ensured by the partial removal of a part of the lithospheric mantle after the re-steepening of the flat slab at 35 Ma and by weakening of the sediments in the Subandean Ranges after 10 Ma. Thirdly, a relatively high interplate friction coefficient (~0.05) is needed to ensure the stress transfer from the slab to the overriding plate, which is further enhanced by the delaminated mantle lithosphere eventually blocking the subduction corner flow.

The pulses of shortening rate occur at the end of each slab-buckling cycle when the trench is blocked. The deformation of the overriding plate is intensified by the eclogitization of the lower crust and the subsequent delamination of the sublithospheric mantle. Finally, at ~10 Ma, the deformation switches from pure-shear to simple-shear shortening, after the underthrusting of the Brazilian craton in presence of weak foreland sediments. 

How to cite: Pons, M., Sobolev, S., Liu, S., and Neuharth, D.: Variability of the shortening rate in Central Andes controlled by subduction dynamics and interaction between slab and overriding plate., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5284, https://doi.org/10.5194/egusphere-egu22-5284, 2022.

EGU22-5344 | Presentations | GD5.2

Effects of subduction termination processes on continental lithosphere 

Simone Pilia, Rhodri Davies, Robert Hall, Conor Bacon, Amy Gilligan, Tim Greenfield, Felix Tongkul, and Nicholas Rawlinson

Subduction is the main driver of tectonic activity on Earth. Termination of subduction is followed by diverse and unexpected tectonic activity, such as anomalous magmatism, exhumation, subsidence and subsequent rapid uplift. What fundamentally drives these processes remain enigmatic. A prime example of subduction termination can be found in northern Borneo (Malaysia), where subduction ceased in the late Miocene and was followed by puzzling tectonic activity, as reconstructed from geological and petrological evidence. Our current understanding of the subduction cycle cannot be reconciled with evidence of post-subduction tectonics in both the near-surface geology and mantle of northern Borneo.

We use new passive-seismic data to image at unprecedent detail a sub-vertical lithospheric drip that developed as a Rayleigh-Taylor gravitational instability from the root of a volcanic arc, which formed above a subducting plate. We use thermo-mechanical simulations to reconcile these images with time-dependent dynamical processes within the crust and underlying mantle, following subduction termination. Our model predictions illustrate how significant extension from a downwelling lithospheric drip can thin the crust in an adjacent orogenic belt, causing lower crustal melting and possible exhumation of subcontinental material, which can explain core-complex formations seen in other areas of recent subduction termination.

How to cite: Pilia, S., Davies, R., Hall, R., Bacon, C., Gilligan, A., Greenfield, T., Tongkul, F., and Rawlinson, N.: Effects of subduction termination processes on continental lithosphere, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5344, https://doi.org/10.5194/egusphere-egu22-5344, 2022.

EGU22-7483 | Presentations | GD5.2

Controls on slab detachment and subsequent topography evolution 

Andrea Piccolo and Marcel Thielmann

Slab detachment causes a reorganization of the forces acting on orogenic systems and can have a distinctive signature in the geological record that may be identified through the structural,  metamorphic and topographic evolution of the orogen. However, this signature is hidden within other signals relating to the general complexity of the mountain building processes. In addition, slab detachment (or slab tearing in 3D) is a complex process that occurs on different timescales as a function of the inherent rheological properties of the lithosphere and the weakening mechanism occurring within the slab (viscous, plastic or thermal weakening).

How these properties affect the slab detachment process and to which extent these controls are reflected in the topograhic evolution of the orogenetic system is not yet fully understood. As slab detachment may occur at different depths and rates, it has different effects on the overall pull force acting on the orogen and on its post-detachment response.

Here, we employ 2D numerical experiments to systematically explore first order controls on slab detachment (slab rheology, geometry and weakening mechanisms) and the corresponding topographic evolution. Apart from the effect of lithosphere rheology and weakening mechanisms, we put particular focus on the effects of plate coupling and breakoff depth.

How to cite: Piccolo, A. and Thielmann, M.: Controls on slab detachment and subsequent topography evolution, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7483, https://doi.org/10.5194/egusphere-egu22-7483, 2022.

EGU22-8243 | Presentations | GD5.2

Styles of seamount subduction and overriding plate deformation 

Maaike Fonteijn, Elenora van Rijsingen, and Ylona van Dinther

The subduction of seamounts and its accompanying crustal deformation of the overriding plate is thought to have a large effect on the occurrence of megathrust earthquakes. Subducted seamounts can generally only be observed using seismic-reflection studies, which have shown that seamounts can subduct intact down to 30-40 km depth. On the other hand, there is evidence for accreted seamounts in e.g. the Costa Rica and Makran subduction zones. Because such observations only provide snapshots in space and time, little is still known about the exact evolution of seamount subduction and its effect on overriding-plate deformation and subduction zone seismicity through time. We investigate the different styles of seamount subduction and how these influence seismicity and overriding plate deformation. We use seismo-thermo-mechanical (STM) models with a visco-elasto-plastic rheology simulating seamount subduction over millions of years in a 2D realistic subduction setting. The momentum, mass and energy equations are solved and a strongly slip rate dependent friction allows for the spontaneous development of faults. The use of a realistic rheology allows us to evaluate faulting patterns and the state of stress in the overriding plate caused by seamount subduction. We find three scenarios for seamount subduction by varying the rock properties cohesion (C) and pore fluid pressure ratio (λ): (1) cutting off of the seamount at the trench leading to frontal accretion; (2) intact subduction through the trench, followed by flattening and stretching of the seamount; and (3) intact subduction of the seamount until seismogenic depths. Scenario’s 1 and 2 are most common, while scenario 3 only occurs under a limited range of material parameters. Particularly, a cohesion of the seamount and upper oceanic crust larger than 20 MPa is required for intact seamount subduction. Decreasing λ on locations with ample amounts of fluids increases the strength of the sediments, upper oceanic crust and seamount, but does not lead to intact seamount subduction. Subduction scenario’s 2 and 3 show more crustal deformation and seismicity within the fore-arc than subduction of a smooth interface (scenario 1 and models without a seamount). Seismicity patterns are also affected by λ and C. A low λ results in shorter and shallower megathrust ruptures and higher cohesions decrease the recurrence interval. Furthermore, the seamount itself introduces more frequent nucleation of smaller events at its edge.

How to cite: Fonteijn, M., van Rijsingen, E., and van Dinther, Y.: Styles of seamount subduction and overriding plate deformation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8243, https://doi.org/10.5194/egusphere-egu22-8243, 2022.

EGU22-8968 | Presentations | GD5.2 | Highlight

The role of subducted fluids on the genesis of deep earthquakes: evidence from deep diamonds and subduction zone thermal modeling 

Lara Wagner, Steven Shirey, Michael Walter, D. Graham Pearson, and Peter van Keken

The role of subducted fluids on the generation of deep earthquakes (300 – 700 km) has been a topic of much research and debate for decades. While fluids are commonly believed to play a role in the genesis of intermediate depth earthquakes (70 – 300 km), it is often argued that fluids (i.e., water- or carbonate-bearing) cannot be transported to sufficient depth to play a role in the triggering or propagation of deep earthquakes. However, recent investigations show evidence of up to ~1.5 wt% water in a ringwoodite inclusion in a diamond from the mantle transition zone [1]. Additionally, heavy iron (δ56Fe = 0.79–0.90‰) and unradiogenic osmium (187Os/188Os = 0.111) isotopic compositions of metallic inclusions in sublithospheric diamonds trace the pathway of serpentinized slabs from the trench to the top of the lower mantle [2]. Given this evidence for slab derived fluids at transition zone depths, we investigate the ability of fluids to reach these depths in subducted slabs by compiling a) new subduction zone thermal models, b) slab earthquake locations within these modeled subduction zones, and c) phase relations of hydrated or carbonated mantle peridotite and basaltic crust. Our results show a distinctive pattern that is consistent with the necessity of fluids in the generation of deep seismicity [3]. Specifically, those slabs capable of transporting water to the bottom of the transition zone (via dense hydrous magnesium silicates (DHMS)) produce earthquakes at transition zone depths. Conversely, virtually all slabs that do not transport water to these depths do not generate deep earthquakes. We also note that the depths of deep earthquakes coincide with the P/T conditions at which oceanic crust is predicted to intersect the carbonate-bearing basalt solidus to produce carbonatitic melts. We suggest that hydrous and/or carbonated fluids released from subducted slabs at these depths lead to fluid-triggered seismicity, fluid migration, diamond precipitation, and inclusion crystallization. Deep focus earthquake hypocenters would then track the general region of deep fluid release and migration in the mantle transition zone [3].

[1] Pearson, D. G., Brenker, F. E., Nestola, F., Mcneill, J., Nasdala, L., Hutchison, M. T., et al. (2014). Hydrous mantle transition zone indicated by ringwoodite included within diamond. Nature, 507, 221–224. https://doi.org/10.1038/nature13080 [2] Smith EM, Ni P, Shirey SB, Richardson SH, Wang W, and Shahar, A (2021) Heavy iron in large gem diamonds traces deep subduction of serpentinized ocean floor. Science Advances 7: eabe9773 https://doi.org/10.1126/sciadv.abe9773 [3] Shirey SB,  Wagner LS, Walter MJ, Pearson DG, and van Keken PE (2021) Slab Transport of Fluids to Deep Focus Earthquake Depths – Thermal Modeling Constraints and Evidence From Diamonds. AGU Advances: 2, e2020AV000304.    https://doi.org/10.1029/2020AV000304

How to cite: Wagner, L., Shirey, S., Walter, M., Pearson, D. G., and van Keken, P.: The role of subducted fluids on the genesis of deep earthquakes: evidence from deep diamonds and subduction zone thermal modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8968, https://doi.org/10.5194/egusphere-egu22-8968, 2022.

EGU22-11903 | Presentations | GD5.2

Modern hotspot-influenced MORBs reveal anoxic conditions during deposition and subduction of recycled Proterozoic sediments in their source 

Qasid Ahmad, Martin Wille, Carolina Rosca, Jabrane Labidi, Timothy Schmid, Klaus Mezger, and Stephan König

Significant Mo mobility and isotope (δ98/95Mo) fractionation is induced during prograde metamorphism at present-day subduction zones. Depending on the redox conditions during early subduction and accompanied slab dehydration, isotopically heavy Mo is released towards the overlying mantle wedge, leaving behind a depleted, and isotopically light subducted slab. This isotopically light Mo signature has been detected in slab-melt influenced volcanic rocks and potentially will be traceable in ocean-island basalts, if their geochemical signatures are affected by previously subducted lithologies (i.e. slab and overlying sediments). Thus, the isotope composition of mantle plume-influenced volcanic rocks might reveal the nature of subducted and re-incorporated lithologies and possibly redox conditions during subduction.

In this study, we present new Mo isotope data for South-Mid Atlantic Ridge basalts that partly interacted with the enriched Discovery and Shona mantle plumes. Isotopically heavier Mo isotope ratios (δ98/95Mo > ambient depleted mantle) are observed in samples tapping a more enriched mantle source. Furthermore, δ98/95Mo correlates with radiogenic isotopes (Sr, Nd, Hf) indicating recycling of a Proterozoic sedimentary components with a Mo isotopic composition that was not modified during and before subduction by Mo mobility under oxidising conditions. Rather, the new Mo isotope data supports and expands on previous stable Se and S isotope evidence that suggests the incorporation of subducted anoxic Proterozoic deep-sea sediments into the mantle of the South-Mid Atlantic Ridge basalts.

How to cite: Ahmad, Q., Wille, M., Rosca, C., Labidi, J., Schmid, T., Mezger, K., and König, S.: Modern hotspot-influenced MORBs reveal anoxic conditions during deposition and subduction of recycled Proterozoic sediments in their source, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11903, https://doi.org/10.5194/egusphere-egu22-11903, 2022.

EGU22-12659 | Presentations | GD5.2

Numerical modeling of subduction zones: thermo-mechanical stabilization as a function of overriding plate rheology and thickness 

Francisco Bolrão, Jaime Almeida, João C. Duarte, and Filipe M. Rosas

The absence of a forearc is a recurrent simplification in numerical subduction models. This because, to our knowledge, there are no previous studies that have systematically investigate the role of this structure on subduction systems. Despite its short length (166 ± 60 km), the forearc has a significant impact in the maintenance of a stable subduction. It has already been proposed that the serpentinization of this region, by percolating fluids from the sinking slab, reduces the effective mechanical strength of the plate coupling zone interface, allowing the one-sided asymmetric subduction observable in nature. Moreover, the forearc could be the key stabilization mechanism in intra-oceanic subduction settings. In this scenarios, the oceanic overriding plate (OP) could be in a thermal state such that would also be negative buoyant. The ubiquitous presence of forearcs in all-active intra-oceanic subductions suggests that a weak interface alone could not be enough to prevent the OP to sink. Adding a positive buoyant forearc  to the tip of the OP could provide the counterforce required to prevent the OP to sink, and eventually, double-sided subduction setting. There are studies that already implement a forearc structure in their numerical models. However, since its dynamic influence has not been study yet, we can not predict its impact and/or ascribe a specific dynamic behaviour of the system to it. 

In this work we investigate the role of the forearc and its contribution to emergent features in subduction zones. We present a series of fully dynamic, buoyancy driven, thermo-mechanical numerical modelling experiments with a free surface carried out to gain insight on the dynamic role of the forearc.  We use the Underwolrd numerical code to perform a parametrization to geometric and rheologic parameters of this structure, namely the thickness (age of the OP), length and density. We consider a forearc that encompasses the arc (25 to 250 km wide) as well. We kept all physical properties of the subducting plate  constant throughout all models. Therefore, we are able to ascribe all dynamic changes solely to variations of the forearc properties. We test different forearc compositions based on its density, ranging between 2700 and 3300  kg.m−3, for 200  kg.m−3 intervals, mimicking a full granitic continental and an basaltic oceanic forearc, respectively. For all densities, we also test several possible lengths, for 130 km and for 200 to 470 km, for intervals of 90 km. Additionally, we test all possible density-length combinations for five different OPs, in terms of age, ranging between 20 and 100 Myr, for 20 Myr intervals. 

We expect a higher accommodation of strain in the tip of the OP in models where the forearc is implemented. The presence of this structure could favor slab roll-forward before this reaches the 660 km discontinuity, enhance subduction velocities and generate a more pronounced orogenic topography. This features would be enhanced with the decrease of density and thickness and  the increase of length of the forearc.

How to cite: Bolrão, F., Almeida, J., C. Duarte, J., and M. Rosas, F.: Numerical modeling of subduction zones: thermo-mechanical stabilization as a function of overriding plate rheology and thickness, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12659, https://doi.org/10.5194/egusphere-egu22-12659, 2022.

EGU22-13213 | Presentations | GD5.2

Channel-flow induced ‘normal faulting’ in the Himalaya: a case study from the Jhala Normal Fault, Garhwal Higher Himalaya, NW India 

Narayan Bose, Takeshi Imayama, Ryoichi Kawabata, Saibal Gupta, and Keewook Yi

The ‘channel flow’ concept is generally associated with the collisional mountain belts (such as the Himalaya) to explain the exhumation of deeper crustal materials. According to the concept, the top part of the subducting plate gets ‘molten’ and tries to return to the surface following the ‘pipe flow’ mechanism via a combination of Poiseuille- and Couette Flows. In this study, we employed these concepts to address a long-standing debate related to the existence and cryptic nature (normal/ reverse) of an orogen parallel discontinuity, named the Jhala Normal Fault (JNF) present in the Bhagirathi River section of the Garhwal Higher Himalaya. More importantly, while a group of researchers consider the JNF to be the northern boundary of the Higher Himalayan channel (i.e., the South Tibetan Detachment System), another group put the JNF well inside the channel. In this scenario, understanding the mechanism of deformation at the JNF will not only solve this local issue but will also provide us with new insights into the geodynamic evolution of an orogeny. Based on fresh field observations and SHRIMP geochronological data (zircon and monazite), a model is being proposed in the current study to explain the origin and evolution of the JNF. The presence of amphibolite-grade rocks across the JNF, along with the lack of well-developed extensional markers, confirm that the fault is located within the Higher Himalayan channel, and not at the channel boundary. The U-Pb zircon rim ages of 33.8 ± 0.8 Ma and 30.7 ± 0.5 Ma obtained from the JNF hanging wall (northern block) and footwall (southern block), respectively, are considered as the ages of peak metamorphism. The hanging wall, which was present at the slow-moving marginal part of the channel during Eocene, eventually lagged behind the relatively faster and warmer central part. As a result, the footwall (southern) block experienced a faster exhumation, resulting in normal-sense movement along the JNF, as documented by sparse extension markers. At 21.4 ± 2.3 Ma (monazite U-Pb age), tourmaline-bearing leucogranite intruded in the JNF hanging wall, rupturing the host. This indicates the passive uplift of the JNF hanging wall (in a brittle domain) as a part of the Higher Himalaya. Hence the JNF originated as an intra-channel discontinuity, and our proposed model predicts the origin of a ‘normal fault’ during crustal channel flow.

How to cite: Bose, N., Imayama, T., Kawabata, R., Gupta, S., and Yi, K.: Channel-flow induced ‘normal faulting’ in the Himalaya: a case study from the Jhala Normal Fault, Garhwal Higher Himalaya, NW India, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13213, https://doi.org/10.5194/egusphere-egu22-13213, 2022.

EGU22-13458 | Presentations | GD5.2

No channel flow in the Longmen Shan: evidence from the Maoxian-Wenchuan fault Cenozoic kinematics (SE Tibet) 

Chenglong Ge, Philippe Hervé Leloup, Yong Zheng, and Haibing Li

The NE striking Longmen Shan (LMS) mountains are located at the eastern margin of the Tibetan plateau, and towers nearly 5000m above the Sichuan basin, which is considered to be the greatest relief than anywhere else around the plateau. From west to east, three major sub-parallel faults straddle the Longmen Shan: Wenchuan-Maoxian fault (WMF), Yingxiu-Beichuan fault and Guanxian-Anxian fault. Several models have been proposed to explain the Cenozoic uplift of the Longmen Shan. The major two models are lower crustal channel flow and upper crustal shortening, which imply different movement sense on the Wenchuan-Maoxian fault. The former suggests that the LMS were uplifted above a lower crustal flow expulsed from below the Tibetan plateau and would require a normal sense movement on the MWF. The latter implies that a series of upper crustal thrusts controlled the uplift of the LMS, and the WMF should have a reverse sense. Here we present field observations, fault gouge structural analysis and authigenic illite K-Ar geochronology data of fault gouge in the Wenchuan-Maoxian fault, showing that the Maoxian-Wenchuan fault was dextral with a reverse component at ~7Ma. Reconstruction of offsets of river valleys along the Wenchuan-Maoxian fault suggests that the corresponding total horizontal dextral offset is ~25km. Analysis of the thermochronology data acquired on both side of the fault suggest that dextral-reverse faulting started at ~13 Ma and possibly lasted until today. Our conclusions support the upper crustal shortening model and suggest the channel model maybe not applicable to Longmen Shan uplifting in the Miocene.

How to cite: Ge, C., Leloup, P. H., Zheng, Y., and Li, H.: No channel flow in the Longmen Shan: evidence from the Maoxian-Wenchuan fault Cenozoic kinematics (SE Tibet), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13458, https://doi.org/10.5194/egusphere-egu22-13458, 2022.

EGU22-2908 | Presentations | GD8.4

New insights in the lithospheric configuration of the Ligurian-Provençal Basin derived from gravity field interpretation 

Hans-Jürgen Götze, Judith Bott, Boris Kaus, Magdalena Scheck-Wenderoth, and Christian Schuler

The area of the western Mediterranean between the French and Italian coasts and Corsica-Sardinia is still of great interest in terms of its structural development, which remains incompletely understood. The resolution of geophysical data was not always high enough to explore detailed structures in the lithosphere. After completion of the new AlpArray gravity maps, a high-resolution gravity field is available. The intended 3D modelling of the lithosphere requires the search for reliable constraints for the density/susceptibility models (seismic, bathymetry, gravity fields, gradients). The calculation of residual gravity fields is difficult due to uncertainties in the calculation of regional fields which are characterized by pronounced gravity highs and lows in a very limited spatial area. The residual fields calculated here provide new insights into the lithospheric structure and suggest that the mass distribution in the Ligurian-Provençal Basin does not monotonously follow the known major geological units. A broad belt of local gravity highs (25 - 40 x 10-5 m/s2) extends off the French coast to the northwest of the basin where it merges with NW-SE directed gravity highs (up to 45 x 10-5 m/s2) near the Italian coast. Hitherto unknown is the residual field anomaly south of Marseille with max. 100 x 10-5 m/s2. Euler deconvolution and correlations with maps of focal depths of earthquakes resulted in source depths that lie in the mantle. The results of further processing techniques (curvature calculations, third derivative of potential, terracing and cluster analysis) were superimposed on geological maps to make visual correlations clear. Results of dynamic modelling of the surrounding subduction zones, as well as newly inferred Moho and LAB depths, are also available for interpreting gravity field components of deeper regions of the Earth's mantle in the study area. Previously performed investigations (magnetic field modelling and recent seismic campaigns, e.g., LOBSTER and AlpArray seismic tomography models) were also added to the research.

How to cite: Götze, H.-J., Bott, J., Kaus, B., Scheck-Wenderoth, M., and Schuler, C.: New insights in the lithospheric configuration of the Ligurian-Provençal Basin derived from gravity field interpretation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2908, https://doi.org/10.5194/egusphere-egu22-2908, 2022.

EGU22-3243 | Presentations | GD8.4

Seismic discontinuities from the Moho to 410 km depth between the Alps and Scandinavia from Sp converted waves 

Rainer Kind, Stefan Schmid, Felix Schneider, Thomas Meier, and Xiaohui Yuan

We use teleseismic data from all available broadband stations, permanent and mobile, in the entire area. Our processing method applies distance moveout correction, amplitude normalization, sign equalization and summation of traces with piercing points in 1° latitude times 1° longitude cells. The traces are stacked along the picked SV onset times. We obtain very clear signals from the Moho, less strong signals from velocity reductions below the Moho and again clear signals from the 410 km discontinuity. We also see locally velocity reductions just above the 410 km discontinuity. We show a number of profiles through the study area and hope to show maps of all seismic discontinuities. We compare our results with earlier observation.

How to cite: Kind, R., Schmid, S., Schneider, F., Meier, T., and Yuan, X.: Seismic discontinuities from the Moho to 410 km depth between the Alps and Scandinavia from Sp converted waves, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3243, https://doi.org/10.5194/egusphere-egu22-3243, 2022.

EGU22-3790 | Presentations | GD8.4

Quaternary paleostress regimes in the Eastern Alps inferred from ruptures in karst caves 

Ivo Baroň, Jacek Szczygieł, Rostislav Melichar, Lukas Plan, Bernhard Grasemann, Eva Kaminsky, and Denis Scholz

In the Alps, the Adriatic plate convergence provoked eastward lateral extrusion compensated by strike-slip faulting and N-directed thrusting. Since the Miocene, these complex processes have led to several paleostress phases. Since the Quaternary phase is the least recognized, we used karst cave passages as the geomorphic displacement indicators. This study presents an overview of 190 Quaternary fault ruptures in totally 27 caves in the Eastern Alps, some radiometrically dated, and the paleostress analysis based on cave passages offset. Reactivated faults have been registered with their orientation, slip vector and offset, in caves adjacent to major fault systems of the Eastern Alps. The paleostress was computed using the multiple inversion method for heterogeneous fault-slip data.

Most active faults in caves along the southern part of the sinistral Vienna Basin Transfer Fault were NW-SE, and NNE-SSW oriented and revealed mostly normal to sinistral kinematics and cumulative offsets of a few mm to a couple of cms. The associated extensional paleostress state comprised the E-W σ3 in agreement with the opening mode of the Vienna Basin. At sinistral Mur-Mürz Fault, the active faults striking NNE-SSE and ENE-WSW operated under a strike-slip regime with σ1 NE-SW. In the eastern segment of sinistral Salzach-Ennstal-Mariazell-Puchberg fault associated strike-slip paleostress regime with horizontal SE-NE σ1, and subhorizontal SE-trending σ3. This stress regime was computed from reverse, oblique reverse, oblique normal, and sinistral strike-slip reactivated faults documented in the Hochschwab massif. The central segment of Salzach-Ennstal-Mariazell-Puchberg fault is adjoin to Totes Gebirge and Dachstein massifs. In the western part of Totes Gebirge, three stress regimes were recorded. N-S and NW-SE striking oblique normal strike-slip faults revealed an extensional regime with NE σ3. Two strike-slip regimes with NE-SW σ1 and subhorizontal σ3 gently inclined to SE and NW were calculated from mostly steep oblique reverse NNE to NW striking faults with offsets up to a few decimetres. In the Dachstein massif, two paleostress phases were identified: the extensional regime with σ3 subhorizontally tilted to NE and the strike-slip regime with N-S σ1. Tens of active, mostly oblique normal strike-slip faults were documented in massifs adjacent to sinistral Königsee-Lammertal-Traunsee Fault: Hoher Göll, Tennengebirge and Hagengebirge. The dominating associated paleostress is an extensional regime with NE-SW σ3. The polyphase sinistral and reverse-dextral NE-SW faults with Late Pleistocene to Early Holocene reactivations and up to 40 cm offsets, identified at the sinistral Obir Fault attributed to the dextral Periadriatic Line. Neither the strike-slip regime with ENE-plunging σ1 nor the other strike-slip regime with σ1 WNW oriented to fit the regional stress setting. It probably resulted from large-scale complex Karawanken Mts. transpressive shear zone deformation.

In conclusion, the paleostress multiple inversions from the Quaternary cave passage ruptures kinematic data brought original information on the paleostress regime over a significant portion of the Eastern Alps in their latest deformational period.

How to cite: Baroň, I., Szczygieł, J., Melichar, R., Plan, L., Grasemann, B., Kaminsky, E., and Scholz, D.: Quaternary paleostress regimes in the Eastern Alps inferred from ruptures in karst caves, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3790, https://doi.org/10.5194/egusphere-egu22-3790, 2022.

EGU22-3979 | Presentations | GD8.4

Initial results of modelling 3D plate dynamics in the Alpine-Mediterranean area 

Christian Schuler, Boris Kaus, Eline Le Breton, and Nicolas Riel

Tectonic reconstructions of lithospheric plate motion can be approached by different geological methods. However hypotheses derived from these findings are often not validated in a physically consistent manner. Therefore we employ 3D geodynamic modelling in order to test geological reconstructions.

In this work, 3D thermomechanical forward simulations of the Alpine-Mediterranean area are conducted using the software LaMEM (Kaus et al. (2016)). A viscoelastoplastic rheology and an internal free surface are applied, which means that apart from the internal dynamics also the surface response can be investigated. Kinematic reconstructions of Le Breton et al. (2021) at 35 Ma serve as an initial setup for the simulations. The goal of these simulations is to determine the main driving forces of plate dynamics in this area. This is done by evaluating effects of different model parameters such as the thermal structure and the geometry of the slabs, the viscosity of the mantle and brittle parameters of the crust.

The geodynamic behaviour of the Alpine-Mediterranean area is dominated by various subducting plates which makes it particularly difficult to distinguish the unique influence of different geodynamic processes. The Adriatic microplate plays a key role in the development of the Alpine Orogeny and its plate motion and therefore serves as a marker as it is possible to compare the current position of this plate with the simulation itself. Even though these forward simulations are not capable of exactly reconstructing the current tectonic setting, they provide insights into parameters which influence the subduction dynamics.

First results suggest that the plate motion of Adria is primarily driven by the interaction of the Calabria slab and the Hellenic slab and that the propagation of these slabs strongly depends on the slab geometry and the initial trench location. Furthermore the spreading rate of rifting in the Liguro-Provençal Basin massively affects the timing of Adria’s plate motion.

 

Kaus, B. J. P., A. A. Popov, T. S. Baumann, A. E. Pusok, A. Bauville, N. Fernandez, and M. Collignon, 2016: Forward and inverse modelling of lithospheric deformationon geological timescales. Proceedings of NIC Symposium.

Le Breton, E., S. Brune, K. Ustaszewski, S. Zahirovic, M. Seton, R. D. Müller, 2021: Kinematics and extent of the Piemont–Liguria Basin–implications for subduction processes in the Alps. Solid Earth, 12(4), 885-913.

 

 

 

 

 

 

How to cite: Schuler, C., Kaus, B., Le Breton, E., and Riel, N.: Initial results of modelling 3D plate dynamics in the Alpine-Mediterranean area, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3979, https://doi.org/10.5194/egusphere-egu22-3979, 2022.

EGU22-4420 | Presentations | GD8.4

Seismotectonics in the Central Alps: An attempt to link fault structures, seismic activity and recent crustal movements 

Marco Herwegh, Samuel Mock, Tobias Diehl, Elmar Brockmann, Sandro Truttmann, Edi Kissling, Eva Kurmann-Matzenauer, Stefan Wiemer, and Andreas Möri

Owing to still ongoing convergence within the Europe-Adria collision zone, Switzerland is affected by heterogeneously distributed moderate seismic activity. The project SeismoTeCH aims to improve the understanding of the links between the seismic activity, existing fault structures and geodynamics in Switzerland and its close vicinity. We started with compiling existing databases on faults (fault densities, lengths and orientations), seismic activity (spatial hypocenter and magnitude distributions, detection of seismic lineaments, focal mechanisms), orientations of mean principal stress axes and recent crustal movements (GNSS, high precision levelling) in order to establish potential correspondences as well as regional variations.

Due to the long-lasting Alpine deformation, fault-orientation patterns as well as fault-densities vary between specific tectonic domains (Jura/North-Alpine foreland, Alpine frontal sediment nappe systems, External Crystalline Massifs, inner-Alpine domains and Southern Alps). Despite this variability, the fault patterns show first order correlations with the spatial arrangement of newly mapped seismic lineaments, earthquake focal planes and associated focal mechanisms. This correlation indicates a regional geodynamics-controlled reactivation of the specific fault networks during current crustal movements. In terms of recent surface movements, variations in (i) horizontal GNSS movements with respect to stable Europe and (ii) vertical uplift (from levelling and GNSS data) have to be discriminated. (i) From E to W in southern Switzerland (S-Grisons–Ticino–Valais, S of Rhone-Simplon line), horizontal movements change from NW to SW directions (velocities >0.5-0.8mm/yr). The southern Adria crustal block shows minimal to no lateral motions in the W-part and a clear NE-directed motion that is progressively increasing towards the E. This motion can be correlated with the so-called counter-clockwise rotation of the Adriatic plate. North of aforementioned domain, N- to NW-directed movements dominate but velocities decrease progressively from the central Alpine domains (<0.3-0.5mm/yr) towards southern Germany, where they are generally small (<0.3-0.4mm NE-CH). This variability between southern and central/northern Switzerland as well as that from E to W, respectively, is accommodated by NE-SW (Rhone-Simplon system) and N-S oriented strike-slip systems. (ii) Most substantial vertical uplift occurs in a WSW-ENE oriented central Alpine belt ranging from the Valais to the Grisons. Note that absolute values of this vertical uplift are 2-3 times larger compared to horizontal movements in the corresponding domains. Focal mechanisms in this high uplift belt indicate orogen-parallel NE-SW extension mainly in the S-Valais and Grisons accommodated by active normal faulting S of the Penninic front. Uplift rates gradually decrease towards the N- and S-Alpine foreland as well as towards Austria and France. Data even suggest tendencies of subsidence at very low rates in the Bresse graben, Upper Rhine graben as well as somewhat more pronounced ones in the eastern Po-plane but not in the CH-Molasse basin. Parts of the northern Alpine foreland exhibit upper to lower crustal seismic activity, while in the thick-crustal-root-enhanced high uplift domains upper crustal seismicity dominates and earthquakes below 20km depth do not occur.

Overall recent surface movements and seismicity in and along Central Alpine crustal blocks are affected by buoyancy-driven vertical combined with transpressional/-tensional horizontal movements indicating a lithosphere-scale geodynamic forcing. 

How to cite: Herwegh, M., Mock, S., Diehl, T., Brockmann, E., Truttmann, S., Kissling, E., Kurmann-Matzenauer, E., Wiemer, S., and Möri, A.: Seismotectonics in the Central Alps: An attempt to link fault structures, seismic activity and recent crustal movements, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4420, https://doi.org/10.5194/egusphere-egu22-4420, 2022.

EGU22-4500 | Presentations | GD8.4

Controls on along-strike variations of basin development: a case study of the Northern Alpine Foreland Basin 

Lucas Eskens, Nevena Andrić-Tomašević, Peter M. Süss, Todd A. Ehlers, Rolf Herrmann, and Matthias Müller

The Northern Alpine Foreland Basin developed in response to the collision between the European and Adriatic plates. During the Oligocene-Early Miocene coeval along-strike deposition of terrestrial and deep marine conditions are recorded in the western and eastern parts of the basin respectively. However, the mechanisms driving the observed variability in along-strike development of the basin are still poorly understood.

To study the causes of the observed along-strike variability we review published geological data and (re)interpret available 2D and 3D seismic data, constrained by well data. We interpret (1) seismic facies, (2) stratigraphic surfaces and (3) tectonic structures. Our current focus area covers the transitional zone between the western and eastern parts of the basin.

In our study we distinguish 6 stratigraphic surfaces from the Base Tertiary to the Top Aquitanian. From Upper Swabia to the German-Austrian border (along the basin strike) we observe that the top of the crystalline basement is tilted towards the east with an angle of 2-3°. Furthermore, the base of the Tertiary deposits is also tilted towards the east with an angle of 0.3°. The main structural features are E-W and NW-SE striking normal faults. In the western part of our study area the normal faults cut the crystalline basement, Mesozoic and Oligocene deposits. The faults are sealed by Rupelian deposits. Thickness changes (~20 m) occur in Rupelian and overlying Chattian deposits. Maximum offsets of up to 60 m are observed for Mesozoic reflectors. In the eastern part of our study area the normal faults cut the crystalline basement, Mesozoic, Oligocene and Early Miocene deposits. Thickness changes across these faults indicate fault activity during the Rupelian, Chattian and Aquitanian. Maximum offsets (>150 m) are observed for Chattian reflectors. Upper Aquitanian deposits seal these faults, which is younger than observed in the western part of the study area. The NW-SE striking faults confine Paleozoic grabens within the crystalline basement.

We relate the observed normal faulting of the Oligocene and Early Miocene deposits to flexural downbending of the European plate, assumed to have been caused by tectonic loading of the Alps and/or European slab pull. Furthermore, we suggest that the observed temporal variation in termination of fault activity is related to temporal and spatial variations in tectonic loading of the Alps and/or European slab pull. Finally, based on the observed eastward tilt of the top crystalline basement and Base Tertiary along the basin strike, variations in pre-existing crustal architecture must be considered.

How to cite: Eskens, L., Andrić-Tomašević, N., Süss, P. M., Ehlers, T. A., Herrmann, R., and Müller, M.: Controls on along-strike variations of basin development: a case study of the Northern Alpine Foreland Basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4500, https://doi.org/10.5194/egusphere-egu22-4500, 2022.

EGU22-4501 | Presentations | GD8.4

High-resolution deformation maps from the Southern-Eastern Alps compiled from 5-yr-long radar interferometric time-series 

Sabrina Metzger, Milan Lacecký, and Najibullah Kakar

Entering the terminal phase of continental collision, the European Alps exhibit surface deformation rates at the mm-level. Uplift peaks in the Central Alps at 2-3 mm/yr as a result of the post-glacial isostatic rebound, slab tearing, and erosion. Horizontal rate changes of <2 mm/yr are observed in the Southern-Eastern Alps due to the anticlockwise rotation of the Adriatic lithosphere. Here, N–S shortening is primarily accommodated at the densely-populated foothills of the Southern Alps, where seismicity is abundant and includes M6+ earthquakes like the devastating Mw6.5 Friuli earthquake in 1975. Further north and beyond the ESE-trending, dextral Periadriatic fault, the Eastern Alps extrude into the Pannonian basin. Today’s fault slip rates are constrained by Global Navigation Satellite System (GNSS) data with an inter-station distance too sparse to provide a detailed insight into plate locking—a vital component of estimating the fault’s seismic potential.

We present 4D-deformation data of the SE-Alps in unprecedented resolution (~400 m, 6 days). The rate maps were derived from radar-interferometric time-series collected since 2017 by the European Sentinel-1 satellites. Each of the assembled 240-km-wide radar tiles consists of 300+ images. The interferograms were automatically generated, phase-unwrapped, and corrected for atmospheric and topographic signal contributions. We estimated the deformation rates using the LiCSBAS time-series analysis software that involves a small-baseline approach and accounts for spatio-temporal coherence and seasonality. By tying the individual, relative InSAR rates—observed in two look directions—into a Eurasian reference frame based on by published GNSS rates we decompose them into east and vertical rates.

Our results illuminate the extreme, to which we can push the InSAR signal-detection threshold if the signal-backscatter properties are as challenging as in the vegetated SE-Alps: The predominant, vertical rates result from a mixture of isostatic, tectonic and anthropogenic processes, overlaid by a soil-moisture bias; the horizontal shortening rates align northwards, to which the radar satellites is least sensitive. Nevertheless, our rates provide new, dense deformation data and highlight processes yet undetected by the GNSS monitoring network.

How to cite: Metzger, S., Lacecký, M., and Kakar, N.: High-resolution deformation maps from the Southern-Eastern Alps compiled from 5-yr-long radar interferometric time-series, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4501, https://doi.org/10.5194/egusphere-egu22-4501, 2022.

EGU22-6582 | Presentations | GD8.4

The AlpArray Seismicity Catalog 

Matteo Bagagli, Irene Molinari, Tobias Diehl, Edi Kissling, and Domenico Giardini

Exploiting the new large seismic data set provided by the AlpArray Seismic Network (AASN) as part of the AlpArray research initiative (www.alparray.ethz.ch), we provide a highly consistent seismicity catalog with precise hypocenter locations and uniform magnitude calculations across the greater Alpine region (GAR) covering the period from 1st January 2016 to 31st December 2019.

With a backbone of 715 broadband seismic stations (415 permanent, 300 temporary) and a uniform interstation distance of ~50 km, the AASN provides a unique opportunity to assess the laterally heterogeneous GAR seismicity distribution. Regularly, the GAR seismicity is monitored and reported by a dozen national and international observatories, requiring a challenging effort to create a uniform and reliable catalog to document and investigate the complex seismicity and tectonics of the GAR.

To establish the highly consistent AlpArray Seismicity Catalog (AASC), we developed a new multi-step, semi-automated method. We applied the SeisComP3 (SC3) seismic-monitoring software and run it in playback mode to analyze the ~50 Tb of continuous data collected in 4 years for initial events detection and to calculate their hypocenter locations. We cleaned this preliminary, automatic seismic catalog from fake events and from events with an initial magnitude less than 2.0 MLv. We then made use of two additional software packages to refine phase picks and locations: the new ADAptive Picking Toolbox (ADAPT) Python library and the VELEST algorithm. The former was used to develop a new multi-picking algorithm for phase identification and precise arrival time determination. The latter was used to obtain the most reliable earthquakes locations, their quantitative error estimation and to reliably predict phase arrivals by solving the coupled hypocenter-velocity problem using the powerful joint-hypocenter determination technique (JHD). The JHD approach was also implemented as a filtering tool for outlier observations and to detect problematic events.

We eventually recalculate the local magnitude (MLv) in a consistent and uniform way, obtaining a statistical magnitude of completeness of 2.4 MLv with different catalog-based techniques. The AASC is also regionally consistent up to 3.0 M+  with seismic bulletins provided by national and international agencies.

Our final 4-year catalog contains 3293 precisely located earthquakes with magnitudes ranging between 0.4 - 4.9 MLv and it clearly delineates the major seismically active fault systems within the GAR. We additionally provide a new minimum 1D P-velocity model for the GAR and appropriate station delays, for both temporary and all permanent stations. These station delays for the permanent seismic station arrays, together with the velocity model, are key to consistently link the GAR past and future seismicity with our current catalog. This would allow the compilation of a broader consistent seismic catalog suitable for other seismological studies including, but not limited to, seismic hazard and a regional 3D local earthquake tomography.

How to cite: Bagagli, M., Molinari, I., Diehl, T., Kissling, E., and Giardini, D.: The AlpArray Seismicity Catalog, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6582, https://doi.org/10.5194/egusphere-egu22-6582, 2022.

EGU22-7246 | Presentations | GD8.4

Status and Implementation of the AdriaArray Seismic Network 

Petr Kolínský, Thomas Meier, and the AdriaArray Seismic Network Working Group

With the advent of plate tectonics in the last century, our understanding of the geological evolution of the Earth system improved essentially. The internal deformation and evolution of tectonic plates remain however poorly understood. This holds in particular for the Central Mediterranean: The formerly much larger Adriatic plate is recently consumed in tectonically active belts spanning at its western margin from Sicily, over the Apennines to the Alps and at its eastern margin from the Hellenides, Dinarides towards the Alps. High seismicity along these belts indicates ongoing lithospheric deformation. It has been shown that data acquired by dense, regional networks like AlpArray provide crucial information on seismically active faults as well as on the structure and deformation of the lithosphere. The Adriatic Plate and in particular its eastern margin have however not been covered by a homogeneous seismic network yet.

Here we report on the status and preparation of AdriaArray – a seismic experiment to cover the Adriatic Plate and its actively deforming margins by a dense broad-band seismic network. Within the AdriaArray region, currently about 950 permanent broad-band stations are operated by more than 40 institutions. Data of 90% of these stations are currently available via EIDA. In addition to the existing stations, 385 temporary stations from 18 mobile pools are to be deployed in the region to achieve a coverage with an average station distance of about 50 – 55 km. The experiment will be based on intense cooperation between network operators, ORFEUS, and interested research groups. Altogether, more than 50 institutions will participate in the AdriaArray experiment. We will introduce the time schedule, participating institutions, mobile station pools, maps of suggested temporary station distribution with station coverage and main points of the agreed Memorandum of Collaboration. The AdriaArray experiment will lead to a significant improvement of our understanding of the geodynamic causes of plate deformation and associated geohazards.

How to cite: Kolínský, P., Meier, T., and Seismic Network Working Group, T. A.: Status and Implementation of the AdriaArray Seismic Network, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7246, https://doi.org/10.5194/egusphere-egu22-7246, 2022.

EGU22-7333 | Presentations | GD8.4

Towards a high-resolution vS crustal velocity model for the Ivrea Geophysical Body: constraints from seismic ambient noise tomography 

Matteo Scarponi, Jiri Kvapil, Ludek Vecsey, Jaroslava Plomerová, IvreaArray Working Group, and AlpArray Working Group

The arc of the Western Alps is characterized by a complex crustal structure. Lower-to-middle crustal composition outcrops are exposed in the Ivrea-Verbano Zone (IVZ) and a major crustal anomaly, known as Ivrea Geophysical Body (IGB), presents dense and seismically fast rocks right below the surface. Understanding better their relation provides a key to refine our understanding of orogeny formation mechanisms.

We performed seismic ambient noise tomography using data from the IvreaArray and the AlpArray Seismic Network, selected within a radius of ca. 100 km around the study area. Previous seismic investigations provided knowledge on the crustal structure in the Western Alps, by means of active refraction seismics and of more recent local earthquake and ambient noise tomography at regional scales (e.g. Solarino et al. 2018 Lithos, Lu et al. 2018 GJI). Recently, gravity data and receiver function analysis imaged the IGB as a dense and fast seismic anomaly, related to upper mantle material, reaching up to few km depth below sea level (Scarponi et al. 2021 Frontiers). However, local high-resolution constraints on the absolute vS distribution remain unknown.

We used raw summer seismic data (June to September) across 3 years of recording, and computed daily ambient noise cross-correlation traces, for all the available station pairs (61 stations in total) in the 2-20s period range. Daily cross-correlations were stacked and processed to extract Green’s functions. Subsequently, we performed frequency-time analysis to get group velocity dispersions for the fundamental mode of surface Rayleigh waves. We computed 2D surface group velocity maps at each period, which clearly show the slow sediment area of the Po Plain, and the fast IGB structure within the crust.

We are going to use the 2D group velocity maps to derive local dispersions curves and invert for 1D vS-depth profiles with the use of the Neighborhood Algorithm, to produce a 3D vS velocity model for the IVZ at high-resolution. This will also provide new geophysical constraints in the target area of the scientific drilling project DIVE (www.dive2ivrea.org) and reliable information for crustal corrections, which are necessary for upper mantle studies in such a complex area.

How to cite: Scarponi, M., Kvapil, J., Vecsey, L., Plomerová, J., Working Group, I., and Working Group, A.: Towards a high-resolution vS crustal velocity model for the Ivrea Geophysical Body: constraints from seismic ambient noise tomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7333, https://doi.org/10.5194/egusphere-egu22-7333, 2022.

EGU22-7433 | Presentations | GD8.4

Thermo-kinematic evolution of the Eastern Alps along TRANSALP: Exploring the transient tectonic state towards slab reversal 

Paul Eizenhöfer, Christoph Glotzbach, Jonas Kley, and Todd Ehlers

The Eastern Alps are shaped by the indentation of Adria into Europe and exhibit a doubly-vergent lithospheric wedge geometry. Immediately after the subduction of the Penninic ocean, pro- and retro-wedges have been established in the European and Adriatic plates, respectively. Recent tomographic studies, depicting several detached slab fragments beneath the Alps, have been interpreted as evidence of continuous southward subduction, contrary to an often-invoked subduction polarity reversal. Systematic changes in orogen-scale exhumation, driven by rock displacement along active faults, should reflect such change in subduction polarity. Low temperature thermochronology can evaluate upper lithospheric cooling as a response to changes in tectonic and/or erosional boundary conditions. This study investigates whether a potential change in locations of the pro- and retro-wedges is reconcilable with observed crustal re-organisations, exhumation patterns and mantle tomography. A suite of thermo-kinematic forward models driven by a new 2D structural-kinematic reconstruction of continental collision along the TRANSALP profile in the Eastern Alps has been subject to systematic sensitivity analyses encompassing variations in shortening rates, thermophysical parameters and topographic evolution, supplemented by new apatite and zircon fission-track data. Results from the thermo-kinematic modelling reproduce: (i) the orogen-scale structural geometry, (ii) the distribution of low-temperature thermochronometer ages, (iii) independently determined time-temperature paths, and (vi) the present-day surface heat flux. We suggest that the observed thermochronologic record along the TRANSALP profile is primarily driven by cooling through rock displacement along active faults. Our thermo-kinematic reconstruction emphasises a systematic southward shift of deformation, in particular in the Southern Alps, since onset of motion along the Tauern Ramp. Interpreting both, the Tauern Ramp as a mega retro-thrust and the southward shift of deformation in the Southern Alps, as a response to new Coulomb-wedge criterions, then our results are consistent with a Mid-Miocene reversal of continental subduction polarity. This time frame is compatible with a detachment of the European slab and a tectonic re-organisation of the Eastern Alps since ~10-25 Ma.   

How to cite: Eizenhöfer, P., Glotzbach, C., Kley, J., and Ehlers, T.: Thermo-kinematic evolution of the Eastern Alps along TRANSALP: Exploring the transient tectonic state towards slab reversal, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7433, https://doi.org/10.5194/egusphere-egu22-7433, 2022.

EGU22-7455 | Presentations | GD8.4

Anisotropy of the Bohemian Massif lower crust from ANT - VTI model or additional azimuthal variations? 

Jiří Kvapil, Jaroslava Plomerová, Hana Kampfová Exnerová, and the AlpArray Working Group

Transversely isotropic lower crust of the Bohemian Massif (BM) has been revealed by an ambient noise tomography (ANT) of the BM (Kvapil et al., Solid Earth 2021). The significant feature of this 3D vSV model is the low velocity layer in the lower part of the crust at depth between 18-30 km and the Moho. The upper interface is characterized by a velocity drop in the 1D velocity models retrieved by the ANT. The interface is interrupted around boundaries of major tectonic units of the BM. The lower interface (Moho) exhibits a sharp velocity increase at 26-40km depths through the massif.

In this work we test whether we are able to detect azimuthal anisotropy in the lower crust, approximated up to now by anisotropic VTI model. We use Rayleigh wave dispersion curves evaluated from station pairs sampling the BM in the period range sensitive to the lower crust. First, we analyze seasonal variations of noise sources and their effect on quality and repeatability of dispersion curve measurements. Then we remove the effect of local heterogeneities by subtraction of synthetic dispersion curves calculated for the 3D vSV model along each station-pair raypath. Retrieved variations of azimuthal anisotropy are period-dependent with the fast velocity directions around NE-SW. We interpret the lower crust anisotropy layer as an imprint of the Variscan orogenic processes such as the NW-SE shortening of the crust and the late-Variscan strike-slip movements along boundaries of the crustal unit recorded in the interruptions of velocity drop interface in zones where anisotropic fabric of the lower crust was modified or erased.

How to cite: Kvapil, J., Plomerová, J., Kampfová Exnerová, H., and Working Group, T. A.: Anisotropy of the Bohemian Massif lower crust from ANT - VTI model or additional azimuthal variations?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7455, https://doi.org/10.5194/egusphere-egu22-7455, 2022.

EGU22-7660 | Presentations | GD8.4

Identifying Seismic Anisotropy Patterns and Improving Tomographic Images in the Alps and Apennines Subduction Environments with Splitting Intensity 

Judith M. Confal, Silvia Pondrelli, Paola Baccheschi, Manuele Faccenda, Simone Salimbeni, and the AlpArray Working Group

Active and past subduction systems influence the interpretation and understanding of current tectonics and velocity structures of the upper mantle of the Alps and Apennines. Computational advances over the years made it possible to identify remnant and active slabs up to great depths. SKS splitting measurements revealed mostly clockwise rotation in the Alpine region and mostly splitting parameters parallel to the Apennines (with new measurements in Central Italy). More than 700 stations were used in this study to calculate splitting intensities and with those similar but more stable fast polarization directions were recovered compared to SKS measurements. Splitting intensity measurements support a possible mantle material flowing through a tear in the Central Apennines. In the Po Plain region as well as east of the Apennine mountains anisotropy seems to be weaker. Moreover the complexity of layered anisotropy, upper mantle flow through possible slab detachments, and subduction related anisotropy with a dipping axis of symmetry are difficult to recover. Due to directional dependency of splitting intensity measurements, they can be used in tomographic inversions to get depth dependent horizontal anisotropy. So far we are able to recover the most prominent splitting patterns and see some changes with depth, especially for anisotropic strength. In this study we intend to use our results to improve tomographic images of the upper mantle by mapping and comparing existing and new anisotropy measurements (e.g., SKS, Pn anisotropy, azimuthal anisotropy from surface waves tomography, and splitting intensities).

How to cite: Confal, J. M., Pondrelli, S., Baccheschi, P., Faccenda, M., Salimbeni, S., and AlpArray Working Group, T.: Identifying Seismic Anisotropy Patterns and Improving Tomographic Images in the Alps and Apennines Subduction Environments with Splitting Intensity, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7660, https://doi.org/10.5194/egusphere-egu22-7660, 2022.

EGU22-7800 | Presentations | GD8.4

Towards a comprehensive High Resolution 3D P- and S-Wave Velocity Model for the Alpine Mountain Chain using Local Earthquake Data 

Benedikt Braszus, Andreas Rietbrock, and Christian Haberland

Seismic data availability and automated picking algorithms drastically improved in the European Alps since the last orogen wide crustal P-wave velocity model was compiled by Diehl et al. (2009). Especially, the abundant seismic data recorded by the AlpArray Seimic Network (AASN) which was in operation from 2015-2021 provides a unique high resolution seismic data set. The aim of our project therefore is to create a comprehensive 3D P- and S-wave crustal velocity model for the European Alpine region using Local Earthquake Tomography (LET). Such a model is not only needed to sharpen high resolution teleseismic tomography studies imaging subducted slabs but also to relate surface structures to mountain building processes in the mantle.
To achieve this aim precise onset times of seismic crustal phases are needed. Here we show our first results of automatic onset time determination obtained through the deep-neural-network PhaseNet. When compared to catalogues of manual travel time picks, we find its performance as accurate as a human analyst's. This confirms the transferability of machine learning approaches to our area and data set.
The large amount of evenly distributed seismic stations yields up to a total of 720 P and S arrival picks with epicentral distances up to 700km for events with ML > 3.5. Earthquakes with magnitudes of ML=2.5 are generally detectable for epicentral distances up to at least 200km and contribute approximately 200-300 arrivals per event.
As a first step towards a 3D model we present a thorough analysis of the consistency of the automatically determined arrival times, which facilitates a reliable removal of outliers. 
Furthermore, we show visualizations of our preliminary tomography model and its resolution.

How to cite: Braszus, B., Rietbrock, A., and Haberland, C.: Towards a comprehensive High Resolution 3D P- and S-Wave Velocity Model for the Alpine Mountain Chain using Local Earthquake Data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7800, https://doi.org/10.5194/egusphere-egu22-7800, 2022.

EGU22-7892 | Presentations | GD8.4

Crustal and upper mantle 3D Vs structure of the Pannonian Region from joint earthquake and ambient noise Rayleigh wave tomography 

Máté Timkó, Amr El-Sharkawy, Lars Wiesenberg, László Fodor, Zoltán Wéber, Sergei Lebedev, and Thomas Meier and the AlpArray Working Group

The Pannonian basin is a continental back-arc basin in Central Europe, surrounded by the Alpine, Carpathian, and Dinaric mountain ranges. To better understand this area's tectonic affinity and evolution, a high-resolution model of the crust, the mantle lithosphere, and the asthenosphere is essential. The region's crustal structures are well documented, e.g., classical active seismic, receiver functions, and ambient noise surface wave studies, but consistent imaging of the entire lithosphere remains a challenge. Here we present a new high-resolution 3D shear wave velocity model of the crust and upper mantle of the broader Pannonian region using joint tomographic inversion of ambient noise and earthquake data.

For this purpose, we collected continuous waveform data from more than 1280 seismic stations for ambient noise cross-correlation measurements from a region centered to the Pannonian Basin and encompassing the rimming orogenic chains. This dataset embraces all the permanent and temporary stations operated in the time period from 2005 to 2018. We calculated Rayleigh wave ambient noise phase velocity dispersion curves using the phase of the noise cross-correlation functions of the vertical components in the period range from 5 to 80 s. Then we combined this dataset with existing measurements from earthquake data in the period range of 8-300 s.

At lower periods (< 50 s) and shorter interstation distances, there is a well-documented systematic discrepancy between the dispersion measurements collected by the two methods. The phase-velocity curves measured by the noise-based method are slower on average than the dispersion curves extracted by the earthquake-based method. A correction term is defined by comparing phase velocity curves from both data sets for the same station pairs. Phase velocity maps are then calculated from 5 s to 250 s periods using ambient noise and earthquake measurements.

Local dispersion curves extracted along each grid node of the 2D phase velocity maps are inverted for depth velocity models using a newly implemented Particle Swarm Optimization (PSO) algorithm to obtain the 3D distribution of the shear-wave velocities. The shear wave velocity structure reveals pronounced variations of the lithospheric thickness and physical properties related to deep tectonic mechanisms operated in the region.

How to cite: Timkó, M., El-Sharkawy, A., Wiesenberg, L., Fodor, L., Wéber, Z., Lebedev, S., and Meier, T. and the AlpArray Working Group: Crustal and upper mantle 3D Vs structure of the Pannonian Region from joint earthquake and ambient noise Rayleigh wave tomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7892, https://doi.org/10.5194/egusphere-egu22-7892, 2022.

EGU22-7932 | Presentations | GD8.4

Seismic properties profiles of the alpine slab predicted by petrophysics versus ambient noise tomography lithospheric model 

Manon Sonnet, Loïc Labrousse, Jérôme Bascou, Alexis Plunder, Ahmed Nouibat, Laurent Stehly, and Anne Paul

The objective of the present study is to use potential lithologic analogues sampled in the European crust units exhumed in the Alps to predict the seismic properties of the buried continental crust panel. To this end, from the chemical compositions of representative rock samples, we calculate seismic velocities (Vp, Vs or Vp/Vs) at any P and T, under the assumption that the rocks have completely re-equilibrated during burial.

The sample catalog comprehend (1) the mafic intercalations, present in the Variscan basement series of the External Crystalline Massif; (2) the rocks involved in the Grand Paradis - Schistes Lustrés contact (metabasites and garnet bearing micaschists of the upper unit, mylonite and gneiss of the lower unit); (3) those along the Lanzo-Canavese contact (serpentinites, blue schist facies mylonites and biotite bearing gneiss); (4) lithologies of the Ivrea domain (peridotites, garnet bearing gabbros, textured mafic rocks, amphibolitic and mylonitic paragneiss), (5) those from the Gruf massif (biotite bearing orthogneiss, deformed leucogranites and charnockites from the Gruf complex and amphibolites and serpentinites from the Chiavenna unit); (6) lithologies from Alpine Corsica (pelitic gneisses of the granulite facies and more or less foliated metagabbros, from the San Petrone and Farinole unit).

In these diagrams, the main seismic contrasts appear to correspond to the early stages of jadeite crystallization (mainly in the Vp/Vs diagram), as well as to the boundaries of the garnet and clinopyroxene stability fields. Considering the selected rocks as relevant analogues, we then compare the evolution of seismic properties along the top of the Alpine dipping panel with profiles inferred from recent Vp and Vs tomography models (CIFALPS 1 and AlpARRAY), varying the effective thermal profile of the Alpine panel, its reaction degree and overall chemistry. Preliminary results suggest that the lower crust of the plunging panel has a seismic velocity too low to be eclogitized. Its velocity rates are closer to those of an underreacted quartzo-felspathic gneiss. At first sight, observed velocities are too low compared to values predicted for any lithology fully reacted during subduction. The best-fitting scenario turns out to be that of a lower crust thermally relaxed in the variscan without significant mineralogical footprint of subduction. If detected, the velocity rise due to eclogitization might offset of several tenth along the slab, implying a sensible impact of reaction kinetics.

How to cite: Sonnet, M., Labrousse, L., Bascou, J., Plunder, A., Nouibat, A., Stehly, L., and Paul, A.: Seismic properties profiles of the alpine slab predicted by petrophysics versus ambient noise tomography lithospheric model, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7932, https://doi.org/10.5194/egusphere-egu22-7932, 2022.

EGU22-8102 | Presentations | GD8.4

3D anisotropic P-wave tomography of the Central Mediterranean: new insights into slab geometry and upper mantle flow patterns 

Francesco Rappisi, Brandon Paul VanderBeek, Manuele Faccenda, Andrea Morelli, and Irene Molinari

Characterized by the coexistence of different compressional and extensional phases associated with episodes of orogenesis, slab rollback, slab tearing and oceanic spreading, the Central Mediterranean represents one of the most interesting convergent margin on Earth. Since the late 1990s, several seismologists have studied this region aiming at imagining the isotropic and anisotropic structures below its surface. Although numerous researchers have demonstrated that performing P-wave tomography neglecting seismic anisotropy can introduce significant imaging artefacts, prior tomographic studies have largely assumed an isotropic Earth. Using the method proposed by VanderBeek & Faccenda (2021), here we discard the isotropic approximation and invert for both P-wave isotropic velocity anomalies and seismic anisotropy and present the first 3D anisotropic P-wave tomography of the upper mantle covering the entire Central Mediterranean. Our results show that inverting for seismic anisotropy strongly reduces the magnitude of the isotropic P-wave anomalies. This suggests that lateral variations in temperature and/or composition are smaller that what can be inferred from purely isotropic tomographies. P-wave fast azimuths orient mostly parallel to the trend of the Balcanic and the Alpine orogens in Eastern and Central Europe, respectively. In the Central Mediterranean the P-wave fast azimuths are sub-parallel to the Oligocene/Miocene-to-present retreating direction of the Ionian trench which led to the opening of the Liguro-Provençal and Thyrrenian basins and rotation of the Corsica-Sardinia block. We find that the pattern of the P-wave fast azimuths is largely consistent with the S-wave fast azimuths determined from the splitting of SKS waves and from Rayleigh waves. This poses further constraints on the interpretation of the regional geodynamic evolution and on the accuracy of the employed inverse method.

References:

VanderBeek, B. P., & Faccenda, M. 2021. Imaging upper mantle anisotropy with teleseismic P-wave delays: insights from tomographic reconstructions of subduction simulations. Geophysical Journal International,225(3), 2097–2119.

How to cite: Rappisi, F., VanderBeek, B. P., Faccenda, M., Morelli, A., and Molinari, I.: 3D anisotropic P-wave tomography of the Central Mediterranean: new insights into slab geometry and upper mantle flow patterns, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8102, https://doi.org/10.5194/egusphere-egu22-8102, 2022.

EGU22-8174 | Presentations | GD8.4

Moho depths beneath the European Alps from receiver functions of the AlpArray Seismic Network 

Konstantinos Michailos, Matteo Scarponi, Josip Stipčević, György Hetényi, Katrin Hannemann, Dániel Kalmár, Stefan Mroczek, Anne Paul,  Jaroslava Plomerová, Frederik Tilmann, Jerôme Vergne, and the AlpArray Receiver Function Research Group AlpArray Working Group

The European Alps, formed by the interactions between the European and Adriatic plates, is a unique geological structure that has been extensively studied over the past decades. Despite numerous active and passive seismic investigations in the past, the crustal structure across the whole Alpine domain is somehow limited - mainly due to the limited number of seismometers available. The deployment of the AlpArray Seismic Network provides, which consisted of around 600 broadband seismometers and was operational from early 2016 till mid-2019, offers a unique opportunity to further update the current knowledge of the crustal structure beneath the European Alps by employing Receiver function (RF) analysis. 

RF method can provide an efficient way to image the structures and the discontinuities within the uppermost part of the Earth. We use teleseismic earthquakes with M≥5.5 and M<8.5 and epicentral distances ranging between 30 and 90 degrees that occurred during the operational time of the AlpArray Seismic Network. We compute RFs using a time-domain iterative deconvolution method. We apply quality control steps to both the original three-component waveforms and the calculated RFs to ensure that we only use high-quality signals. 

As of abstract submission, we are in the process of calculating the RFs. We also intend to perform a time to depth migration, in a 3D spherical coordinate system, to the RFs. This methodology, together with unprecedented data coverage, will provide us with migrated profiles that will image the structure of the crust and map the Moho depths at a great level of detail. 

How to cite: Michailos, K., Scarponi, M., Stipčević, J., Hetényi, G., Hannemann, K., Kalmár, D., Mroczek, S., Paul, A., Plomerová,  ., Tilmann, F., Vergne, J., and AlpArray Working Group, T. A. R. F. R. G.: Moho depths beneath the European Alps from receiver functions of the AlpArray Seismic Network, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8174, https://doi.org/10.5194/egusphere-egu22-8174, 2022.

EGU22-8725 | Presentations | GD8.4

The DIVEnet: a local seismographic network monitoring the lower continental crust drillings for the ICDP-DIVE project 

Silvia Pondrelli, György Hetényi, Simone Salimbeni, Adriano Cavaliere, Stefania Danesi, Emanuela Ercolani, Irene Molinari, Carlo Giunchi, Konstantinos Michailos, Claudia Piromallo, Lucia Zaccarelli, Giovanna Cultrera, Rocco Cogliano, Gaetano Riccio, and Alberto Zanetti

The ICDP DIVE project (www.dive2ivrea.org) is aimed at addressing fundamental questions on the nature of the lower continental crust and its transition to the mantle, in a first phase through two drillings in the Ivrea Verbano zone (IVZ). The IVZ, considered the world's best outcrop of lower crustal continental rocks, is the exposed part of the Ivrea Geophysical Body (IGB), a major high gravity and high seismic velocity anomaly studied since the 1960s and strongly related to Western Alps structural and tectonic history. Beneath the IVZ the Moho possibly reaches very shallow depth (locally ~1±1 km b.s.l.), making this site unique all over the World.

The two proposed drillings will start in the 2022 in Val D’Ossola: the first in Ornavasso and the second in Megolo, 7 km apart from each other. The assemblage of the two will constitute the most complete record of lower continental crust. Physical and chemical data systematically collected downhole as well as along drill cores will be combined and compared with local/regional geophysical and geological surveys. Within this frame and scope, a dedicated seismographic network named DIVEnet has been planned to monitor local earthquakes and operation-related seismic activity.

Starting from summer 2021 the survey and seismic station deployment started to have all stations running by January 2022. So far 10 seismographic stations provided by INGV and University of Lausanne have been installed within a 15 km maximum distance from the mid-point between the two drilling sites and recording in continuous mode (100 sps). One of the seismometers will be housed in the first completed borehole while the second one is being drilled. Given that the area is characterized by low natural local seismicity and low seismic stations density, having a long time record of background activity and background noise, including the period before and after the drilling activities’ initiation, is of crucial importance. The acquisition and first elaboration of seismic data have been actively included in the routine work at INGV.

How to cite: Pondrelli, S., Hetényi, G., Salimbeni, S., Cavaliere, A., Danesi, S., Ercolani, E., Molinari, I., Giunchi, C., Michailos, K., Piromallo, C., Zaccarelli, L., Cultrera, G., Cogliano, R., Riccio, G., and Zanetti, A.: The DIVEnet: a local seismographic network monitoring the lower continental crust drillings for the ICDP-DIVE project, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8725, https://doi.org/10.5194/egusphere-egu22-8725, 2022.

EGU22-8790 | Presentations | GD8.4

Establishing the eastern alpine-dinaric transition with teleseismic receiver functions: Evidence for subducted European Crust 

Stefan Mroczek, Frederik Tilmann, Jan Pleuger, Xiaohui Yuan, and Ben Heit and the SWATH-D and AlpArray Working Groups

The dense SWATH-D seismic network in the Central-Eastern Alps gives an unprecedented window into the collision of the Adriatic and European plates. We apply the receiver function method to the SWATH-D stations, covering approximately the area from 45-49°N and 10-15°E, supplemented by the AlpArray Seismic Network and the EASI data. A switch in the subduction polarity between the Central Alps (European subduction) and the Dinarides (Adriatic subduction) had been previously suggested to occur below the Eastern Alps but its location and nature are heavily debated. To probe this hypothesis we produce a high resolution Moho map of the Eastern Alps and derive Moho depths from joint analysis of receiver function images of direct conversions and multiple reflections, which enables us to map overlapping discontinuities. Contrary to the hypothesis suggesting the subduction of Adriatic lithosphere in the Eastern Alps, we observe the European Moho to be underlying the Adriatic Moho up to the eastern edge of the Tauern Window (~13.5°E). East of this longitude, a sharp transition from underthrusting European to a flat and thinned crust associated with Pannonian extension tectonics occurs, which is underthrust by both European crust in the north and by Adriatic crust in the south. The northeast-directed underthrusting of Adriatic lithosphere smoothly transitions to subduction below the northwestern Dinarides.

Teleseismic tomography and receiver functions show different aspects of the same system (velocity anomalies versus velocity gradients) making direct comparisons difficult. The common conversion point stacks and Moho picks show good agreement with the tomography however some key differences remain. In particular, teleseismic tomography indicates high velocity anomalies detached from the crust east of ~13°E while receiver functions, in particular the transverse component, show some evidence for connection with a continuous interface going to depth.

How to cite: Mroczek, S., Tilmann, F., Pleuger, J., Yuan, X., and Heit, B. and the SWATH-D and AlpArray Working Groups: Establishing the eastern alpine-dinaric transition with teleseismic receiver functions: Evidence for subducted European Crust, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8790, https://doi.org/10.5194/egusphere-egu22-8790, 2022.

EGU22-9206 | Presentations | GD8.4

Present-day upper mantle structure of the Alps: insights from data-driven dynamic modelling 

Ajay Kumar, Mauro Cacace, Magdalena Scheck-Wenderoth, Judith Bott, Hans-Jürgen Götze, and Boris Kaus

Present-day surface deformation in the Central Alps, that is, uplift and upper-crustal level seismicity in contrast to its northern and southern forelands, has been attributed to surface (i.e., climatic) and tectonic processes (i.e., subduction, slab detachment/break-off, mantle flow). Understanding the relative contribution of these processes is fundamental to understanding their coupling and role in mountain building. The present-day 3D architecture of the lithosphere (i.e., lateral variations of crustal layers and lithospheric mantle thickness) and asthenosphere (i.e., subducted slabs, attached or detached to the orogenic lithosphere) resulting from tectonic processes operating at geologic time scale serve as a boundary condition to test the contribution of surface processes. While the crustal structure in the Alps is well constrained by seismic and gravity data, the upper mantle (i.e., lithospheric mantle and asthenosphere) structure differs from that due to the diversity and subjective interpretation of seismic tomography models. We convert the results of regional shear-wave seismic tomography models to temperature models using the Gibbs-free energy minimization algorithm to define the base of the lithosphere and the position of slabs in the asthenosphere. Our results show that the shallow/attached slab in the Northern Apennines is a common feature in different tomography models, but there are differences in the Alps area. We statistically cluster tomography models into three end-members corresponding to the mean and 67% confidence intervals to address these differences objectively. These end-members represent scenarios ranging from shallow/attached slabs to almost no slabs in the Northern Apennines and Alps. The three end-member scenarios are then used as an input to model the topography and velocities by solving the buoyancy-forces driven instantaneous flow, subject to the first-order rheological structure of the lithosphere-asthenosphere system. Modelled topography and velocities are compared to the first-order patterns of observed topography and GPS derived vertical velocities to discern among the end-member scenarios. Our preliminary results suggest that the lithospheric slab subducting beneath the Northern Apennines should be connected to the overlying lithosphere, whereas it appears to be detached along most of the Alps. The sensitivity of results to the viscosity structure of the crust, lithosphere, and asthenosphere will be discussed.  

How to cite: Kumar, A., Cacace, M., Scheck-Wenderoth, M., Bott, J., Götze, H.-J., and Kaus, B.: Present-day upper mantle structure of the Alps: insights from data-driven dynamic modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9206, https://doi.org/10.5194/egusphere-egu22-9206, 2022.

EGU22-9314 | Presentations | GD8.4

The Saint-Ursanne earthquakes of 2000 revisited: Evidence for active shallow thrust-faulting in the Jura fold-and-thrust belt 

Federica Lanza, Tobias Diehl, Nicholas Deichmann, Toni Kraft, Christophe Nussbaum, Senecio Schefer, and Stefan Wiemer

The interpretation of seismotectonic processes within the uppermost few kilometers of the Earth’s crust has proven challenging due to the often significant uncertainties in hypocenter locations and focal mechanisms of shallow seismicity. Here, we revisit the shallow seismic sequence of Saint-Ursanne of March and April 2000 and apply advanced seismological analyses to reduce these uncertainties. The sequence, consisting of five earthquakes of which the largest one reached a local magnitude (ML) of 3.2, occurred in the vicinity of two critical sites, the Mont Terri rock laboratory and Haute-Sorne, which is currently evaluated as a possible site for the development of a deep geothermal project. Template matching analysis for the period 2000-2021, including data from mini arrays installed in the region since 2014, suggests that the source of the 2000 sequence has not been persistently active ever since. Forward modelling of synthetic waveforms points to a very shallow source, between 0 and 1 km depth, and the focal mechanism analysis indicates a low-angle, NNW-dipping, thrust mechanism. These results combined with geological data suggest that the sequence is likely related to a backthrust fault located within the sedimentary cover and shed new light on the hosting lithology and source kinematics of the Saint-Ursanne sequence. Together with two other more recent shallow thrust faulting earthquakes near Grenchen and Neuchâtel in the north-central portion of the Jura fold-and-thrust belt (FTB), these new findings provide new insights into the present-day seismotectonic processes of the Jura FTB of northern Switzerland and suggest that the Jura FTB is still undergoing seismically active contraction at rates likely <0.5 mm/yr. The shallow focal depths provide indications that this low-rate contraction in the NE portion of the Jura FTB is at least partly accommodated within the sedimentary cover and possibly decoupled from the basement. This trenspressive regime is confirmed by the ML4.1 Réclère earthquake of December 24. 2021, which occurred ~20 kilometres west of St. Ursanne in the uppermost crust.

How to cite: Lanza, F., Diehl, T., Deichmann, N., Kraft, T., Nussbaum, C., Schefer, S., and Wiemer, S.: The Saint-Ursanne earthquakes of 2000 revisited: Evidence for active shallow thrust-faulting in the Jura fold-and-thrust belt, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9314, https://doi.org/10.5194/egusphere-egu22-9314, 2022.

EGU22-9691 | Presentations | GD8.4

The three-dimensional stress field around the margins of the Adriatic Plate derived from source mechanisms 

Elisabeth Glück, Thomas Meier, and Josip Stipcevic

At present time, the formerly much larger Adriatic Microplate is still actively being subducted beneath the Apennines and the Dinarides-Hellenides zone with continental collision and related processes occurring under the Alps and the Dinarides. These tectonic processes along with the large-scale component of the northward moving African Plate resulted in a complex 3D stress field.

In the light of the complex tectonic processes accompanying the movement of the Adriatic Plate, we aim to investigate the three-dimensional stress field in that area by stress inversion using focal mechanism data from the available CMT and RCMT earthquake catalogues. The focal mechanisms are inverted to better understand the stress regime in that region and how the stress pattern is depending on the current tectonic setting. A staggered grid algorithm was used for binning the focal mechanisms before the inversion.

The calculated 3D stress field indicates that the direction of the large-scale convergence of Africa and Eurasia is similar to the dominating direction of the maximum horizontal stress axis in the western central Mediterranean, with the exception of the Apennines, where the subduction of the Adriatic Plate beneath the northern Apennines is the primary source of stress. On the eastern margin of the Adriatic Plate the lack of deeper seismicity and a back arc basin, as well as the orogen normal orientation of the maximum horizontal stress axis in the Dinarides is pointing towards a continental subduction zone with an aseismic delaminating slab of lower lithosphere without a significant slab pull component.
Changes of the stress pattern within the Adriatic Plate may result from intraplate deformation, which points towards a fragmentation of Adria along the Mid Adriatic Ridge into two subplates, Adria Sensu Strictu in the north and Apulia in the south. While Adria Sensu Strictu is moving independently from Africa, Apulia is depending on the larger plates movement.
The inversion of the focal mechanisms from the Hellenic Subduction Zone yields results about the rotation of the stress field with depth, as the maximum horizontal stress rotates from trench normal at shallow depths to trench parallel deeper down.

How to cite: Glück, E., Meier, T., and Stipcevic, J.: The three-dimensional stress field around the margins of the Adriatic Plate derived from source mechanisms, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9691, https://doi.org/10.5194/egusphere-egu22-9691, 2022.

EGU22-11256 | Presentations | GD8.4

Revisiting moment tensors in Switzerland: Unraveling source characteristics in Central Alps and their foreland 

Maria Mesimeri, Tobias Diehl, John Clinton, Marco Herwegh, and Stefan Wiemer

Studies on moment tensors (MT) and focal mechanisms are of great importance for assessing regional and local seismotectonic processes, especially when a high-quality, dense network is in operation. However, common MT inversion methods are largely restricted to magnitudes > 3.5. In order to lower the completeness of MT catalogs, improved Green’s functions and/or hybrid inversion techniques are needed. In this study, we revisit small-to-moderate earthquakes, which occurred in Switzerland and surrounding regions by means of various MT inversion methods and assess the potential to improve completeness of MT catalogs in Central Alps region. To accomplish this, we implement state-of the art methods for MT inversion using either full waveform data or combinations of first-motion polarities with amplitudes and amplitude ratios. Methods based on full waveform inversion considered in this study are ISOLA (Sokos & Zahradnik 2013) and Grond (Heimann et al. 2018), as well as techniques based on amplitudes and/or polarities (HybridMT (Kwiatek et al. 2016), MTfit (Pugh & White 2018)), which can solve MTs for smaller magnitude earthquakes. Hence, the combination of multiple techniques allows to compute full or deviatoric MTs for a broader range of magnitudes and enrich the existing catalogs.

We first apply these methods to recent earthquake sequences occurred in the Central Alps between 2019 and 2021. During that period, several earthquake sequences, like the one associated with the 2021 M4.1 Arolla earthquake, occurred and show complexity on the waveforms, due to their shallow focal depths. In addition, several of the standard MT solutions calculated by the Swiss Seismological Service (SED) for these earthquakes indicate complex moment tensors with unusually high percentage of the CLVD component. To check whether such CLVD component is real and not an artifact caused, for instance, by unmodeled heterogeneities, we invert for full and deviatoric MTs using multiple 1D velocity models and algorithms. Additionally, we perform MT inversions for several earthquakes either within selected earthquake sequences or regional background seismicity. The resulting MT solutions are compared to existing high-quality focal mechanisms computed using first motion polarities as well as to high-precision double difference locations. Uncertainties of MT solutions are estimated using bootstrap-based methods. This work contributes towards an enriched high-quality focal mechanisms database for Switzerland, which could be used to revisit the regional to local stress field at unprecedented resolution and provides new insights into the complexities of active fault systems in the Central Alps region.

References:

Heimann, S., Isken, M., Kühnn, D., Sudhaus, H., Steinberg, A., Vasyura-Bathke, H., Daout, S., et al. (2018) Grond - A probabilistic earthquake source inversion framework., GFZ Data Services. doi:10.5880/GFZ.2.1.2018.003

Kwiatek, G., Martínez-Garzón, P. & Bohnhoff, M. (2016) HybridMT: A MATLAB/Shell Environment Package for Seismic Moment Tensor Inversion and Refinement. Seismol. Res. Lett., 87, 964–976. doi:10.1785/0220150251

Pugh, D.J. & White, R.S. (2018) MTfit: A Bayesian Approach to Seismic Moment Tensor Inversion. Seismol. Res. Lett., 89, 1507–1513. doi:10.1785/0220170273

Sokos, E.N. & Zahradnik, J. (2013) Evaluating Centroid-Moment-Tensor Uncertainty in the New Version of ISOLA Software. Seismol. Res. Lett., 84, 656–665. doi:10.1785/0220130002

How to cite: Mesimeri, M., Diehl, T., Clinton, J., Herwegh, M., and Wiemer, S.: Revisiting moment tensors in Switzerland: Unraveling source characteristics in Central Alps and their foreland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11256, https://doi.org/10.5194/egusphere-egu22-11256, 2022.

EGU22-11266 | Presentations | GD8.4

Internal deformation of the Dolomites Indenter, eastern Southern Alps: structural field data and low-temperature thermochronology 

Thomas Klotz, Hannah Pomella, Anna-Katharina Sieberer, Hugo Ortner, and István Dunkl

The Dolomites Indenter represents the front of the Neogene to ongoing N(W)-directed continental indentation of Adria into Europe. Deformation of the Dolomites Indenter is well studied along its rim, documented by important fault zones such as the Periadriatic fault system, the Giudicarie belt, and the Valsugana and Montello fault systems. With this study, we aim to investigate the internal deformation of the Dolomites Indenter, which has been much less studied so far but is important for understanding crustal-scale processes during the Alpine orogeny.

 

Our approach to unravel the indenters exhumation and deformation history comprises (i) the compilation and acquisition of detailed structural and sedimentological field data within the Dolomites Indenter, (ii) a collection of a new and comprehensive low-temperature thermochronological dataset (this contribution), and (iii) crustal- to lithospheric-scale physical analogue modelling experiments (see contribution of Sieberer et al. in session TS7.2 – Internal deformation of the Dolomites Indenter, eastern Southern Alps: Orthogonal to oblique basin inversion investigated in crustal scale analogue models).

 

New field data comprise evidence for four distinguishable shortening directions. Examined intersection criteria along N-S cross sections covering the indenters extend from Periadriatic to Bassano fault system support a succession of Top SW, Top (S)SE, Top S and Top E(SE) movement. However, preexisting geometry strongly seems to affect the regional expression of respective compression phases and along strike variation of lineation trends can be observed within coherent fault systems.

 

The limited amount of existing thermochronological data already indicates the presence of relative vertical displacements within the Dolomites Indenter after the onset of indentation, including mostly Miocene apatite fission track (AFT) cooling ages along the Periadriatic and the Valsugana fault and several age clusters of Triassic to Jurassic AFT data. In order to obtain a detailed picture of the indenters thermotectonic evolution, an extensive set of samples has been collected along three roughly N-S striking corridors between Bolzano in the west and Tolmezzo in the east. In this contribution we present the new apatite (U-Th)/He and fission track data along the westernmost corridor (Mauls - Brixen - Valsugana - Schio).

 

The results of field work, comprehensive modelling of time temperature paths, and physical analogue modelling substantially contribute to the understanding of internal deformation and thus enable conclusions to be drawn about the processes at lithospheric scale.

How to cite: Klotz, T., Pomella, H., Sieberer, A.-K., Ortner, H., and Dunkl, I.: Internal deformation of the Dolomites Indenter, eastern Southern Alps: structural field data and low-temperature thermochronology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11266, https://doi.org/10.5194/egusphere-egu22-11266, 2022.

EGU22-11358 | Presentations | GD8.4

Distribution of Active Seismic Deformation in the Eastern Alps from the Recent Swath-D Experiment 

Rens Hofman, Joern Kummerow, Simone Cesca, Joachim Wassermann, and Thomas Plenefisch and the AlpArray Working Group

The Swath-D network was a temporary seismic experiment nested within the AlpArray backbone network. Roughly 150 broadband stations were deployed across the Austrian-Italian border in the Eastern Alps during the second half of 2017, and were active to late 2019. This dense network provided an unprecedented resolution in a tectonically active region that is considered to play an important role in the evolution of the Alps. Extracting new information from this dataset turned out to be challenging due to the large volume of the dataset, low magnitude of the seismicity, and heterogeneity of the study area.

We applied waveform-based methods to detect, phase-pick, and relocate seismic events using data from the Swath-D network in the Eastern Alps. A GPU-accelerated template matching algorithm was developed in order to increase the number of detected earthquakes based on the previously known seismicity. Newly detected events were automatically picked using based on waveform similarity, and precisely relocated. This poster provides an overview of our results and the methods that we have applied.

How to cite: Hofman, R., Kummerow, J., Cesca, S., Wassermann, J., and Plenefisch, T. and the AlpArray Working Group: Distribution of Active Seismic Deformation in the Eastern Alps from the Recent Swath-D Experiment, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11358, https://doi.org/10.5194/egusphere-egu22-11358, 2022.

EGU22-12266 | Presentations | GD8.4

SEismic imaging of the Ivrea ZonE (project SEIZE) reveals the 3D structure of the Ivrea body near Balmuccia, Italy 

Britta Wawerzinek, Trond Ryberg, Klaus Bauer, Manfred Stiller, Christian Haberland, Alberto Zanetti, Luca Ziberna, György Hetényi, Michael Weber, and Charlotte M. Krawczyk

The Ivrea-Verbano Zone (IVZ) located in the Italian Alps is known as one of most complete archetypes of continental crust–upper mantle section on Earth (e.g. Pistone et al., 2017). Because of its accessibility at the surface it can be used as natural laboratory to improve the understanding of the crust–mantle transition zone. Several geophysical observables indicate the presence of mantle rocks (high density, high seismic velocity) in the shallow sub-surface (~ 1 km), commonly known as the “Bird’s Head” or Ivrea body (Berckhemer, 1968; Diehl et al., 2009; Scarponi et al., 2021). 

The project SEIZE images and characterizes the shallow upper crust at the Balmuccia site (Italy) providing depth, extent and shape of the outcropping Ivrea body as well as its rock properties. Our tomographic study covers the crust down to about 3 km depth, while seismic reflection imaging is possible down to 6 km depth or deeper. With SEIZE we contribute to the comprehensive ICDP Drilling program in the Ivrea-Verbano ZonE (DIVE, www.dive2ivrea.org).

To tackle this task, a controlled source (vibroseis) seismic experiment was carried out in the region around Balmuccia in October 2020. The seismic survey comprised two crossing profiles with a total length of 28 km which ran along (NNE-SSW) and across (W-E) the Balmuccia peridotite. In total, 432 vibro points were acquired with a nominal distance of ~60 m which were recorded using a fix-spread (110 receivers, ~250 m spacing) and a roll-along setup (330 receivers, ~20 m spacing).

To obtain a structural image of the shallow upper crust various seismic techniques are applied: The fix-spread data set is used to recover the velocity structure down to 3 km depth. By using a 3D Markov chain Monte Carlo travel time tomography a shallow, distinct high velocity body is imaged in 3D near Balmuccia, at the proposed drill site. Reflection seismic processing is applied to the roll-along data set. However, the difficult terrain setting (deep mountain valleys) results in complex wave propagation that is challenging for conventional processing methods (e.g. static and dynamic corrections, CDP stacking). Therefore, pre-stack migration techniques are applied enabling the imaging of steeply dipping structures.

How to cite: Wawerzinek, B., Ryberg, T., Bauer, K., Stiller, M., Haberland, C., Zanetti, A., Ziberna, L., Hetényi, G., Weber, M., and Krawczyk, C. M.: SEismic imaging of the Ivrea ZonE (project SEIZE) reveals the 3D structure of the Ivrea body near Balmuccia, Italy, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12266, https://doi.org/10.5194/egusphere-egu22-12266, 2022.

EGU22-12668 | Presentations | GD8.4

Inside the fault core in the footwall of Simplon Fault Zone (Central Alps): ductile to brittle deformation history shown by fault gouge 

Valentina Argante, David Colin Tanner, Christian Brandes, Christoph Von Hagke, and Sumiko Tsukamoto

For thorough understanding of the dynamics of mountain building processes, it is crucial to reconstruct the youngest crustal deformation history over time. Low-angle normal faults are features caused by orogen-parallel extension, which occurs in the last stage of collision. Low-angle normal faults play a key role in the exhumation of the lower crust and they are the reason for most of the seismicity within the chain.

We carried out microstructural analyses on an outcrop in the footwall of one of the major normal faults of the Alpine chain, the Simplon Fault Zone. This low-angle normal fault extended the crust by tens kilometers and it caused exhumation of its footwall, the deeper lower crust of the Alps, i.e. the Penninic nappes. The Simplon Fault Zone itself consists of a thick mylonitic zone overprinted by a narrow cataclastic zone, with the same kinematics. Its timing evolution history from ductile to brittle deformation is still under discussion. This study shows a new microstructural analysis from a fault gouge within the footwall of the northern part of the Simplon Fault Zone, and how it can reconstruct the different stages of exhumation history of this shear zone.

Results from micro-structural analyses show grain boundary migration features on folded quartz veins. This suggests that the protolith of the fault zone was at high temperature conditions, T>600°C, during dynamic deformation. This folding belongs to extension-parallel folds that affect only the ductile shear zone. The presence of greenschist facies minerals suggests that the rock was exposed to low temperature and pressure conditions (T=300-400°C, P=0.2GPa). Pressure-solution mechanisms affect both quartz and greenschist paragenesis, indicating formation in a shallow position of the shear zone. The last deformation was purely brittle, as shown by vertical calcite veins or fractures in quartz. It suggests a near-surface position of the fault.

Altogether, these multiple deformation phases within the gouge samples indicate a continuous exhumation history from high to low temperatures, with clear cross-cutting relationships. However, the lack of cataclasite features can be related to an involvement of the rocks within the fault core in a subsequent stage of deformation. To explain this we suggest a model in which the footwall maintained a high temperature over a long time, which inhibited cataclastic processes.

How to cite: Argante, V., Tanner, D. C., Brandes, C., Von Hagke, C., and Tsukamoto, S.: Inside the fault core in the footwall of Simplon Fault Zone (Central Alps): ductile to brittle deformation history shown by fault gouge, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12668, https://doi.org/10.5194/egusphere-egu22-12668, 2022.

EGU22-13245 | Presentations | GD8.4

3D geophysical and thermal modelling of the northeast Carpathian lithosphere: Implications for geothermal potential of the Baia Mare region 

Alexander Minakov, Carmen Gaina, Liviu Matenco, Maik Neukirch, and Ionelia Panea

The presented study is part of an international multidisciplinary project aiming to investigate the geothermal potential of the Baia Mare volcanic province in north-western Romania. We integrate existing geological, geochemical, hydrogeological, and geophysical data into a 3D lithospheric temperature model. In addition, new seismic reflection and broadband magnetotelluric data, acquired in the study region, provide additional constraints on the crustal-scale structures possibly controlling the transport of deep heat to the surface.

The study area is located within the Neogene Inner Carpathian volcanic arc and includes the area of the recent crustal uplift between the north-eastern part of the Pannonian Basin and the Transylvanian Basin. Borehole temperature measurements showed a geothermal gradient of 45-55 oC km-1 and temperatures higher than 150 oC at depths of 3000 m, the highest values of heat flow recorded to date in Romania. The region is known for surface hot springs and hydrothermal and epithermal volcanic ore deposits.

The heterogeneous pre-Neogene basement contains metamorphic and igneous rocks deformed or emplaced during Precambrian to Paleozoic orogenic cycles and a Triassic-Paleogene sedimentary cover with a variable radioactive heat production rate. The Miocene magmatic plumbing system within the Neogene sedimentary sequence includes intrusive bodies of 1-10s of km size. Crustal hydraulic properties and associated hydrothermal systems are possibly controlled by the regional Bogdan Voda – Dragos Voda strike-slip faults system, which provided pathways for the Miocene volcanic emplacement and sub-volcanic intrusions.

The knowledge of deep lithospheric structure is important for the characterisation of sedimentary basins with a geothermal exploration potential. In this contribution, we present geophysical and geological data and describe the construction of a regional 3D lithospheric temperature model. The structural model includes sedimentary successions, crystalline crustal layers and lithosphere-asthenosphere boundary constrained by gravity, seismic tomography and magnetotelluric data. The temperature modelling is performed by solving 3-D steady state heat conduction equation using a finite element method. We compare the model responses with available surface heat flow and borehole temperature measurements and discuss the role of local crustal heterogeneities, transient heat transfer and fluid circulation on the thermal state of the Baia Mare region.

How to cite: Minakov, A., Gaina, C., Matenco, L., Neukirch, M., and Panea, I.: 3D geophysical and thermal modelling of the northeast Carpathian lithosphere: Implications for geothermal potential of the Baia Mare region, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13245, https://doi.org/10.5194/egusphere-egu22-13245, 2022.

Wholesale slab breakoff or detachment in the Alps has been invoked to explain Periadriatic
calc-alkaline magmatism (43-29 Ma), rapid exhumation of HP metamorphics, as well as
clastic infill of proximal parts of the Alpine Molasse basin (31-28 Ma). However, the 14 My
timespan of these events exceeds the duration of slab detachment estimated from
thermomechanical modelling (2-8 My) and from depocenter migration (~5 My) along
equivalent lengths of the Carpathians and Apennines. Moreover, wholesale slab
detachment does not explain major E-W differences in Alpine orogenic structure, basin
evolution, and kinematics of indentation in the Alps.
Recent V p tomography from AlpArray suggests that the slab segment beneath the
Central Alps comprises European lithosphere and remains attached down to the MTZ. The
~600km length of this segment suggests that it never ruptured and is still connected to
subducted lithosphere of Alpine Tethys. In contrast, the Alpine slab is detached beneath the
Eastern Alps and Pannonian Basin. The minimum time since detachment is bracketed at 25-
10 Ma based on a comparison of vertical detachment distance with global slab sink rates.
We propose a new model of slab detachment in the Alps that began with slab
steepening when the Adria-Europe convergence rate after collision at ~35 ma decreased to
<1 cm/yr. Periadriatic magmatism is no longer attributed to slab detachment and
asthenospheric upwelling, but to fluxing of the cold mantle wedge by fluids derived from
the devolatilizing Alpine slab (Müntener et al. 2021; doi: 10.2138/gselements.17.1.35). Slab
steepening and delamination were more pronounced in the Eastern Alps, possibly due to
the greater negative buoyancy of the slab in the absence of Brianconnais continental
lithosphere, which was never present in the eastern part of Alpine Tethys. Slab pull thus
drove subsidence and continued marine sedimentation in the E. Molasse basin from 29-19
Ma, while the western part of the basin filled with terrigeneous sediments already at 31-28
Ma.
Slab detachment was restricted to the part of the Alps east of the Giudicarie Fault in
Miocene time. Detachment coincided with a switch in the advancing orogenic front, from
the northern front in the Eastern Alps to the southern front in the eastern Southern Alps.
This also coincided with rapid exhumation in the Tauern Window and lateral eastward
escape of the orogenic crust toward the Pannonian Basin. Rapid W-to-E filling of the Eastern
Molasse basin between 19-16 Ma is interpreted to reflect eastward propagation of the slab
tear and the onset of rollback subduction in the Carpathians.
E-W differences in Alpine structure are thus attributed to the contrasting response of
the Alpine orogenic wedge to slab steepening, delamination and detachment. Whereas
steepening and delamination in the west in late Oligocene time induced horizontal
shortening and increased taper of the orogenic wedge with rapid exhumation and
denudation focused in the retro-wedge, Miocene detachment in the east triggered a
dramatic switch in the pro- and retro-wedges, such that rapid exhumation and denudation
was ultimately focused in the axis of the orogenic wedge.

How to cite: Handy, M. R.: A new model of slab detachment in the Alps and its geodynamic consequences, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13517, https://doi.org/10.5194/egusphere-egu22-13517, 2022.

EGU22-877 | Presentations | GMPV2.2

Magnesium isotopic composition of back-arc basin lavas and its implication for the recycling of serpentinite-derived fluids 

Yi Ding, Xianglong Jin, Xiaohu Li, Zhenggang Li, Jiqiang Liu, Hao Wang, Jihao Zhu, Zhimin Zhu, and Fengyou Chu

Dehydrated fluids expelled from serpentinized mantle in the subducted slab are gradually recognised as a vital role in generating arc magmatism and element cycling in the Earth. However, it remains not clear about their recycling at various depth in subduction zones and if slab serpentinite-derived fluids contribute to the genesis of lavas from the back-arc basins. Here, we study the magnesium (Mg) isotopic compositions of lavas from the Okinawa Trough (OT) and Lau basin (LB) as Mg isotopes have shown great potential to trace dehydration of slab serpentinites in recent years. Overall, lavas from the OT and LB have averagely heavier Mg isotopic compositions relative to the mid-ocean ridge basalt (MORB) mantle, which could be attributed to the involvement of slab serpentinite-derived fluids rather than crustal assimilation or input of subducted sediments as indicated by the isotopic modelling results. The δ26Mg values of the southern OT (SOT) and southern LB (SLB) are generally higher than the middle OT (MOT) and northern LB (NLB), respectively, with an average of -0.11 ± 0.06‰ (2SD, n=5) for the SOT, -0.20 ‰ ± 0.04 (2SD, n=5) for the MOT, -0.13 ‰ ± -0.08 for the SLB (2SD, n=6) and -0.19 ‰ ± 0.06 (2SD, n=10) for the NLB. The binary modelling results have shown that various amounts of serpentinite-derived fluids could explain the variations in Mg isotopic compositions observed in the OT and LB. Combined published δ26Mg values in subduction zones with our data, the thermal structure of inter-subduction zone may play a first control on the signal of Mg-rich serpentinite-derived fluids. By contrast, the contributions of these fluids to different segments in a specific subduction zone may depend on the slab depth beneath magmatic activity sites.

How to cite: Ding, Y., Jin, X., Li, X., Li, Z., Liu, J., Wang, H., Zhu, J., Zhu, Z., and Chu, F.: Magnesium isotopic composition of back-arc basin lavas and its implication for the recycling of serpentinite-derived fluids, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-877, https://doi.org/10.5194/egusphere-egu22-877, 2022.

EGU22-1215 | Presentations | GMPV2.2

Experimental constraints on low temperature dehydration induced by mineral reactions in calcite-bearing ophicarbonates 

Lisa Eberhard, Oliver Plümper, and Daniel J. Frost

It is generally accepted that subduction zones are important sites for element recycling into the Earth’s mantle. This does in particular also include carbon, which is transported in the form of organic carbon and carbonates. While organic carbon is expected to effectively fix carbon in the slab, carbonates are often entitled as an important CO2 source for arc magmatism. The exact composition of the total subducted carbon load, in terms of oxidised and reduced carbon material, changes between different slabs and consequently the total released carbon varies significantly among suduction zones. An important mechanism for carbon release is the dissolution of carbonates in aqueous fluids. Ophicarbonates, containing both serpentine and carbonate minerals, are thus of special interest: The fluid released through serpentine dehydration reactions interacts with carbonates and causes the release of carbon. However, to better constrain the carbon release it is essential to understand the release of fluid in carbonated systems.

In this study we present a detailed experimental analysis on the effect of carbonates on the fluid release from serpentinites. We performed multi-anvil experiments on model ophicarbonates. Our starting material was a mixture between natural antigorite and Ca-carbonate and/or graphite. We also conducted thermodynamic calculations on various serpentinite-carbonate systems. Our experimental results show that serpentine dehydrates at temperatures <600 °C at 2.5 GPa, which is lower with respect to uncarbonated serpentinites. For a serpentinite with 20 wt% CaCO3 the dehydration of serpentine thus takes place at 50 - 60 km depth. In the absence of CaCO3 the fluid is released at 60 - 70 km depth. In cold subduction zones this shift in dehydration depth is even more extreme: In a carbonated system the serpentine was found to dehydrate at 80 - 110 km depth, in comparison to 110 - 130 km depth in the uncarbonated system. We found that this shift is mainly due to Ca-Mg exchange reactions between the carbonate and silicate fraction. The experimental run products show distinct dehydration mineralogy, forming Ca-silicates and Mg-bearing carbonates. In combination with mass balance calculations we show that the total carbonate-fraction does not decrease over the whole experimental temperature range. In conclusion, serpentinites with a high Ca-carbonate content are expected to dehydrate earlier in the subduction zones, whereas the carbon remains in the slab. The presence of Ca-carbonate thus has the potential to prevent subduction of water into deeper levels of the Earth’s mantle.

How to cite: Eberhard, L., Plümper, O., and Frost, D. J.: Experimental constraints on low temperature dehydration induced by mineral reactions in calcite-bearing ophicarbonates, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1215, https://doi.org/10.5194/egusphere-egu22-1215, 2022.

EGU22-2584 | Presentations | GMPV2.2

Multidimensional Analysis of Serpentinite Dehydration Networks and Implications for Volatile Flux in Subduction Zones 

Austin Arias, Andreas Beinlich, Lisa Eberhard, Marco Scambelluri, and Oliver Plümper

Subduction zones are principal pathways for the cycling of volatiles such as  hydrogen and carbonfrom the Earth’s surface to the mantle and back to the atmosphere. This cycling has significant long-term effects on Earth’s climate. However, the processes that lead to volatile release during subduction and total volatile fluxes are poorly understood. In our study, we will quantify and characterize the network architecture of dehydration pathways exhibited as mineralized olivine-bearing metamorphic veins in the exhumed meta-serpentinites from the Erro-Tobbio unit, Italy [1]. Applying network analytical methods and graph theory both macroscopically and microscopically can provide the mode of propagation and describe the controlling factors affecting the evolution of these dehydration networks. Furthermore, multiscale observations can confirm the scalability of the vein network and if quantitative results such as permeability or volatile flux can be extrapolated to larger scales.

Along with 2-D network analysis, these vein networks will be analyzed in 3-dimensions using X-ray tomography and sophisticated machine-learning methods, such as generative adversarial networks. The results of both will be compared, which can then assure whether current machine-learning methods can effectively create statistically equivalent copies of these networks. Lastly, the synthesis of 2-D and 3-D multiscale results should provide meaningful parameters for accurate calculations of volatile flux during the dehydration of subducting slabs. 

 

[1] Plümper et al. (2017) Nature Geoscience 10(2), 150-156.

How to cite: Arias, A., Beinlich, A., Eberhard, L., Scambelluri, M., and Plümper, O.: Multidimensional Analysis of Serpentinite Dehydration Networks and Implications for Volatile Flux in Subduction Zones, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2584, https://doi.org/10.5194/egusphere-egu22-2584, 2022.

EGU22-3092 | Presentations | GMPV2.2

New rutile and titanite phase stability constraints at subsolidus conditions in a mafic system 

Inês Pereira, Kenneth Koga, and Emilie Bruand

Rutile, titanite and ilmenite are the most common Ti-bearing minerals found in metamorphic rocks of variable grades. Rutile and titanite, in particular, are extremely useful minerals as they can be dated using U-Pb, and Zr concentrations are calibrated as geothermometers for both minerals, making them valuable petrochronometers. Previous experimental studies on MORB composition [1] established that titanite is more stable at LT-LP, rutile at HP (> 12 kbar), while ilmenite at HT-LP metamorphic conditions. Despite these phase stabilities, the natural occurrence of rutile at LP (< 12 kbar) and titanite at HP (> 20 kbar) and ilmenite at both HP and LP indicates strong uncertainties on our current understanding about their stabilities. [2] demonstrated a non-trivial compositional effect mainly driven by CaO content, on the titanite-out reaction for granitoid compositions (2-4 kbar). For MORB compositions, experimental constraints are currently lacking in the 400-600 ºC temperature range.

Here we present the results of a set of experiments run in a piston-cylinder apparatus using a gold capsule with a NNO oxygen fugacity buffer. We tested multiple starting materials, with different Ti/Ca values, including: 1) a pulverised eclogite (MORB composition) powder with titanite and rutile as well as a few initial eclogitic silicate mineral seeds, promoting nuclei for mineral overgrowth, 2) the same eclogite, glassed and pulverised in the lab, with fewer product seeds, and some of these with added Ti powder; 3) a different MORB powder with crushed titanite and kaersutite seeds. More than 30 experiments were conducted, with pressure ranging between 12 and 23 kbar, and temperature between 400 and 750 ºC in water-saturated conditions and using a cold pressure-seal capsule technique. Due to the challenging LT experiments, equilibrium is not attained, but dissolution and precipitation features are often observable. Epidote is one of the first minerals to nucleate and grow when the initial water content is > 10 wt%, and crystallisation is followed by amphibole. We show that when Ti/Ca is high, rutile is stable even at lower pressures, and when Ti/Ca is low, titanite seeds appear metastable even at higher pressures (19 kbar) and low temperatures. This is in agreement with petrological observations (i.e. peak titanite reported in blueschist rocks). At lower water saturation conditions (10 wt%), reactions are more sluggish, but successful experimental assemblies show that at 600 ºC and 14 kbar titanite seeds become unstable and start reacting with the basalt bulk rock powder to form ilmenite. We found that H2O content, as well as Ti/Ca ratios appear to influence the stability of these Ti-phases in a mafic system. These results can be used to constrain the stabilities of rutile, titanite and ilmenite, which in turn elucidate the P-T-X conditions that these accessory minerals are able to record.

[1] Liou, et al. (1998). Schweiz. Mineral. Petrog. Mitt., 78, 317-335. [2] Angiboust, S., & Harlov, D. (2017). Am. Min., 102, 1696-1708.

How to cite: Pereira, I., Koga, K., and Bruand, E.: New rutile and titanite phase stability constraints at subsolidus conditions in a mafic system, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3092, https://doi.org/10.5194/egusphere-egu22-3092, 2022.

EGU22-3423 | Presentations | GMPV2.2

Metasomatism between serpentinite and pelitic schist in the Yuli belt, eastern Taiwan: fluid-rock interactions during subduction metamorphism 

Dominikus Deka Dewangga, Chin-Ho Tsai, Hao-Yang Lee, Yoshiyuki Iizuka, Wen-Han Lo, and Chi-Yu Lee

Metasomatic rocks in orogenic mélanges bear critical information about fluid-rock interactions and element mobilities during subduction processes. The Yuli belt contains a few mélange units that crop out high-pressure blocks of metaigneous rocks and serpentinites enclosed in metasedimentary rocks. Metasomatic rocks are found along contacts between the serpentinites and metasedimentary rocks. However, the protolith and formation of those metasomatic rocks are largely unknown. Meter-scale metasomatic zones occur at the contact between pelitic schists (PS) and serpentinites (SP) in the Tsunkuanshan area. Five zones from PS to SP are newly identified: (I) chlorite-albite schist, (II) amphibole-albite rock, (III) albite-chlorite schist, (IV) epidote-chlorite schist, and (V) chlorite-talc schist. Minor garnet and amphibole (glaucophane core - barroisite mantle - actinolite rim) are present in the zone I and II, respectively. Field and petrographic observations combined with whole-rock major elements data suggest that this rock association likely was formed by chemical exchanges between the SP and PS. However, the zone II shows enrichment of Si, Na, and Ca, but Al depletion relative to the other metasomatic rocks. This anomaly might be due to infiltration of external fluids. Rare earth element patterns of the PS, zone I, II, III, and IV are similar, indicating a similar protolith origin. Hence, the original boundary between the PS and SP is likely between the zone IV and V. We estimate the chemical mass balance from the PS to the metasomatic rocks (zone I, II, III, and IV) using the sparse isocon method (Kuwatani et al., 2020). The result shows that the chemical components in zone I, III, and IV are gained relative to the PS, whereas those in zone II are of loss. We interpret that the zone I, III, IV, and V were produced by diffusive exchanges of components between the PS and SP, whereas formation of the zone II was likely created by Na-Ca rich fluid infiltrations. The newly-found occurrence of glaucophane within the zone II indicates fluid-rock interactions during subduction metamorphism.

Keywords: Chemical mass balance, sparse isocon method, Na-Ca rich fluids, Yuli belt.

How to cite: Dewangga, D. D., Tsai, C.-H., Lee, H.-Y., Iizuka, Y., Lo, W.-H., and Lee, C.-Y.: Metasomatism between serpentinite and pelitic schist in the Yuli belt, eastern Taiwan: fluid-rock interactions during subduction metamorphism, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3423, https://doi.org/10.5194/egusphere-egu22-3423, 2022.

EGU22-3611 | Presentations | GMPV2.2 | Highlight

Perturbation of the deep-Earth carbon cycle in response to the Cambrian Explosion 

Andrea Giuliani, Russell N. Drysdale, Jon D. Woodhead, Noah J. Planavsky, David Phillips, Janet Hergt, William L. Griffin, Senan Oesch, Hayden Dalton, and Gareth R. Davies

Earth’s carbon cycle is strongly influenced by subduction of sedimentary material into the mantle. The composition of the sedimentary subduction flux has changed considerably over Earth’s history, but the impact of these changes on the mantle carbon cycle is unclear. Here we show that the carbon isotopes of kimberlite magmas record a fundamental change in their deep-mantle source compositions during the Phanerozoic Eon. The 13C/12C of kimberlites prior to ~250 Myr preserves typical mantle values, whereas younger kimberlites exhibit lower and more variable ratios – a switch coincident with a recognised surge in kimberlite magmatism. We attribute these changes to increased deep subduction of organic carbon with low 13C/12C following the Cambrian Explosion when organic carbon deposition in marine sediments increased significantly. These observations demonstrate that biogeochemical processes at Earth’s surface have a profound influence on the deep mantle, revealing an integral link between the deep and shallow carbon cycles.

How to cite: Giuliani, A., Drysdale, R. N., Woodhead, J. D., Planavsky, N. J., Phillips, D., Hergt, J., Griffin, W. L., Oesch, S., Dalton, H., and Davies, G. R.: Perturbation of the deep-Earth carbon cycle in response to the Cambrian Explosion, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3611, https://doi.org/10.5194/egusphere-egu22-3611, 2022.

EGU22-3929 | Presentations | GMPV2.2

Carbonation of peridotites along the basal thrust of the Semail Ophiolite (OmanDP Hole BT1B): insights from Fe and Zn isotopes 

Thierry Decrausaz, Marguerite Godard, Baptiste Debret, and Isabelle Martinez

The formation of carbonated serpentinites (serpentine, Mg-Ca carbonates) and listvenites (quartz, Mg-carbonate) by reactions between exhumed mantle peridotites and percolating CO2-bearing fluids is a major sink for carbon from spreading ridges to ophiolites and orogenic suture zones. During ICDP Oman Drilling Project, the transition from the base of the Semail Ophiolite to its metamorphic sole was drilled at Hole BT1B (Wadi Mansah), allowing to recover ~200 m of variously carbonated serpentinites and listvenites, and underlying metabasalts. Mineralogical and geochemical investigations indicate that carbonation at the expense of the Wadi Mansah peridotites was triggered by the migration of multiple fluid batches along the basal thrust at shallow depths and low temperatures (50-250 °C). To better constrain the impacts of fluid source(s) and protolith compositions on reaction pathways and oxidation state during carbonation, we carried out iron and zinc isotopes study of 19 variously carbonated peridotites (13 listvenites, 5 carbonated serpentinites, one serpentinized harzburgite) and of 6 underlying metamorphic samples from Wadi Mansah area (including 3 BT1B samples).

The partially serpentinized harzburgite and carbonated serpentinites have δ56Fe and δ66Zn compositions ranging between -0.05 – +0.06 ‰ and -0.11 – +0.15, respectively, overlapping that of previously analysed abyssal (δ56Fe: -0.15 – +0.11 ‰; δ66Zn: +0.12 – +0.62 ‰), ophiolitic (δ56Fe: -0.27 – +0.14 ‰; δ66Zn: -0.56 – +0.38 ‰), orogenic (δ56Fe: -0.06 – +0.12 ‰; δ66Zn: +0.03 – +0.55 ‰), and fore-arc (δ56Fe: -0.26 – +0.09 ‰) peridotites. In contrast, listvenites display highly variable δ56Fe and δ66Zn values, between -0.33 – +0.2 ‰ and -0.46 – +0.64 ‰ respectively. Iron isotopes compositions show a positive correlation with bulk iron contents. Zinc isotope compositions are positively correlated to δ13CTC values, suggesting a high mobility of Zn in carbonate-bearing fluids. The lightest δ66Zn values were measured in listvenites with minor amounts of fuchsite (Cr-mica), that often display evidences for breakdown of Cr-spinel. Metamorphic sole samples display isotopic compositions typical of mafic rocks (δ56Fe: +0.01 – +0.24 ‰; δ66Zn: +0.24 – +0.47 ‰), in agreement with an oceanic crust-derived protolith (MORB, δ56Fe: +0.06 – +0.18; δ66Zn: +0.27 – +0.30 ‰).

Our results suggest an important control of the protolith chemistry and complexation with dissolved carbon in reactive fluids on the Fe and Zn isotopes compositions.

How to cite: Decrausaz, T., Godard, M., Debret, B., and Martinez, I.: Carbonation of peridotites along the basal thrust of the Semail Ophiolite (OmanDP Hole BT1B): insights from Fe and Zn isotopes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3929, https://doi.org/10.5194/egusphere-egu22-3929, 2022.

The role of subduction zones has been considered critical to understand carbon fluxes among the Earth’s reservoirs. At plate margins, most of the carbon is stored in carbonate sediments. Nevertheless, the past decade saw an increasing focus also on reduced carbon - kerogen and graphite – to understand its role in the deep carbon cycle. Most of reduced carbon derive from seafloor organic-rich sediments, even if, a little portion can form by decarbonation during metamorphism.

In the Palaeoproterozoic supracrustal rocks of the Lewisian Complex, graphitic marbles were found in a mixed succession of metasediments at Gott Bay, Island of Tiree (Scotland). Such marbles show bedding-parallel slip surfaces associated with chlorite that are absent in other marbles on the island that are devoid of graphite. Marbles and schists-hosted graphite were analysed showing marked differences in carbon isotopic composition and structural ordering measured by means of Raman spectroscopy.

Petrographic and chemical evidence support the hypothesis of an abiotic origin of the marble-hosted graphite and the mechanisms that led to its formation could explain the heavy isotopic composition of many Proterozoic marbles in the world.

 

 

 

 

How to cite: Schito, A., Parnell, J., Muirhead, D., and Boyce, A.: Evidence of abiotic graphite formation in Proterozoic marbles of the Lewisian Complex: mechanisms and consequences for the deep carbon cycle, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5014, https://doi.org/10.5194/egusphere-egu22-5014, 2022.

EGU22-5782 | Presentations | GMPV2.2

Deep subduction of continental crust contributes to mantle metasomatism and deep carbon cycle 

Alessia Borghini, Gautier Nicoli, Silvio Ferrero, Patrick J. O'Brien, Oscar Laurent, Laurent Remusat, Giulio Borghini, and Sula Milani

The garnet in the ultra-high pressure (UHP) eclogites of the Erzgebirge (Bohemian Massif, Germany) trapped primary inclusions of metasomatic melt originated by the partial melting of the continental crust. The study of these inclusions alow us to estimate the contribution of the subducted continental crust to mantle metasomatism and deep carbon fluxes. The inclusions are randomly distributed in the inner part of the garnet, they are micrometric and occur as both polycrystalline, i.e. nanogranitoids, and glassy, often with a shrinkage bubble. Nanogranitoids consist of kumdykolite, quartz, kokchetavite, biotite, white mica, calcite and rare graphite. The inclusions share their microstructural position in the garnet with inclusions of polycrystalline quartz interpreted as quartz pseudomorph after coesite that indicate the entrapment at UHP conditions. The melt composition, measured on glassy inclusions and rehomogenized nanogranitoids, is granitic. The melt is also hydrous, slightly peraluminous and the trace element enrichments observed are consistent with an origin from the continental crust, testified by the high amount of incompatible elements such as Cs, Pb, Th, U, Li and B. Similar signatures were also reported elsewhere in the Bohemian Massif, e.g. in other metasomatic melts hosted in HP mantle eclogites, in metasomatized mantle rocks and in post-collisional ultrapotassic magmatic rocks, suggesting that mantle metasomatism from melts originated in the continental crust is widespread in the orogen.

The melt H2O and CO2 contents were measured with the NanoSIMS. The CO2 values in particular were corrected reintegrating the vapor contained in the shrinkage bubble and are in average 19552 ± 772 ppm, the highest content of CO2 measured so far in crustal melt inclusions. The modelled endogenic carbon flux associated with the subduction of the continental crust of the Variscan Orogenic Cycle is 22 ± 8 Mt C yr-1. This flux within error is similar to the endogenic carbon fluxes in the serpentinized mantle (~ 14 Mt C yr-1) and to the exogenic fluxes in mid-oceanic ridges (~ 16 Mt C yr-1) and arc volcanoes (~ 24 Mt C yr-1). Hence, in collisional settings, deeply subducted continental crust carried a large amount of volatiles to the mantle and the lower crust. Due to the absence of post collisional arc volcanism, most of these volatiles remained trapped in the root of mountain belts. This long-term storage of the carbon in the orogen roots prevents ultimately the closure of the carbon cycle.

How to cite: Borghini, A., Nicoli, G., Ferrero, S., O'Brien, P. J., Laurent, O., Remusat, L., Borghini, G., and Milani, S.: Deep subduction of continental crust contributes to mantle metasomatism and deep carbon cycle, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5782, https://doi.org/10.5194/egusphere-egu22-5782, 2022.

EGU22-6180 | Presentations | GMPV2.2

New zircon U-Pb geochronology from the Ketilidian orogen of South Greenland 

Rikke Vestergaard, Tod Waight, Andreas Petersson, Heejin Jeon, and Martin Whitehouse

The Paleoproterozoic Ketilidian orogen in South Greenland (1.85-1.73 Ga) is interpreted to be the result of northwards-dipping oblique subduction of an oceanic plate beneath the Archaean continental crust of the North Atlantic Craton. The Ketilidian orogen was part of the subducted-related magmatism and accretionary orogenic belt named the Great Paleoproterozoic Accretionary Orogen that existed along an active margin stretching through Laurentia (North America and South Greenland) to Baltica (Northeast Europe), which formed the supercontinent Columbia/Nuna. Thus, the orogeny represents part of an important episode of crustal growth and preservation in Earth’s history. The Central Domain of the orogeny is dominated by the plutonic remnants of a magmatic arc (the Julianehåb Igneous Complex (JIC), ca. 1.85-1.80 Ga), which eventually grew sufficiently large and stable to subsequently uplift and unroof, to produce rocks interpreted to represent erosional fore-arc deposits that are preserved to the south in the Southern Domain. Between ca. 1.80 Ga and 1.76 Ga, the fore-arc was subjected to metamorphism of amphibolite to granulite facies, and was subsequently intruded by post-tectonic granites (including rapakivi variants) of the Ilua Suite (1.75-1.73 Ga). We present new zircon U-Pb SIMS ages for granitic and metasedimentary rocks sampled at a regional scale in a traverse stretching NW to SW through the Central and Southern Domains of the Ketilidian Orogen in South Greenland. Previous studies have distinguished two pulses of magmatism in the JIC, an early event at ca. 1.85-1.83 Ga and a later phase at ca. 1.80-1.78 Ga. Our JIC samples are dominated by the late stage (<1.83 Ga) with most ages concentrated at 1.8 Ga, suggesting that the main volume of crust in the western portion of the arc was generated over a relatively short period. Ages for the Ilua Suite agree well with previous studies. Zircon age distributions in the metasedimentary rocks of the Southern Domain are consist with detritus dominantly sourced from the JIC, however the presence of small populations of older zircons (up to 2.8 Ga) not observed as inherited zircons in the JIC, indicates that older crustal components also eroded into the fore-arc. These U-Pb zircon results are part of an ongoing larger investigation combining O-Hf isotope compositions in zircon, coupled with whole rock geochemical and isotope data. This research will provide the first thorough geochemical and petrogenetic investigation of the timing, across arc variations, and source components involved in the formation and evolution of South Greenland as well as its contribution in one of the worldwide peaks of continental crustal growth.

How to cite: Vestergaard, R., Waight, T., Petersson, A., Jeon, H., and Whitehouse, M.: New zircon U-Pb geochronology from the Ketilidian orogen of South Greenland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6180, https://doi.org/10.5194/egusphere-egu22-6180, 2022.

EGU22-9318 | Presentations | GMPV2.2

Subducted Carbon in the Earth’s lower mantle: The fate of magnesite 

Lélia Libon, Georg Spiekermann, Melanie Sieber, Johannes Kaa, Serena Dominijanni, Mirko Elbers, Ingrid Blanchard, Christian Albers, Nicole Bierdermann, Wolfgang Morgenroth, Karen Appel, Catherine McCammon, Anja Schreiber, Vladimir Roddatis, Konstantin Glazyrin, Rachel Husband, Louis Hennet, and Max Wilke

Subduction of carbon-bearing phases throughout Earth’s history may be an important mechanism of sourcing carbon to the Earth’s lower mantle. As carbon has very low solubility in mantle silicates, it is primarily present in accessory phases such as carbonates, diamond, or metal carbides. Previous studies indicate that more than half of the carbonate contained in the oceanic crust may survive metamorphism and dehydration in the sub-arc and reach the lower mantle, even though the oxygen fugacity in the deep mantle may not favour their stability [1]. Indeed, the presence of carbonate in ultra-deep diamond inclusions provides evidence for carbonate subduction at least down to the transition zone [2].

The carbonate phases present in the lower mantle depend on their bulk composition, the oxygen fugacity, and on their stability at a given pressure and temperature. Results from high-pressure experiments show that magnesite (MgCO3) can be stable up to deep lower mantle conditions (∼80 GPa and 2500 K) [3]. Accordingly, magnesite may be considered the most probable carbonate phase present in the deep Earth. Experimental studies on magnesite decarbonation in presence of SiO2 at lower mantle conditions suggest that magnesite is stable along a cold subducted slab geotherm [4, 5]. However, our understanding of magnesite’s stability in contact with bridgmanite [(Mg,Fe)SiO3],  the most abundant mineral in the lower mantle, remains incomplete.

Hence, to investigate sub-solidus reactions, melting, decarbonation, and diamond formation in the system MgCO3-(Mg,Fe)SiO3, we conducted a combination of high-pressure experiments using multi-anvil press and laser-heated diamond anvil cells (LH-DAC) at conditions ranging from 25 to 70 GPa and 1300 to 2100 K.

Multi-anvil experiments at 25 GPa and temperatures below the mantle geotherm (1700 K) show the formation of carbonate-silicate melt associated with stishovite crystallization, indicating incongruent melting of bridgmanite to stishovite, in accordance with the recent finding of Litasov and Shatskiy [4]. LH-DAC data from in situ X-ray diffraction show crystallization of bridgmanite and stishovite. Diamond crystallization is detected using Raman spectroscopy. A melt phase could not be detected in situ at high temperatures.

Our results suggest a two-step process that starts with melting at temperatures below the mantle geotherm, followed by crystallization of diamond from the melt produced.  Therefore, we propose that subducted carbonate-bearing silicate rocks will not remain stable in the lower mantle and will instead melt at upper-most lower mantle conditions, fostering diamond formation. Our study also provides additional evidence that diamond production is related to carbonated melt. Consequently, the melting of recycled crust and chemical transfer to the surrounding mantle will hinder the transport of carbon deeper into the lower mantle.

[1] Stagno et al. (2015) Contrib. Mineral. Petrol. 169(2), 16.
[2] Brenker et al. (2007) EPSL 260(1-2), 1-9.
[3] Binck, et al. (2020) Physical Review Materials, 4(5),1-9.
[4] Litasov & Shatskiy (2019) Geochemistry International, 57(9), 1024-1033.
[5] Drewitt, et al. (2019). EPSL, 511, 213-222.

How to cite: Libon, L., Spiekermann, G., Sieber, M., Kaa, J., Dominijanni, S., Elbers, M., Blanchard, I., Albers, C., Bierdermann, N., Morgenroth, W., Appel, K., McCammon, C., Schreiber, A., Roddatis, V., Glazyrin, K., Husband, R., Hennet, L., and Wilke, M.: Subducted Carbon in the Earth’s lower mantle: The fate of magnesite, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9318, https://doi.org/10.5194/egusphere-egu22-9318, 2022.

EGU22-9783 | Presentations | GMPV2.2

Titanium isotopic fractionation of arc derived melts and cumulates 

Julian-Christopher Storck, Nicolas David Greber, Alexandra Müller, Thomas Pettke, and Othmar Müntener

Mechanisms such as crystallization differentiation, subduction erosion, delamination, or relamination that are responsible for the formation and modification of modern crust with an on average andesitic composition are actively debated (Hacker et al. 2015). Isotope fractionation associated with igneous processes is documented for many non-traditional stable isotope systems, making them promising tools to advance our understanding of modern arc crust formation. Titanium isotopes are especially promising, as volcanic and plutonic arc rocks show a trend from light to heavy isotope values with increasing SiOconcentration due to the fractionation of minerals with light Ti isotopes.

We present new Ti isotope data on medium K calc-alkaline to shoshonitic magmatic differentiation suites from the Adamello Batholith (N-Italy), Kos (Agean arc), Torres del Paine (Patagonia) and the Dolomites (N-Italy) in addition to crust-derived mafic cumulates. The Ti isotopic composition of dacites and granites range between δ49TiOL-Ti ≈ 0.3 to 1.1‰, with heavier values for more alkaline granitic melts in agreement with published data (Hoare et al. 2020). Mafic cumulates from related and additional localities are overall isotopically lighter than (their) granitic counterparts ranging between δ49TiOL-Ti ≈ -0.15 and +0.08‰. Cumulates of studied crustal sections enriched in Fe-Ti oxides (>5 modal %) show δ49Ti values lighter than the depleted MORB mantle (DMM, δ49TiOL-Ti ≈ +0.002 ± 0.007‰) and counterbalance the isotopically heavy composition of felsic rocks. The occurrence of cumulates heavier than DMM may have several reasons: (i) “heavy” cumulates may represent late-stage relicts of progressive magma differentiation containing trapped intercumulus melt or (ii) they experienced overprinting, e.g., by mafic rejuvenation.

We therefore find that the Ti isotopic composition of cumulate rocks and likely also the magmatic lower continental crust is influenced by their mineralogical composition. How this impacts the Ti isotopic composition of the bulk continental crust in the light of delamination and relamination processes needs further work.

 

REFERENCES

Hacker, B. R., Kelemen, P. B., & Behn, M. D. (2015). Continental lower crust. Annual Review of Earth and Planetary Sciences43, 167-205.

Hoare, L., Klaver, M., Saji, N. S., Gillies, J., Parkinson, I. J., Lissenberg, C. J., & Millet, M. A. (2020). Melt chemistry and redox conditions control titanium isotope fractionation during magmatic differentiation. Geochimica et Cosmochimica Acta282, 38-54.

How to cite: Storck, J.-C., Greber, N. D., Müller, A., Pettke, T., and Müntener, O.: Titanium isotopic fractionation of arc derived melts and cumulates, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9783, https://doi.org/10.5194/egusphere-egu22-9783, 2022.

EGU22-9996 | Presentations | GMPV2.2

Metaserpentinite carbonation and decarbonation reactions during subduction metamorphism and subsequent tectonic exhumation 

Vicente López Sánchez-Vizcaíno, José Alberto Padrón-Navarta, Casto Laborda-López, María Teresa Gómez-Pugnaire, Manuel Dominik Menzel, and Carlos Jesús Garrido

In subduction zones, serpentinite-hosted ophicarbonates and their main dehydration and decarbonation reactions linked to prograde metamorphism are relatively well understood. On the contrary, the geological conditions and processes leading to the carbonation of subduction-zone metaserpentinites by fluid–rock interactions remain poorly constrained. At different arc depths, the reaction of decarbonation fluids derived from marble and carbonate‐bearing sediment with slab and mantle wedge serpentinites, as well as tectonic mixing and deformation along subduction zone interface, may produce magnesite-bearing rocks with a bulk composition similar to that of ophicarbonates. Subsequently, these hybrid metasomatic lithologies will undergo decarbonation reactions at prograde or retrograde conditions which may influence the cycling of C and other volatiles from the slab to the mantle wedge and the global estimates of C fluxes at convergent margins. This can be evaluated through the study of exposed paleo-subduction metamorphic suites.

Here we investigate the tectonic, textural and mineralogical evolution of marble layers and magnesite-rich lenses hosted in chlorite harzburgite (Chl-harzburgite) in the Cerro Blanco ultramafic massif (Nevado-Filábride Complex, Betic Cordillera, S. Spain), which records high-pressure alpine subduction metamorphism as evidenced by the transition from antigorite serpentinite (top of the body) to Chl-harzburgite (bottom) due to high-pressure deserpentinization. Chl-harzburgite is separated from a gneiss and mica schist crustal sequence by a footwall of strongly heterogenous mylonite (around 20 m thick) encompassing: transposed, foliated and brecciated marble layers, foliated Chl-harzburgite lenses (in some cases completely transformed to retrograde serpentinite), centimetre to several decimetre thick boudins of idiomorphic coarse to very coarse magnesite aggregates, associated to chlorite and magnetite and enveloped by the mylonitic foliation, and, finally, abundant almost monomineralic amphibole aggregates. We interpret this mylonite zone as a detachment leading to the exhumation of the Cerro Blanco massif after reaching peak subduction metamorphic conditions that formed the Chl-harzburgite assemblage.

Combined field, EDS-SEM, and EPMA data obtained from a detailed cross-section sampling of this mylonite zone reveal that, locally, metamorphic equilibrium was reached between Chl-harzburgite and the transformation products of the magnesite boudins during the mylonite foliation development. Thermodynamic modelling of these assemblages allows inferring the relationship between deformation and metamorphic conditions during exhumation, including possible decarbonation reactions.

We thank the Universidad de Jaen 1263042 FEDER-UJA grant, funded by the European Social Fund and the European Regional Development Fund.

How to cite: López Sánchez-Vizcaíno, V., Padrón-Navarta, J. A., Laborda-López, C., Gómez-Pugnaire, M. T., Menzel, M. D., and Garrido, C. J.: Metaserpentinite carbonation and decarbonation reactions during subduction metamorphism and subsequent tectonic exhumation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9996, https://doi.org/10.5194/egusphere-egu22-9996, 2022.

EGU22-11108 | Presentations | GMPV2.2

Eclogite-hosted metamorphic veins in the Münchberg Massif (Germany) 

Johannes Pohlner, Afifé El Korh, Reiner Klemd, Thomas Pettke, and Bernard Grobéty

Eclogite-hosted metamorphic veins mark former fluid migration pathways during a subduction-exhumation cycle, and allow to trace fluid-mediated element transfer across lithologies, to ultimately metasomatize the mantle wedge. Fluids can be generated by dehydration reactions at different P-T conditions in various lithologies, all influencing how different chemical constituents are dissolved and re-precipitated. Here we present a study of eclogite-hosted quartz-rich metamorphic veins in the Variscan Münchberg Massif. The eclogites probably represent subducted continental crust that was variably hydrated and subjected to amphibolite facies conditions before reaching eclogite facies peak conditions of ca. 3 GPa and 700°C.

Isolated, mm-sized quartz pockets with euhedral high-pressure minerals are common in the Münchberg eclogites, but continuous veins that may have allowed focused fluid flow beyond specimen scale are rare. Nevertheless, where such veins occur, they can contain high-pressure minerals such as garnet and omphacite, but also rutile, zircon, and allanite, indicating high field strength-element (HFSE) mobility at least on the specimen scale. Garnet- and omphacite-bearing veins are typically 1-10 mm thick with average crystal sizes of 1 mm and less. A different vein type is mostly similar in thickness, but consists of quartz + phenocrysts (sometimes >1 cm long) of kyanite, phengite, and/or rutile. Symplectite-rich selvages surrounded by mostly fresh host eclogite are common.

Oxygen isotope thermometry of quartz-garnet, quartz-phengite, and quartz-kyanite pairs yield temperatures around 700°C, interpreted to represent vein crystallization. δ18O values of vein quartz (+6.1 to +10.5‰) from all vein types are identical to δ18O values of host rock quartz (the latter were predicted from mass balance modelling at 700°C based on host rock δ18O values from +4.0 to +7.9‰). While it is evident that the garnet- and omphacite-bearing veins were formed under eclogite facies conditions, pressures are uncertain for the quartz-rutile, quartz-phengite, and quartz-kyanite veins. Still, vein formation at relatively high pressures seems probable, as solubilities of chemical components tend to increase with pressure, facilitating HFSE mobilization from the source rock. We propose that internal fluids were generated by dehydration of phengite and/or zoisite and/or amphibole from the eclogites. Isolated quartz-rich pockets formed in eclogites that may have released only small amounts of fluid, whereas continuous metamorphic veins were formed in eclogites that produced more fluid, probably reflecting a more intense hydration before eclogite facies metamorphism. The internal origin of the fluids supported by oxygen isotope evidence argues against fluid transport over large distances. The fluids may have largely remained in place before being consumed for symplectite formation upon retrogression to amphibolite facies conditions.

How to cite: Pohlner, J., El Korh, A., Klemd, R., Pettke, T., and Grobéty, B.: Eclogite-hosted metamorphic veins in the Münchberg Massif (Germany), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11108, https://doi.org/10.5194/egusphere-egu22-11108, 2022.

EGU22-11350 | Presentations | GMPV2.2

Hydrocarbon-bearing fluid migration produces brecciation at high pressure condition in subduction 

Francesco Giuntoli, Alberto Vitale Brovarone, and Luca Menegon

It has been recently proposed that high-pressure genesis of abiotic hydrocarbon can lead to strain localization in subducted carbonate rocks1. However, the mechanical effects of the migration of these hydrocarbon-bearing fluids on the infiltrated rocks still need to be constrained.

In this study, we investigate omphacitite (i.e. omphacite-rich rock) adjacent to an high-pressure methane source from the Western Italian Alps (Italy) using a multiscale and analytical approach including petrographic, microstructural, X-ray compositional mapping and electron backscatter diffraction analyses (EBSD). In the field, omphacitite bands are 1-5 metres thick and tens of metres long and are adjacent to carbonate rocks affected by high-pressure reduction and methane production.

Hand specimens and thin sections display a brecciated structure, with omphacitite fragments ranging in size from a few microns to several centimetres, surrounded by a matrix of jadeite, omphacite, grossular, titanite, and graphite. X-ray compositional maps and cathodoluminescence images highlight oscillatory zoning and skeletal (jackstraw) textures in jadeite, omphacite and garnet in the matrix, suggesting a fast matrix precipitation under plausible disequilibrium conditions. CH4 and H2 are found in fluid inclusions in the jadeite grains. This feature suggests a potential link between the genesis of CH4 in the adjacent carbonate rocks and the brecciation event.

EBSD analysis was performed on omphacitite clasts close to their borders, where omphacite grain size varies between a few microns and a maximum of 100 microns. Those omphacite grains display no crystallographic preferred orientation, abundant low angle boundaries and low (< 5°) internal lattice distortion. We interpret these textures as formed by pervasive and diffuse micro-fracturing related to the brecciation occurring at high pore fluid pressure, reaching sub-lithostatic values. This study suggests that at high-pressure conditions in subduction zones, the genesis and migration of hydrocarbon-bearing fluids can trigger fracturing in adjacent lithotypes.

1Giuntoli, F., Vitale Brovarone, A. & Menegon, L. Feedback between high-pressure genesis of abiotic methane and strain localization in subducted carbonate rocks. Sci. Rep. 10, 9848 (2020).

This work is part of project that has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (Grant agreement No. 864045).

 

How to cite: Giuntoli, F., Vitale Brovarone, A., and Menegon, L.: Hydrocarbon-bearing fluid migration produces brecciation at high pressure condition in subduction, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11350, https://doi.org/10.5194/egusphere-egu22-11350, 2022.

EGU22-11697 | Presentations | GMPV2.2

Sulfur in the slab: A sulfur-isotopes and thermodynamic-modeling perspective from exhumed terranes 

Jesse Walters, Alicia Cruz-Uribe, and Horst Marschall

Sulfur is a key element in the subduction zone-volcanic arc system; however, the mechanism(s) that recycle sulfur from the slab into the overlying volcanic arc are debated. Here we summarize recent advances in quantifying this component of the deep sulfur cycle. First, primary metamorphic or inherited sulfides in oceanic-type eclogites are only rarely observed as inclusions and are typically absent from the rock matrix. Additionally, sulfides are relatively common in rocks metasomatized at the slab-mantle interface by slab-derived fluids during exhumation. Combined, these two observations suggest that sulfur loss from subducted mafic crust is relatively efficient. Thermodynamic modeling in Perple_X using the Holland and Powell (2011) database combined with the Deep Earth Water model suggests that the efficiency and speciation of sulfur loss varies depending on the degree of seafloor alteration prior to subduction and the geothermal gradient of the slab. In relatively cold subduction zones, such as Honshu, slab-fluids derived from subducted mafic crust are predicted to exhibit elevated concentrations of HSO4-, SO42-, HSO3-, and CaSO4(aq), whereas hot subduction zones, such as Cascadia, are predicted to produce slab fluids enriched in HS- and H2S at lower pressures. The oxidation of sulfur expelled from subducted pyrite is balanced by the reduction of Fe3+ to Fe2+, consistent with the low Fe3+/SFe of exhumed eclogites relative to blueschists and altered oceanic crust. Where oxidized S-bearing fluids are produced, they are anticipated to interact with more reduced rocks at the slab-mantle interface and within the mantle wedge, resulting in sulfide precipitation and significant isotopic fractionation. The δ34S values of slab fluids are estimated to fall between -11 and +8 ‰. Rayleigh fractionation during progressive fluid-rock interaction results in fractionations of tens of per mil as oxidized species are depleted and sulfides are precipitated, resulting in δ34S values of sulfides that easily span the -21.7 to +13.9 ‰ range observed in metasomatic sulfides in exhumed high-pressure rocks. However, in subduction zones where reduced species prevail, the S isotopic signature of slab fluids is expected to reflect their source and will exhibit a narrower range in δ34S values. As a result, the δ34S values measured in arc magmas may not always be a reliable indicator of the contribution of different components of the slab, such as sediments vs. AOC. Additionally, the impact of S recycling on the oxygen fugacity of arc magmas is expected to vary both spatially and temporally throughout Earth history.

How to cite: Walters, J., Cruz-Uribe, A., and Marschall, H.: Sulfur in the slab: A sulfur-isotopes and thermodynamic-modeling perspective from exhumed terranes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11697, https://doi.org/10.5194/egusphere-egu22-11697, 2022.

High-pressure COH fluids have a fundamental role in a variety of geological processes. Their composition in terms of volatile species can control the solidus temperature, carbonation/decarbonation reactions, and influences the amount of solutes generated during fluid-rock interaction at depth. Over the last decades, several systems have been experimentally investigated to unravel the effect of COH fluids at upper mantle conditions. However, fluid composition is rarely tackled as a quantitative issue, and rather infrequently fluids are analyzed in the same way as the associated solid phases in the experimental assemblage. A comprehensive characterization of carbon-bearing aqueous fluids in terms of composition is hampered by experimental difficulties in synthetizing and analyzing high-pressure fluids, without altering their composition upon quench.

Recently, improved ex situ techniques have been proposed for the analyses of experimental COH fluids, leading to significant advancement in synthetic fluids characterization. The development of customized techniques in order to investigate these fluids, in terms of volatile speciation and dissolved solute load, allowed to elucidate some of the processes involving carbon at high-pressure conditions and to assess its influence in the mantle wedge.

Some of the recently developed techniques employed for ex situ quantitative analyses of carbon-saturated COH fluids will be presented, such as the capsule piercing QMS technique (Tiraboschi et al., 2016) and the cryogenic LA-ICP-MS technique (Kessel et al., 2004; Tiraboschi et al., 2018). The capsule piercing QMS technique allow to measure the main uncharged volatile species in the COH system (i.e., H2O, CO2, CH4, H2, O2, CO), while the cryogenic LA-ICP-MS technique permits to measure the amount solutes generated by mineral dissolution in COH fluids, in terms of mol/kg.

The results obtained by employing these analytical strategies indicate that a quantitative approach to COH fluid analyses is a fundamental step to understand the effect of carbon-bearing fluids at upper mantle conditions and to ultimately unravel the deep cycling of carbon.

 

Kessel, R., Ulmer, P., Pettke, T., Schmidt, M. W. and Thompson, A. B. (2004) A novel approach to determine high-pressure high-temperature fluid and melt compositions using diamond-trap experiments, Am. Mineral., 89(7), 1078–1086.

Tiraboschi, C., Tumiati, S., Recchia, S., Miozzi, F. and Poli, S. (2016) Quantitative analysis of COH fluids synthesized at HP–HT conditions: an optimized methodology to measure volatiles in experimental capsules, Geofluids, 16(5), 841–855.

Tiraboschi, C., Tumiati, S., Sverjensky, D., Pettke, T., Ulmer, P. and Poli, S. (2018) Experimental determination of magnesia and silica solubilities in graphite-saturated and redox-buffered high-pressure COH fluids in equilibrium with forsterite + enstatite and magnesite + enstatite, Contrib. to Mineral. Petrol., 173(1), 1–17.

How to cite: Tiraboschi, C.: Carbon-saturated COH fluids in the upper mantle: what ex situ experiments tell us about carbon at high-pressure and high-temperature conditions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11725, https://doi.org/10.5194/egusphere-egu22-11725, 2022.

EGU22-11784 | Presentations | GMPV2.2

Elemental and lithium isotopic signature of fluids in metapelites from ancient subduction zones 

Kristijan Rajic, Hugues Raimbourg, Antonin Richard, Catherine Lerouge, Romain Millot, and Clement Herviou

The objective of this work is to study the fluid rock-interactions at low metamorphic grade in subduction zones. We focused in particular on the evolution of metapelites from the base of the seismogenic zone (⁓250℃) to the down-dip transition to the aseismic domain (⁓330℃). In the three examples examined here (Kodiak Complex in Alaska, Shimanto Belt in Japan, the French Alps), we followed the variations in mineralogy, trace element budget, as well as fluid inclusion elemental and isotopic (δ7Li) composition.

In the Kodiak and Shimanto belt, the mineralogy remains constant with temperature increase, with the dominance of phyllosilicates (white mica and chlorite), quartz and plagioclase. In more deformed zones of higher-T samples (330 ± 16℃ and 3 ± 0.4 kbar for Kodiak and 320 ± 14℃ and 3.9 ± 0.4 kbar for Shimanto belt) quartz and plagioclase are completely dissolved, while large white mica and chlorite grains crystallized. Also, the chlorite/white mica ratio is higher with temperature increase.

White mica is a main host for B, LILE and to smaller extent for Li. Plagioclase hosts the same elements but in lower concentrations. Chlorite is a main host for Li ± B and quartz hosts Li to smaller extent than chlorite and mica. Bulk rock analysis revealed partial loss in B, Rb, Sr and Cs with temperature increase, in contrast to the retention of Li and Ba. Mass balance based on trace element concentrations of individual phases and their proportion point to a reorganization of elements released during quartz and plagioclase dissolvement and phyllosilicate recrystallization: Rb, Cs and Ba released from plagioclase are incorporated in higher grade mica, Li released from mica and quartz is incorporated into chlorite. In the lack of newly formed phase as a host, B and Sr are probably released into a fluid.

The salinity at 250°C is around 2wt.% NaCl eq., i.e. lower than original pore-filling seawater. The freshening can be accounted for by smectite dehydration and transformation into illite. From 250 to 330°C, a salinity increase is observed, up to 3.5wt.%, possibly related to the chlorite crystallization requiring higher amount of water. The fluid is highly enriched in fluid-mobile elements in comparison with seawater. δ7Li values of fluid inclusion leachates are distinct for each locality: +8.1 to +17.07‰, in the Kodiak, +2.53 to +10.39‰ in the Shimanto belt and -1.54 to +9.54 ‰ in the western Alps. δ7Li of fluids is independent of other parameters, such as temperature or Li concentration.

Mineral reactions and fluid-mobile elements concentration in phases point to overall a local redistribution of fluid-mobile elements between phases, except for minor release of B and Sr. Lithium isotopes, which show that δ7Li of fluid is possibly buffered by host rock, confirm the fact that the rocks behaved to a large extent as a closed system during burial and subsequent exhumation.

How to cite: Rajic, K., Raimbourg, H., Richard, A., Lerouge, C., Millot, R., and Herviou, C.: Elemental and lithium isotopic signature of fluids in metapelites from ancient subduction zones, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11784, https://doi.org/10.5194/egusphere-egu22-11784, 2022.

EGU22-11854 | Presentations | GMPV2.2

Iron mobility in slab-derived hydrous silicate melts at sub-arc conditions 

Carla Tiraboschi, Rohrbach Arno, Klemme Stephan, Berndt Jasper, and Sanchez-Valle Carmen

Aqueous and saline fluids have a fundamental role in subduction zones and represent a major vector of mass transfer from the slab to the mantle wedge. In this setting, assessing the mobility of redox sensitive elements, such as iron, in aqueous fluids and melts is essential to provide insights on the oxygen fugacity conditions of slab-derived fluids and the oxidation state of arc magmas.

We experimentally investigate the solubility of magnetite and hematite in water-saturated haplogranitic melts, which represent the felsic melt produced by subducted eclogites. Experiments were conducted at 1–2 GPa and temperature ranging from 700 to 950 °C employing an endloaded piston cylinder apparatus. Single gold capsules were loaded with natural hematite, magnetite and synthetic haplogranite glass. Two sets of experiments were conducted: a first set with pure H2O and a second set with a 1.5 m H2O-NaCl solution. After quench, the presence of H2O in the haplogranite glass was verified by Raman spectroscopy, while iron and major element contents were determined by electron microprobe analysis.

Results show that a significant amount of FeO is released from magnetite and hematite equilibrated with hydrous melts, up to 1.96 ± 0.04 wt% at 1 GPa and 950 °C. In the presence of NaCl, we observed an increase in the amount of iron in the haplogranite glass, e.g. from 1.04 ± 0.12 wt% to 1.50 ± 0.31 wt% of FeOtot at 800 °C. These concentrations are substantially higher than the iron solubility in aqueous and saline fluids predicted by thermodynamic modelling (DEW model, Sverjensky et al., 2014), likely due to formation of Fe- and Si-bearing complex in the haplogranite-bearing fluid at run conditions. Our results suggest that hydrous melts can effectively mobilize iron from Fe-oxides even at relatively low-pressure conditions. Slab-derived hydrous melts can thus represent a valid agent for mobilizing iron from the subducting slab to the mantle wedge, and can strongly influence the geochemical cycles of Fe and the redox conditions of subduction zone fluids.

 

Sverjensky, D. A., Harrison, B. and Azzolini, D. (2014) Water in the deep Earth: The dielectric constant and the solubilities of quartz and corundum to 60kb and 1200°C, Geochim. Cosmochim. Acta, 129, 125–145

How to cite: Tiraboschi, C., Arno, R., Stephan, K., Jasper, B., and Carmen, S.-V.: Iron mobility in slab-derived hydrous silicate melts at sub-arc conditions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11854, https://doi.org/10.5194/egusphere-egu22-11854, 2022.

EGU22-13148 | Presentations | GMPV2.2

Rupture of serpentinized mantle wedge by self-promoting carbonation: insights from Sanbagawa metamorphic belt 

Atsushi Okamoto, Ryosuke Oyanagi, Kazuki Yoshida, Masaoki Uno, Hiroyuki Shimizu, and Madhusoodhan Satish-Kumar

The slab-mantle interface is one of the most active sites of fluid-rock interaction, which affects the mass transfer and mechanical properties along subduction zone megathrust. However, the effects of CO2 fluids and carbonation/decarbonation reactions on seismic activity are still poorly understood. In addition, although mantle peridotite is known as a large sink of CO2, the nature of carbonation at mantle wedge condition remains unconstrained. In this study, we show the characteristics of carbonation of serpentinite body from the Sanbagawa metamorphic belt, Kanto Mountain, Japan [1]. The Higuchi serpentinite body (8 x15 m) is mainly composed of antigorite, and has not relics of olivine and pyroxenes. Massive antigorite parts are segmented by talc + carbonates (magnesite, dolomite and calcite) veins. At the boundary between serpentinite body and pelitic schists, actinolite-chlorite schist and chlorite rocks were formed. The location, depleted composition of Cr-rich spinel in the Higuchi body and temperature of ~400 ˚C of carbonation suggest that this body was originated from the leading edge of the mantle wedge. The carbon and oxygen stable isotope compositions of carbonates within the Higuchi body reveal that carbonic fluid was derived from carboniferous materials in sediments. Carbonation of serpentinite body is characterized by gains of CO2, silica and Ca, and losses of H2O and Mg. The thermodynamic calculations on mineral-fluid equilibria reveal that (1) the carbonic fluid produced under the oxidizing conditions (QFM +0.3) explains the systematic mineralogical variations within the Higuchi body, and that (2) carbonation of serpentinite proceeded with solid volume contraction, high fluid pressure and high mobility of Mg, which is largely consistent with the experimental carbonation at the mantle wedge condition [2]. This is consistent with the tree-like patterns of carbonate veins within the Higuchi body. Brittle failure to form carbonate veins was followed by a viscos flow of carbonate and talc. We infer that episodic infiltration of oxidizing fluids causes self-promoting carbonation of mantle wedge with solid volume change, which could affect the mechanical properties of slab-mantle interface.

[1] Okamoto, A, et al., 2021. Com Env Earth, 58, 4831-4839. doi.org/10.1038/s43247-021-00224-5

[2] Sieber et al. 2020. J. Petrol., 1-24. doi: 10.1093/petrology/egaa035

How to cite: Okamoto, A., Oyanagi, R., Yoshida, K., Uno, M., Shimizu, H., and Satish-Kumar, M.: Rupture of serpentinized mantle wedge by self-promoting carbonation: insights from Sanbagawa metamorphic belt, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13148, https://doi.org/10.5194/egusphere-egu22-13148, 2022.

EGU22-13287 | Presentations | GMPV2.2

Reconciling extensive mantle hydration at subduction trenches and limited deep H2O fluxes 

Diane Arcay, Nestor Cerpa, and José Alberto Padrón-Navarta

The long-term global sea level depends on the balance of H2O exchanges between the Earth's mantle and the surface through both volcanism (mantle degassing) and subduction of hydrous minerals (mantle regassing). The estimates of H2O fluxes by the current thermopetrological subduction models predict that regassing exceeds degassing by 60%, which may lead to a sea-level drop of at least a hundred meters in the last 540 Ma [Parai & Mukhopadhyay, 2012, Earth Planet. Sc. Lett., 317, 396-406. https://doi.org/10.1016/j.epsl.2011.11.024. These models further imply a moderate ( Tg/Myr) global input of H2O at the subduction trenches. In contrast, geological constraints suggest a near-steady state of long-term sea level while geophysical observations advocate for a larger global H2O input, especially given the large amounts of hydrated lithospheric mantle that are inferred at present-day subduction trenches. To address this paradox, we revise the subduction-H2O flux calculations using recently published experimental data on natural hydrated peridotites at high-pressure conditions, which suggest that all hydrated phases destabilize below 800˚C for pressures higher than 8 GPa [Maurice et al., 2018, Contrib. Mineral. Petrol, 173(10), 86. https://doi.org/10.1007/s00410-018-1507-9 ]. Our reassessed thermopetrological models show that a prominent global H2O input ( Tg/Myr), mainly conveyed by the layer of subducted serpentinized mantle, is compatible with a limited global H2O retention in subducted slabs at mid-upper mantle depths ( Tg/Myr), including in models that consider some worldwide variability of the input serpentine. We also show that the global H2O retention at mid-upper mantle depths is only driven by the hydrated mantle of coldest subducting plates. Overall, our models show that the present-day global water retention in subducting plates beyond mid-upper mantle depths barely exceeds the estimations of mantle degassing, and thus quantitatively support the stable-sea level scenario over geological times.

How to cite: Arcay, D., Cerpa, N., and Padrón-Navarta, J. A.: Reconciling extensive mantle hydration at subduction trenches and limited deep H2O fluxes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13287, https://doi.org/10.5194/egusphere-egu22-13287, 2022.

EGU22-13297 | Presentations | GMPV2.2

Experimental constraints on the nature of multiphase solid inclusions and their bearing on mantle wedge metasomatism, Bohemian Massif 

Antonio Acosta Vigil, Jana Kotková, Renata Copjaková, Richard Wirth, and Jörg Hermann

Fluids are the primary agents for mass transfer in subduction zones. These fluids can be captured as primary inclusions within minerals crystallizing during subduction processes. Some of these inclusions, referred to as multiphase solid inclusions (MSI), are characterized by the high proportion and variety of minerals, hence by a high concentration of solute in the trapped fluid. Kotková et al. (2021) have described primary MSI in garnets of subduction-related ultra-high pressure (UHP) peridotites (P-T of 1030-1150 ºC/3.6-4.8 GPa) of the Bohemian Massif. MSI range in size between ≈5-40 µm and are mostly composed of hornblende, the barian mica kinoshitalite, dolomite and magnesite. MSI have been interpreted as trapped residual liquids produced after partial UHP crystallization of carbonate-silicate melts that now form garnet pyroxenite veins in the peridotites. Experimental re-melting of MSI is the best procedure to investigate the precise nature of trapped fluids. We have conducted re-melting experiments of MSI present in garnets of a lherzolite, taking the inclusions to P-T around their entrapment conditions at or close to host rock peak P-T, 4-4.5 GPa and 1000-1225 ºC. The inclusions (re-)crystallized into a garnet fringe at the boundary between inclusions and host garnet, barian mica and carbonatite melt towards the center of the inclusion, and a large irregular and empty space in between the garnet fringe and the central silicate-carbonate component. Microstructures and mass balance indicate that the empty space was occupied by a Na-K-Cl-F-rich saline aqueous fluid (brine). Hence experiments did not produce a single melt at any experimental conditions, but systematically show the stability and coexistence of barian mica + carbonatite melt + brine at the entrapment conditions, and a garnet fringe indicating reaction between trapped fluids and host garnet. This suggest that growing garnet trapped a carbonatite melt and a saline aqueous fluid coexisting in the matrix, together with solid crystals of barian mica likely produced by metasomatism of the percolating fluids through the host peridotite. It is intriguing, however, that neither single mica crystals nor separate former carbonate melt and brine have been found included in garnets. Mass balance shows that carbonate melt is the main host for incompatible elements such as Ba. This presentation will discuss the bearings of the experimental results on the nature and origin of these MSI, potential links to diamond formation and their implication on mass transfer processes in subduction zones.

Kotkova et al. (2021) Lithos 398-399, 106309

How to cite: Acosta Vigil, A., Kotková, J., Copjaková, R., Wirth, R., and Hermann, J.: Experimental constraints on the nature of multiphase solid inclusions and their bearing on mantle wedge metasomatism, Bohemian Massif, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13297, https://doi.org/10.5194/egusphere-egu22-13297, 2022.

TS8 – Strike-slip tectonic settings

EGU22-1070 | Presentations | TS8.1

Looking beyond kinematics: 3D thermo-mechanical modelling reveals the dynamics of transform margins 

Anthony Jourdon, Charlie Kergaravat, Guillaume Duclaux, and Caroline Huguen

Transform margins represent ~30% of nonconvergent margins worldwide. Their formation and evolution have traditionally been addressed through kinematic models that do not account for the mechanical behaviour of the lithosphere. In this study, we use high-resolution 3D numerical thermo-mechanical modelling to simulate and investigate the evolution of intra-continental strain localization under oblique extension. The obliquity is set through velocity boundary conditions that range from 15 (high obliquity) to 75 (low obliquity) every 15 for rheologies of strong and weak lower continental crust. Numerical models show that the formation of localized strike-slip shear zones leading to transform continental margins always follows a thinning phase during which the lithosphere is thermally and mechanically weakened. For low- (75) to intermediate-obliquity (45) cases, the strike-slip faults are not parallel to the extension direction but form an angle of 20 to 40 with the plate motion vector, while for higher obliquities (30 to 15) the strike-slip faults develop parallel to the extension direction. Numerical models also show that during the thinning of the lithosphere, the stress and strain re-orient while boundary conditions are kept constant. This evolution, due to the weakening of the lithosphere, leads to a strain localization process in three major phases: (1) initiation of strain in a rigid plate where structures are sub-perpendicular to the extension direction; (2) distributed deformation with local stress field variations and formation of transtensional and strikeslip structures; (3) formation of highly localized plate boundaries stopping the intra-continental deformation. Our results call for a thorough re-evaluation of the kinematic approach to studying transform margins.

How to cite: Jourdon, A., Kergaravat, C., Duclaux, G., and Huguen, C.: Looking beyond kinematics: 3D thermo-mechanical modelling reveals the dynamics of transform margins, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1070, https://doi.org/10.5194/egusphere-egu22-1070, 2022.

EGU22-1979 | Presentations | TS8.1

Extensional tectonics at oceanic transform plate boundaries: evidence from seafloor morphology 

Yu Ren, Jacob Geersen, and Ingo Grevemeyer

Oceanic transform faults are among the most prominent morphologic features in ocean basins, offsetting mid-ocean ridges by tens to hundreds of kilometers. Since the inception of plate tectonics, transform faults have been assumed to be simple, two-dimensional strike-slip, conservative plate boundaries, where lithosphere is neither created nor destroyed. This concept nurtured an over-simplified understanding of oceanic transform faults for many decades. New advances in seafloor mapping revealed that the morphology of oceanic transform faults is difficult to explain exclusively by strike-slip faulting and differential thermal subsidence. We compiled ship-based bathymetric data of 94 oceanic transform faults, and parameterized their morphological characteristics (e.g., length, width, depth, etc.) using quantitative geomorphologic methods. A prominent feature of most oceanic transform plate boundaries is a deep valley extending along the active transform fault. Our statistical analysis indicates that these valleys are generally deeper and wider at slow- and ultraslow-slipping rates than at faster slipping rates. However, the key feature that governs structural variability, seems to be age-offset across a transform fault rather than spreading rate. While the correlation between transform morphology and spreading rate turns out to be rather weak, our statistical results consistently show that transform valleys get deeper and wider with increasing age-offset. The surface deformation pattern observed therefore supports the tectonic extension scaling with age-offset predicted by recent geodynamic simulations (Grevemeyer et al., 2021). Furthermore, at small age-offsets (< 5 Myr), scatters especially in the depth of transform valley increase, indicating that small-age-offset transforms corresponding to weak lithospheric strength are easily affected by secondary tectonic processes, such as nearby hotspots and changes in plate motion. Now, five decades after Wilson (1965) published his seminal paper on transform faults, our quantitative submarine geomorphologic study emphasizes that oceanic transform faults are not simple conservative strike-slip plate boundaries, but that tectonic extension is an integral process affecting their morphology. The larger age-offset causes greater extension at OTFs and hence wider and deeper valleys as evidenced by our statistics on transform morphology.

References

Wilson, J. T. (1965), A new class of faults and their bearing on continental drift. Nature, 207, 343–347. doi: 10.1038/207343a0

Grevemeyer, I., Rüpke, L. H., Morgan, J. P., Iyer, K., & Devey, C. W. (2021), Extensional tectonics and two-stage crustal accretion at oceanic transform faults. Nature, 591, 402–407. doi: 10.1038/s41586-021-03278-9

How to cite: Ren, Y., Geersen, J., and Grevemeyer, I.: Extensional tectonics at oceanic transform plate boundaries: evidence from seafloor morphology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1979, https://doi.org/10.5194/egusphere-egu22-1979, 2022.

EGU22-2128 | Presentations | TS8.1

A kink in the plate boundary, rotation and transtension: new 4d insights into the tectonics of the southern Dead Sea Transform 

Jakub Fedorik, Abdulkader Afifi, Frank Zwaan, and Guido Schreurs

The southern Dead Sea Transform (SDST) is an active left-lateral transform plate boundary that extends from the Sinai triple junction to the Lebanon restraining bend, separating the Arabian and Sinai plates. In this study, we analyze structural variations along the SDTS, and reproduce these variations in a 4D analogue model.  

From south to north, the structural styles along the SDTS indicate (1) rotational transtension within the Gulf of Aqaba, (2) pure strike-slip in Wadi Araba and Jordan River valley, and (3) pull-apart basins in the Dead Sea, Sea of Galilee and Hula basin. These different structural styles were replicated experimentally in an analogue model incorporating transtension with minor rotation along a kinked plate boundary. Our 4D model produced a deep southern depression with en echelon faults corresponding to the Gulf of Aqaba, a simple strike-slip fault system without vertical displacement reflecting the Wadi Araba and Jordan Valley, and a set of pull-apart basins reminiscent of the Dead Sea, Sea of Galilee and Hula basins. The accurate reproduction of the structural styles along this 600km-long plate boundary segment constrains the relative movement between the Arabian and Sinai plates to a simple combination of transtension with minor rotation, thereby negating the earlier hypothesis of Euler pole shift during the tectonic evolution of the SDST. 

How to cite: Fedorik, J., Afifi, A., Zwaan, F., and Schreurs, G.: A kink in the plate boundary, rotation and transtension: new 4d insights into the tectonics of the southern Dead Sea Transform, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2128, https://doi.org/10.5194/egusphere-egu22-2128, 2022.

EGU22-2279 | Presentations | TS8.1 | Highlight

The Oceanographer transform fault revisited – preliminary results from a micro-seismicity survey reveals extensional tectonics at ridge-transform intersections 

Ingo Grevemeyer, Dietrich Lange, Ingo Klaucke, Anouk Beniest, Laura Gómez de la Peña, Yu Ren, Helene-Sophie Hilbert, Yuhan Li, Louisa Murray-Bergquist, Katharina Unger, Colin W. Devey, and Lars Ruepke

Fracture zones were recognized to be an integral part of the seabed long before plate tectonics was established. Later, plate tectonics linked fracture zones to oceanic transform faults, suggesting that they are the inactive and hence fossil trace of transforms. Yet, scientist have spent little time surveying them in much detail over the last three decades. Recent evidence (Grevemeyer, I., Rüpke, L.H., Morgan, J.P., Iyer, K, and Devey, C.W., 2021, Extensional tectonics and two-stage crustal accretion at oceanic transform faults, Nature, 591, 402–407, doi:10.1038/s41586-021-03278-9) suggests that the traditional concept of transform faults as being conservative (non-accretionary) plate boundary faults might be wrong. Instead, transform faults are always deeper than the associated fracture zones and numerical modelling results suggest that transform faults seem to suffer from extensional tectonics below their strike-slip surface fault zone. During the cruise M170 of the German research vessel METEOR early in 2021, we aimed to test this hypothesis by collecting, in a pilot study, micro-seismicity data from the Oceanographer transform fault which offsets the Mid-Atlantic Ridge by 120-km south of the Azores near 35°N. Preliminary analysis of 10-days of seismicity data recorded at 26 ocean-bottom-seismometers and hydrophones showed 10-15 local earthquakes per day. Along the transform fault the distribution of micro-earthquakes and focal mechanisms support strike-slip motion. However, at both ridge-transform intersections seismicity does not mimic a right-angular plate boundary; instead, seismicity occurs below the inside corner and focal mechanism indicate extensional tectonics. Therefore, micro-seismicity supports features found in numerical simulations, revealing that transform faults have an extensional as well as a strike-slip component.

How to cite: Grevemeyer, I., Lange, D., Klaucke, I., Beniest, A., Gómez de la Peña, L., Ren, Y., Hilbert, H.-S., Li, Y., Murray-Bergquist, L., Unger, K., Devey, C. W., and Ruepke, L.: The Oceanographer transform fault revisited – preliminary results from a micro-seismicity survey reveals extensional tectonics at ridge-transform intersections, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2279, https://doi.org/10.5194/egusphere-egu22-2279, 2022.

EGU22-3802 | Presentations | TS8.1

Post-5 Ma rock deformation on Alonnisos (Greece) constrains the propagation of the North Anatolian Fault 

Kristóf Porkoláb, Ernst Willingshofer, Dimitrios Sokoutis, Eszter Békési, and Fred Beekman

The localization of the North Anatolian Fault in the northern Aegean Sea (North Aegean Trough) is an intriguing example of continental transform fault propagation. Understanding this process critically depends on quantifying the amount of strike-slip displacement and the superposition of normal and strike-slip faulting in the region, which is the aim of this study. In particular, we unravel and quantify normal and dextral faulting along the Alonnisos fault system, at the south-western margin of the North Aegean Trough (Sporades Basin), in order to constrain the spatial and temporal evolution of the basin and the North Anatolian Fault. We present detailed structural data collected from Messinian strata of Alonnisos to infer the amount of tilting and shortening and to constrain normal and dextral faulting along the Alonnisos fault system through simple analytical half-space models of dislocations. The Messinian rocks of Alonnisos record significant tilting and gentle folding close to the termination zone of the main fault segment. The tilting of the Messinian rocks implies footwall uplift in the order of 6-7 km (vertical displacement) during normal faulting on the boundary fault system, which lead to post 5 Ma substantial deepening of the Sporades Basin. The post-Messinian folding accommodated ~ 1 km shortening at the footwall termination zone of the Alonnisos fault, which implies a dextral slip of 3-4 km. Our results support the models of currently distributed dextral strain in the North Aegean in response to the propagation of the North Anatolian Fault. However, similarities with the evolution of the Sea of Marmara might suggest that dextral shear could yet become fully localized in the NAT in the next few Myrs.

How to cite: Porkoláb, K., Willingshofer, E., Sokoutis, D., Békési, E., and Beekman, F.: Post-5 Ma rock deformation on Alonnisos (Greece) constrains the propagation of the North Anatolian Fault, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3802, https://doi.org/10.5194/egusphere-egu22-3802, 2022.

EGU22-4993 | Presentations | TS8.1

A new model for the evolution of oceanic transform faults based on 3D PSDM Seismic observations from São Tomé and Príncipe, eastern Gulf of Guinea. 

Christian Heine, Myron Thomas, Jimmy van Itterbeeck, Ilya Ostanin, Andrey Seregin, Michael Spaak, Tamara Morales, and Tess Oude Essink

Oceanic Transform faults are one of the three major tectonic plate boundaries and yet their evolution and deformational mechanism is not well understood. They are broadly considered to be dominated by strike-slip displacement along simple planar vertical faults and to be conservative in nature with no magmatic addition. Observations from Pre-Stack depth-migrated (PSDM) 3D seismic of Cretaceous-aged transforms in the eastern Gulf of Guinea allow complex internal architectures to be described, including crustal scale detachments and rotated packages of volcanics.

These insights demonstrate additional complexity previously only predicted in numerical simulations of spreading ridge-transform interaction, namely intra-transform extension at a high angle to the spreading orientation, and the addition of significant extrusive volcanic material. In the study area of São Tomé and Príncipe, several Oceanic Fracture Zones (OFZ) are identified, consisting of a broad deformational zones that can be described from top to base crust. OFZ scarps are observed to connect at depth with zones of low angle reflectivity which dip into the OFZ and perpendicular to the spreading orientation. At depth they detach onto the Moho below, necking the adjacent crust along the length of the OFZ in the manner of extensional shear zones. Thickly stacked and tilted reflectors, interpreted as extrusive lava flows, are common above the shear zones and infill up to 75% of the crustal thickness. The entire OFZ stratigraphy is overlain and sealed by late-stage lavas that are continuous from the abyssal hills of the trailing spreading ridge. This constrains a process of oblique extension at a high angle to the spreading orientation along a low angle shear zone which also acts as a conduit for decompression related melt.

We demonstrate that transforms in São Tomé and Príncipe were both non-conservative and not a simple strike slip fault zone, contradicting the current understanding of modern systems. This style of deformation has similarities with anomalously deep and smooth nodal basins which form at slow spreading inside-corner crust. Our model adds strong observational constraints to complement recent numerical models that predict oblique extension within transform zones.

How to cite: Heine, C., Thomas, M., van Itterbeeck, J., Ostanin, I., Seregin, A., Spaak, M., Morales, T., and Oude Essink, T.: A new model for the evolution of oceanic transform faults based on 3D PSDM Seismic observations from São Tomé and Príncipe, eastern Gulf of Guinea., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4993, https://doi.org/10.5194/egusphere-egu22-4993, 2022.

EGU22-5427 | Presentations | TS8.1

3D geodynamic evolution of strike-slip restraining and releasing bends modulated by surface processes: application to the Dead Sea Transform 

Esther Heckenbach, Sascha Brune, Anne Glerum, and Derek Neuharth

The region around the Dead Sea Transform represents a unique example of the structures that form around restraining and releasing bends in a strike-slip environment. With our 3D numerical models, we aim to understand the processes that shaped the region including the Dead Sea Basin, the Dead Sea Transform Fault, and the Lebanese Restraining Bend.

In our study, we employ geodynamic modelling using the software ASPECT coupled to the surface processes code FastScape. Our model setup includes a compressive and a tensional stepover along a strike-slip fault with periodic along-strike boundary conditions. Even though we use a simplistic setup with horizontally homogeneous rock layers, we can reproduce many of the present-day features of the Dead Sea Transform region, including the sediment thicknesses in the Dead Sea basin, heat flow patterns, relative topographical height differences, and the general outlines and activity of the main faults along the Dead Sea basin, the Mount Lebanon and Anti Lebanon ranges.

With our models we can investigate the influence of surface processes on the underlying stepover strike-slip tectonics and the resulting crustal-scale flower structures: (1) Along the tensional stepover, the horizontal distance between the bounding faults of the pull-apart basin increases with greater efficiency of surface processes due to an increasing sediment load filling the basin. The sediments hinder the border faults in approaching each other at the surface, thereby enforcing basin-ward fault dip, resulting in wider and deeper basins with greater surface process efficiency. (2) In the uplifted compressive stepover, the erosional efficiency has a direct feedback on the longevity of faults and the rheological state of the crust through its influence on the uplift rate. Elevated erosion-induced uplift rates lead to a connection of the brittle parts of lower and upper crust, because the upper crustal viscous part is moved into a zone of lower temperatures and thus becomes brittle. This drastic change of the underlying rheology manifests in the formation of a new fault, which cuts through the centre of the compressional area. When no erosion is assumed a similar fault is observed in map view, but cross sections reveal that without erosion this fault has a different origin and the flower structure is more complex and more symmetric than for models that include erosion.

How to cite: Heckenbach, E., Brune, S., Glerum, A., and Neuharth, D.: 3D geodynamic evolution of strike-slip restraining and releasing bends modulated by surface processes: application to the Dead Sea Transform, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5427, https://doi.org/10.5194/egusphere-egu22-5427, 2022.

Passive and transform margins emerging during continental rifting and opening of oceanic basins are fundamental elements of plate tectonics. It has been suggested that inherited structures, variable plate divergence velocities and surface processes exert a first order control on the topographic, bathymetric and magmatic evolution and thermal history of these margins and related sedimentary basins. We conducted 3D thermo-mechanical numerical experiments with the code I3ELVIS coupled to surface processes modelling (FDSPM) to simulate the dynamics of continental rifting, continental transform fault zone formation and persistent oceanic transform faulting. Numerical modelling results allow to explain the first order observations from passive and transform margins, such as diachronous rifting, strain localization into individual oblique rift basins and the opening of structurally separate oceanic basins connected in an open marine environment. In addition, the models reproduce the rise of transform marginal ridges and submarine plateaus, continental crustal slivers within oceanic transforms and their interaction with erosion and sedimentation. Model results are compared and validated by seismic and well data from passive and transform margin segments of the Atlantic.

How to cite: Balazs, A., Gerya, T., May, D., and Tari, G.: Contrasting passive and transform margin tectonic history and sedimentation: insights from 3D numerical modelling and observations from the Atlantic, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8005, https://doi.org/10.5194/egusphere-egu22-8005, 2022.

EGU22-10112 | Presentations | TS8.1

Formation and Development of the San Andreas Fault System with Migration of the Mendocino Triple Junction 

Kevin P. Furlong and Kirsty A. McKenzie

The faults that accommodate Pacific - North America plate motion along the San Andreas plate boundary occupy a region that previously served as part of the upper plate of the Cascadia subduction zone plate boundary. After the passage of the Mendocino triple junction (MTJ), several fault systems develop within the newly formed Pacific-North America plate margin, with one fault system eventually evolving to become the primary plate boundary structure (termed the San Andreas Fault in central California). As a result of the northward migration of the MTJ, the Cascadia subduction zone, undergoing NNW-directed shortening at a rate of ~ 50 km/Ma, replaced by the equivalent lengthening of the San Andreas system.  In northern California, three primary fault systems are identified:  on the west (along the western margin of the North America plate) is the San Andreas fault (which does not serve as major component of the lithospheric scale plate boundary structure in northern California; moving inland (eastward) is the Maacama - Rodgers Creek (M-RC) fault system; further east is the Lake Mountain - Bartlett Springs (LM-BS) fault system.  These latter two faults primarily accommodate Pacific -North America motion in the region just to the south of the MTJ. 

New tomography imagery of this region of northern California provides crustal constraints on deformation and fault localization, both within Cascadia, north of the MTJ, and south of the transition from subduction to translation. Using these tomographic images and analyses of GPS data within the region, we have developed a tectonic model that both explains the present fault systems north and south of the MTJ, and helps us understand why one of these fault systems - the M-RC fault system - develops to become the primary plate boundary structure over several million years after MTJ passage. Two fundamental aspects of the North America and Pacific plates control the location of these primary fault systems - the existence of relatively rigid upper-plate backstops  (the Great Valley and Klamath blocks), and a small remnant (the Pioneer fragment) of the subducted Farallon plate accreted to the eastern margin of the Pacific plate and migrating northward with it. As a result of these structures, the LM-BS fault system develops as an upper-crust (brittle) fault system, while the M-RC system initially forms as a shear zone (ductile) along the eastern margin of the Pioneer fragment, with the upper-crustal faults developing in response to the deeper plate boundary shear zone. This lithospheric shear zone localizes the plate boundary development and leads to the M-RC system becoming the main plate boundary fault.

How to cite: Furlong, K. P. and McKenzie, K. A.: Formation and Development of the San Andreas Fault System with Migration of the Mendocino Triple Junction, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10112, https://doi.org/10.5194/egusphere-egu22-10112, 2022.

EGU22-10205 | Presentations | TS8.1

Linking the strike-slip kinematics of the Rennick Graben Fault system and the Aviator Fault from field structural data, North Victoria Land, Antarctica 

Paola Cianfarra, Francesco Salvini, Laura Crispini, Michele Locatelli, and Laura Federico

The North Victoria Land structural framework is characterized by the long-lived tectonic activity along major crustal lineaments, including the NNW-SSE and NW-SE trending Rennick Graben Fault (RGF) system and Aviator Fault (AF). This tectonic corridor is characterized by an important strike-slip component that is easily connected to the main strike-slip fracture zone that characterizes the Southern Ocean between Australia and East-Antarctica. Structural analysis of field data along the RGF evidences a poly-phased activity with multiple reactivations related to the Paleozoic juxtaposition of NVL to the East Antarctic craton (as resulting from the Gondwana breakup) and to the Meso-Cenozoic plate tectonics associated to the Australia-East Antarctica separation and characterized by both offshore and onshore crustal strike-slip deformation. Both the northward, offshore propagation of the RGF system and its southward prosecution and link with the AF are inferred but still need to be proved/better framed.

During the XXXVII Italian Antarctic campaign in the framework of the LARK project 92 field measurement sites have been surveyed between latitude 71.5°S and 73.5°S. To better frame the link between the RGF and AF the evidence of brittle deformation (including faults with the associated kinematic indicators and fracture attitude, dimension and sets) have been measured. This deformation involve rocks with ages ranging from Lower Paleozoic to Lower Jurassic. Where time constraints from stratigraphy are lacking and to better frame the age of the tectonics with its associated vertical displacement, ad hoc field samples have been collected for thermochronology dating.

Open, un-mineralized fracture sets are important indicator of recent paleo-stress (tectonic) activity, since their formation is limited to shallow depth and their presence testify a short erosion time, thus representing a good indicator of the last, recent stress regime. The intensity of brittle deformation associated to this last tectonic setting can be quantified by the H/S adimensional parameter, where H represents the size of the fracture and S is the spacing between nearest fractures belonging to the same azimuthal family and having comparable dimensions. This parameter has been proved (Cianfarra & Salvini 2016) to be proportional to the total energy released by the stress during fracture generation though time. The analysis of the recently collected field structural data is still in progress and will allow to prepare both a map of the spatial distribution of H/S values and to infer the (multiple) paleostress responsible for the observed brittle deformations by the application of original methodologies that include the inversion of fault and near orthogonal fracture systems. The latter inversion methodology solves both the identification and grouping of the fractures into the two systematic and non-systematic families, and the orientation of the responsible paleostress by a Monte Carlo approach.

Results from the central RGF system area shows the increase of the H/S values by approaching the RGF central zone, due to the increase of the local stress produced by its kinematics.

Cianfarra P. and Salvini F., (2016). Quantification of fracturing within fault damage zones affecting Late Proterozoic carbonates in Svalbard. Rend. Fis. Acc. Lincei, 27(19), 229-241. DOI 10.1007/s12210-016-0527-5

How to cite: Cianfarra, P., Salvini, F., Crispini, L., Locatelli, M., and Federico, L.: Linking the strike-slip kinematics of the Rennick Graben Fault system and the Aviator Fault from field structural data, North Victoria Land, Antarctica, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10205, https://doi.org/10.5194/egusphere-egu22-10205, 2022.

EGU22-11355 | Presentations | TS8.1

Cuba's northern offshore: a witness to geodynamics evolution of the northern boundary of the Caribbean plate 

Alana Oliveira de Sa, Sylvie Leroy, Elia D'Acremont, Sara La Fuerza, and Bernard Mercier de Lepinay

The northern boundary of the Caribbean plate is characterized by the oblique collision between the Caribbean (CAR) and North American (NOAM) tectonic plates. The progressive counterclockwise rotation of the two plates accompanying the eastward translation of NOAM vs. CAR is responsible for the increasing obliquity of the collision between these two plates. Consequently, successive southward jumps of major strike-slip faults accommodate the eastward escape of the Caribbean plate and the collisional indentation against the Bahama Banks. During this process, Cuba was progressively welded to the North American Plate. Several strike-slip corridors record this diachronous collision as major left-lateral transfer zones in Cuba: Eastern Yucatan Margin (Upper Cretaceous), Pinar-Varadero (Paleocene), La Trocha (early Eocene), Cauto-Nipe (middle/late Eocene), and Oriente Fault Zone (early Oligocene). The nature and age of the related tectonic events of these tectonic corridors were widely studied onshore. However, offshore northern Cuba remains relatively unknown. We provided a first offshore description of northeastern Cuba based on a multi-channel seismic reflection and swath-bathymetric dataset from the Haiti-SIS cruise. The seismic reflection profiles show that the structural and sedimentary architecture of the insular slope varies significantly from central to eastern Cuba. This lateral variability seems mainly influenced by the proximity with the Bahama Banks, which act as a succession of local indenters. The width of the insular slope varies from 5-10km in central Cuba to more than 50km in width towards the east off the Guacanayabo-Nipe tectonic corridor. In this region, the insular slope shows a thick sedimentary cover suggesting a main subsiding regional block related to the middle/late Eocene onset of the Guacanayabo-Nipe tectonic corridor. Contrasting lateral deformation patterns in this region are probably related to the diachronous strike-slip events related to the activity of the Cauto-Nipe fault. The coexistence of folds, transtensive and transpressive structures affecting the sedimentary infill attests that the local stress regimes of this fault have gradually changed. Our study correlates offshore deformation phases recorded in the offshore northeastern coast of Cuba, with major deformation episodes recorded onshore Cuba from Eocene to present-day. Our tectonostratigraphic evolution of the eastern offshore of Cuba provides new constraints to improve the knowledge of the geodynamics of the northern boundary of the Caribbean plate.

How to cite: Oliveira de Sa, A., Leroy, S., D'Acremont, E., La Fuerza, S., and Mercier de Lepinay, B.: Cuba's northern offshore: a witness to geodynamics evolution of the northern boundary of the Caribbean plate, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11355, https://doi.org/10.5194/egusphere-egu22-11355, 2022.

EGU22-12062 | Presentations | TS8.1

Quaternary Seismogenic Activity Along the Eastern Periadriatic Fault System: Dating of Fault Gouges via Trapped Charge Methods 

Erick Prince, Kamil Ustaszewski, Sumiko Tsukamoto, Christoph Grützner, and Marko Vrabec

The Periadriatic Fault System (PAF) is one of the most important tectonic and geomorphological features in the Alps. It has accommodated between 150-300 km of right-lateral strike-slip motion between the European and Adriatic plates from about 35 Ma until 15 Ma. However, for such a large-scale feature, the eastern PAF reveals relatively little instrumental and historical seismic activity, especially when compared to nearby structures in the adjacent Southern Alps. With this project, we aim to show which fault segments of the eastern PAF system accommodated seismotectonic deformation in the Quaternary by applying trapped charge dating methods to fault gouges produced by its activity. We use optically stimulated luminescence (OSL) and electron spin resonance (ESR). The principle for both is the accumulation of unpaired electrons in lattice defects of quartz and feldspar, due to natural radiation product of the decay of radiogenic nuclides, which are then released during an earthquake due to shear heating allowing the system to reset (Fukuchi 1992, Aitken 1998, Tsukamoto et al., in Tanner 2019). Due to their dating range (a few decades to ~1Ma) and low closing temperature, trapped charge methods provide a unique opportunity to date earthquake activity during the Quaternary at near-surface conditions. During our field campaigns, we collected 19 fault gouge samples from 15 localities along the PAF, the Labot/Lavanttal fault, and the Šoštanj fault. From each locality, we controlled the structures found in the field, which allowed us to relate the observed deformation features in outcrop scale to the activity along each fault. Aside from the fault gouge in the cores of the large-scale structures at the sampled localities, we additionally found gouge and cataclasites formed within the host rocks in small-scale faults presenting the orientation of the respective regional fault, providing supplementary evidence of activity.

How to cite: Prince, E., Ustaszewski, K., Tsukamoto, S., Grützner, C., and Vrabec, M.: Quaternary Seismogenic Activity Along the Eastern Periadriatic Fault System: Dating of Fault Gouges via Trapped Charge Methods, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12062, https://doi.org/10.5194/egusphere-egu22-12062, 2022.

EGU22-12463 | Presentations | TS8.1

East African Fracture Zones: a long lifespan since the breakup of Gondwana 

Vincent Roche, Sylvie Leroy, Jean-Claude Ringenbach, François Sapin, Sidonie Revillon, François Guillocheau, William Vetel, and Louise Watremez

Gondwana splitting started during the Early Jurassic (ca. 180 Ma) with the separation of Antarctica and Madagascar from Africa, followed by the separation of South America and Africa during the Middle Jurassic. Thanks to recent seismic profiles for petroleum exploration, the architecture of rifted margins and the transform faults zones, which developed as a result of the relative motion between tectonic plates have been recently evidenced and studied along the whole eastern and south-eastern Africa (i.e., in the Western Somali Basin, the Mozambique Basin, the Natal Basin, and the Outeniqua Basin). Yet, the structure and overall kinematic evolution of the three major transform faults zones together – i.e., the Agulhas, the Davie, and the Limpopo Fracture Zones – that control the opening of these major oceanic basins remain poorly studied. The interpretation of an extensive regional multichannel seismic dataset coupled with recent studies allows us to propose an accurate regional mapping of the crustal domains and major structural elements along the rifted margins along the whole eastern and south-eastern Africa. We provide new constraints on the structuration and evolution of these three transform systems. Although our findings indicate common features in transform style (e.g., a right-lateral transform system, a wide sheared corridor), the deformation and the thermal regime along these systems appear quite different. In particular, we show that the Davie and Agulhas Fracture Zones recorded spectacular inversions during the transform stage whereas transtensional deformation is observed along the Limpopo Fracture Zone during its activity. This suggests that faults activity controls vertical displacements along transform margins, minimising other processes such as thermal exchanges between the oceanic and continental lithospheres across the transform fault and flexural behaviour of the lithosphere. This different style of deformation may be explained by two main forcing parameters: (i) the magmatic conditions that may modify the rheology of the crust, and (ii) the far-field forces that may induce a rapid change of regional tectonic stress. Further, in the Davie and Agulhas cases, the major transform faults postdate the development of the rift zone-controlling faults. Thus, there are no pre-existing structures that control the initiation of a transform fault zone. Conversely, the Limpopo margin shows an intracontinental transform faulting stage. In both cases, a minimum of several Ma is required to establish a complete kinematic linkage between the two-active spreading centers. During this period, the rifted segments opening possibly triggered rift-parallel mantle flow, which progressively favors the decoupling in-between the continental domain and the future oceanic domain. In the post-drift history, rapid changes of regional tectonic stress are recorded and show that some transform margins are excellent recorders of large plate kinematic changes.

How to cite: Roche, V., Leroy, S., Ringenbach, J.-C., Sapin, F., Revillon, S., Guillocheau, F., Vetel, W., and Watremez, L.: East African Fracture Zones: a long lifespan since the breakup of Gondwana, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12463, https://doi.org/10.5194/egusphere-egu22-12463, 2022.

TS9 – Modelling tectonic processes

Modelling studies show that subduction initiation requires failure of the load-bearing crustal and mantle layers and critically depends on the buoyancy and strength contrast within the lithosphere. Such findings suggest that the probability of subduction initiation must increases in the vicinity of continental margins. Yet, direct evidence for subduction initiation at passive margin is scarce and the mechanisms of subduction initiation in this particular setting remains a recurrent and long-standing unresolved question. Therefore, our study focuses on the kinematic and rheologic key parameter combinations relevant for the formation of a subduction zone, with the aim of identifying the feasibility of subduction initiation at a passive margin setting. To challenge the existing limits and discriminate processes that fit conditions for subduction nucleation, we compare and combine analogue and numerical modelling techniques. In this work, numerical modelling allows exploring temperature driven feedback mechanisms whereas analogue modelling allows for mapping characteristic length scales of deformation against the mode of subduction initiation. Overall, model results highlight that the convergence rate, the strength contrast at the margin as well as the degree of crust-mantle coupling control the development of a shear zone at the base of the crust, and the propagation of deformation into the mantle lithosphere. In addition, comparison between analogue and numerical modelling results infers that shear heating, weak sediments, magmatic heterogeneities or a serpentinite mantle wedge, are important parameters for the development of a self-sustaining subduction zone. The relevance of the modelling results is demonstrated by comparing length-scales of deformation with observations from inverted continental passive margins and orogenic systems, such as the Alps and Dinarides. Models predict that primary response of the lithosphere to compression is by folding and that tectonic structures and early-stage length-scales of deformation can be used to predict the likeliness of subduction initiation at a passive margin.

How to cite: Auzemery, A.: A comparison of numerical and analogue models of subduction initiation at passive margins., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-356, https://doi.org/10.5194/egusphere-egu22-356, 2022.

We present a numerical scheme to study 3D fracture problems at a planar interface. This scheme is based on the spectral representation of the boundary integral equation method which involves the evaluation of elastodynamic convolutions at the interface. The advantage of this method is that it is numerically efficient as it calculates the field quantities only on the fracture plane rather than in the entire domain. In the current approach, spatial convolution is replaced by multiplication in the spectral domain which increase the computational efficiency. In the literature, Geubelle and Rice [1995] first introduced the 3D spectral representation of the formulation of Budiansky and Rice [1979]. In their approach, the time-convolution is performed of the displacement history at the interface. Later, 3D formulation for a bi-material interface was proposed by Breitenfeld and Geubelle [1998]. Recently, a spectral form of the Kostrov [1966] was proposed by Ranjith [2015] for 2D in-plane problems. In this approach, time-convolution is performed of the traction history at the interface. An advantage of this approach is that the convolution kernels for a bi-material interface can be expressed in closed form, whereas Breitenfeld and Geubelle [1998] had to obtain their convolution kernels numerically. In the present work, convolution kernels for 3D elastodynamic fracture problems at a bi-material interface are derived following the approach of Ranjith [2015].

How to cite: Gupta, A. and Kunnath, R.: Spectral formulation of the 3D elastodynamic boundary integral equations for a bi-material interface, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-767, https://doi.org/10.5194/egusphere-egu22-767, 2022.

The diapir structure is closely related to the distribution of oil and gas resources and has received extensive attention. In this regard, previous works have conducted much research on it. So far, many important achievements and understandings have been obtained on the formation environment and deformation styles of diapir structures, but there are few studies on the formation mechanism of salt or mud diapir initiation and its downbuilding. This study uses analog modeling to establish four sets of combined models of the basal silicon layer and overlying quartz sand, including the differences in initial geomorphology, the thickness of the covering layer above the ductile layer, sedimentary rate, and basal and lateral friction. Results show that the difference in geomorphology is the initial necessary condition for the formation of salt dome or mud dome structure, i.e., the extension, compression environment, and weak zone formed by tectonic activity are all conducive to the rapid start of the diapir structure. The formation of diapir downbuilding, rapid deposition loading, thick initial covering layer above the ductile layer, and significant basal and lateral friction will inhibit the development of early diapirs. In contrast, slow deposition rate, thin initial covering layer above the ductile layer, and reduced basal and lateral friction will promote the growth of early diapirs. Simultaneously, in the middle and late stages of diapir downbuilding, diapirs will grow and deform rapidly with the loading of the deposition rate. Based on the physical modeling results and natural deformation of the diapiric structure, comprehensive analysis shows that diapir downbuilding results from the combined effects of geomorphology, deposition rate, formation temperature and pressure, and diapir fluid depth. It is found that the salt diapir downbuilding in the North Sea Basin and mud diapir downbuilding in the Andaman back-arc basin are similar to the formation mechanism of analog modeling downbuilding in this paper.

 

Keywords: Diapir Structure; Downbuilding; Initial Geomorphology; Sedimentary Rate; Covering Thickness; Basal and Lateral Friction; Analogue Modeling

How to cite: He, W.: Diapiric initiation and formation mechanism of diapir’s downbuilding—Insights from analogue modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1058, https://doi.org/10.5194/egusphere-egu22-1058, 2022.

EGU22-1670 | Presentations | TS9.1

Influence of Time-dependent Healing on Reactivation of Granular Shear Zones in analogue models: A Community Benchmark 

Michael Rudolf, Matthias Rosenau, and Onno Oncken

Inverted structures are some of the economically most important geological features worldwide. Besides their most common manifestation as traps for hydrocarbons, they are also interesting for the storage of CO2 and extraction of other resources such as heat, minerals or hydrogen. Analogue modelling is frequently used to understand the long-term geological evolution of basins and basin inversion as an addition to numerical and mathematical models. Most analogue models use granular materials, like sands and glass beads, to simulate the brittle-plastic rheology of the crust. The main driving mechanism for basin inversion, both in nature and analogue models is the reactivation of pre-existing structures. This is due to strain-dependent weakening which leads to a reduced strength of a fault or shear zone in comparison with the surrounding bulk material. If the structure comes to a rest, several mechanisms lead to a time-dependent restrengthening of the structure. Therefore, older structures are usually more resistant to reactivation than younger ones, in the same material. In this study we use an annular shear tester to quantify the healing of granular materials commonly used for analogue models. We take advantage of a large collection of analogue material samples at the Helmholtz Laboratory for Tectonic Modelling, coming from many laboratories worldwide. To estimate granular healing, we employ slide-hold-slide tests with hold times comparable to typical analogue models of basin inversion. We show that all materials tested exhibit healing which follows a power-law relation quantified by with a healing rate. For example, fused glass microbeads showed a healing rate of 0.025 per decade in hold time. This means that for a tenfold increase in hold time the strength required to reactivate the given fault increases by 2.5%. Consequently, if a fault is inactive for a longer period of time, it is slightly stronger in comparison with a fault with shorter inactivity. Comparing the healing exponent for several materials reveals that some materials show a stronger healing than others. Glass beads have a stronger healing than sands, with quartz sands having lower healing rates than garnet or feldspar sands. Geomechanical tests on natural materials (quartz and gypsum fault gouges) and measurements of seismic velocities across fault zones suggest that healing obeys a similar power law. The healing rates in real rocks are roughly equal or higher depending on the temperature and water saturation of the fault. Albeit small, this change in reactivation strength for analogue materials might have a strong influence on the structural style of inversion if the models are run with different timespans between extensional phase and compressional phase. With a typical range of experimental time-spans of a view seconds to several hours this may result in up to 10% difference in reactivation strength similar to the difference between static and dynamic friction. This becomes especially relevant, if the angles of the formed pre-existing structures are close to the angle of internal friction of the bulk material which is the default in models where reactivated structures have been formed self-consistently in a pre-inversion phase.

How to cite: Rudolf, M., Rosenau, M., and Oncken, O.: Influence of Time-dependent Healing on Reactivation of Granular Shear Zones in analogue models: A Community Benchmark, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1670, https://doi.org/10.5194/egusphere-egu22-1670, 2022.

EGU22-1970 | Presentations | TS9.1

Fault growth and rift propagation during rotational continental rifting: Insights from an analogue modelling study 

Timothy Schmid, Guido Schreurs, and Jürgen Adam

Continental rifts typically result from regional horizontal stretching of the lithosphere and in modelling studies, such rifts are typically assumed to be the result of orthogonal or oblique extension. However, in nature often V-shape rift geometries occur indicating an underlying rotational component that results in a divergence velocity gradient along plate boundaries. Consequently, the geometric, kinematic, and dynamic rift evolution in such rotational settings may significantly differ from those of orthogonal or oblique rifts. Here, we present new findings from an analogue modelling study using a crustal-scale model series with a rotational opening component to investigate the effect of such a rift-axis parallel divergence velocity gradient on fault growth and rift propagation towards the rotation axis.

We use a simplified two-layer system simulating an upper brittle and a lower ductile crust with an imposed initial mechanically weak zone on top of the viscous layer to ensure localized rifting. The experimental monitoring by means of a stereoscopic camera setup and X-Ray computed tomography (XRCT) enables a detailed and quantitative investigation of near-surface rift evolution and internal deformation, respectively. With the combination of 3D surface topography, 3D displacement fields, and XRCT, we gain a comprehensive understanding of deformation evolution in analogue models of rotational rifting. Our modelling results depict a novel characterization of normal fault growth under rotational extension and a rift evolution which is described by (1) rift propagation in two consecutive stages: A first stage showing bidirectional fault growth due to segment linkage with high rift propagation rates, and a second stage during which rift propagation occurs by unidirectional fault growth towards the rotation axis with linearly decreasing growth rates at decreasing distance to the rotation axis, (2) strain partitioning between competing conjugate normal faults with fault activity switching repeatedly from one segment of a normal fault to a segment on the oppositely dipping normal fault, and (3) active faulting migrating from the rift boundary faults inwards to intra-rift normal faults.

Our quantitative, spatiotemporal fault growth analysis reveals a characteristic segmentation of all deformation features listed above. The conclusion that the gradual decrease of the divergence velocity towards the rotation axis causes segmented deformation propagation is key and can help to understand natural examples of rotational rift settings such as the Taupo Rift Zone in New Zealand.

How to cite: Schmid, T., Schreurs, G., and Adam, J.: Fault growth and rift propagation during rotational continental rifting: Insights from an analogue modelling study, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1970, https://doi.org/10.5194/egusphere-egu22-1970, 2022.

EGU22-2743 | Presentations | TS9.1

Investigating Rift-Rift-Rift triple junctions through analogue and numerical modelling 

Daniele Maestrelli, Giacomo Corti, Sascha Brune, Derek Keir, and Federico Sani

Continental break-up at Rift-Rift-Rift triple junctions commonly represents the “prequel” of oceanic basin formation. Currently, the only directly observable example of a Rift-Rift-Rift setting is the Afar triple junction where the African, Arabian and Somalian plates interact to form three rift branches, two of which are experiencing oceanization (the Gulf of Aden and the Red Sea). The younger of the three (the Main Ethiopian Rift) is still undergoing continental extension. We performed analogue and numerical models simulating continental rifting in a Rift-Rift-Rift triple junction setting to investigate the resulting structural pattern and evolution. By adopting a parametrical approach, we modified the ratio between plate velocities, and we performed single-phase (all the three plates move) and two-phase models (with a first phase where only one plate moves and a second phase where all the three plates move). Additionally, the direction of extension was changed to induce orthogonal extension only in one of the three rift branches. Our single-phase models suggest that differential extension velocities in the rift branches determine the localization of the triple junction, which is located closer to the rift branch experiencing slower extension velocities. Furthermore, imposed velocities affect the distribution of deformation and the resulting pattern of faults. The effect of a faster plate is to favour the formation of structures trending orthogonal to dominant velocity vectors, while faults associated with the movement of the slower plates remain subordinate. In contrast, imposing similar velocities in all rift arms leads to the formation of a symmetric fault pattern at the triple junction, where the distribution of deformation is similar in the three rift branches. Two-phase models reveal high-angle faults interacting at the triple junction, confirming that differential extension velocities in the three rift branches strongly affect the fault pattern development and highlighting geometrical similarities with the Afar triple junction.

How to cite: Maestrelli, D., Corti, G., Brune, S., Keir, D., and Sani, F.: Investigating Rift-Rift-Rift triple junctions through analogue and numerical modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2743, https://doi.org/10.5194/egusphere-egu22-2743, 2022.

EGU22-2847 | Presentations | TS9.1

The effect of brittle-ductile weakening on the formation of detachment faults at ultraslow spreading ridges 

Mingqi Liu, Antoine Rozel, and Taras Gerya

Large offset detachment faults form with exhuming mantle-derived rocks into the seafloor at the slow and ultralow spreading ridges. However, their formation mechanism still remains partly elusive.  The thick axial lithosphere of ultraslow spreading ridges detected by seismic studies may prevent the formation of detachment faults. Previous studies have proposed that only the combination of both serpentinization and grain size reduction in the mantle lithosphere can result in detachment faults which are consistent with the natural cases. Here, through 3D self-consistent magmatic-thermomechanical numerical models with both brittle/plastic strain weakening and grain size evolution, we systematically investigate effects of these coupled brittle-ductile weakening processes on the formation of detachment faults at ultraslow spreading ridges. Numerical results show that ultraslow ridges spontaneously break into shorter and warmer magma-rich (10-20% of the ridge length) and longer and colder magma-starved segments (80-90% of the ridge length). Small grain size formed in the deep root of detachment faults near the brittle-ductile transition depth at the magma-starved amagmatic segments. Then with mantle rocks exhumation into the surface, the decreasing temperature leads to the growth of small grain size, consistent with the deformation process of detachment fault systems in the amagmatic segments of the eastern part of the Southwest Indian Ridge. Through quantitatively exploring effects of grain size reduction and strain weakening, we obtained that strain weakening may be the primary factor to control the formation of detachment faults at the ultra-slow spreading ridges, although grain size evolution can also influence the spreading pattern in case of small (<= 1 mm) initial grain size of the lithospheric mantle. Furthermore, we also found that the weak ductile domain induced by the very small initial grain size (<= 0.1 mm) promotes the formation of detachment faults in the models without grain size evolution.

How to cite: Liu, M., Rozel, A., and Gerya, T.: The effect of brittle-ductile weakening on the formation of detachment faults at ultraslow spreading ridges, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2847, https://doi.org/10.5194/egusphere-egu22-2847, 2022.

EGU22-3265 | Presentations | TS9.1

Prediction of Off-Fault Deformation from Strike-slip Fault Structures in clay and sand experiments using Convolutional Neural Networks 

Michele Cooke, Hanna Elston, Laainam Chaipornkaew, Sarah Visage, Pauline Souloumniac, and Tapan Mukerji

Crustal deformation occurs both as localized slip along faults and distributed deformation off faults; however, we have few robust geologic estimates of off-fault deformation over multiple earthquake cycles. Scaled physical experiments simulate crustal strike-slip faulting and allow direct measurement of the ratio of fault slip to regional deformation, quantified as Kinematic Efficiency (KE). We offer an approach for KE prediction using a 2D Convolutional Neural Network (CNN) trained directly on images of fault maps produced by physical experiments of strike-slip loading of wet kaolin. A suite of experiments with different loading rate and basal boundary conditions, contribute over 13,000 fault maps throughout strike-slip fault evolution. Strain maps allow us to directly calculate KE and its uncertainty, utilized in the loss function and performance metric. The trained CNN achieves 91% accuracy in KE prediction of an unseen dataset. We then apply this CNN trained on wet kaolin experiments to strike-slip experiments in dry sand. The different rheology of sand and kaolin may lead to different relationships between fault geometry and off-fault deformation, which can be detected by differences in the predictive power of the CNN trained only on kaolin.  We also apply the trained CNN to crustal maps of off-fault deformation over coseismic, 10ka and 1 Ma time scales. The CNN predicted off-fault deformation overlap available geologic estimates.

How to cite: Cooke, M., Elston, H., Chaipornkaew, L., Visage, S., Souloumniac, P., and Mukerji, T.: Prediction of Off-Fault Deformation from Strike-slip Fault Structures in clay and sand experiments using Convolutional Neural Networks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3265, https://doi.org/10.5194/egusphere-egu22-3265, 2022.

EGU22-4212 | Presentations | TS9.1

Sharing data and facilities in the analogue modelling community: the EPOS Multi-Scale Laboratories Thematic Core Service 

Francesca Funiciello, Matthias Rosenau, Stephane Dominguez, Ernst Willingshofer, Geertje ter Maat, Frank Zwaan, Fabio Corbi, Jan Olivier Eisermann, Benjamin Guillaume, Pauline Souloumiac, Silvia Brizzi, Giacomo Mastella, Riccardo Reitano, Elena Druguet, Guido Schreurs, and Claudio Faccenna and the EPOS Multi-Scale Laboratories Team

EPOS, the European Plate Observing System, is a unique e-infrastructure and collaborative environment for the solid earth science community in Europe and beyond (https://www.epos-eu.org/). A wide range of world-class experimental (analogue modelling and rock and melt physics) and analytical (paleomagnetic, geochemistry, microscopy) laboratory infrastructures are concerted in a “Thematic Core Service” (TCS) labelled “Multi-scale Laboratories” (MSL) (https://www.epos-eu.org/tcs/multi-scale-laboratories). Setting up mechanisms allowing for sharing metadata, data, and experimental facilities has been the main target achieved during the EPOS implementation phase. The TCS Multi-scale Laboratories offers coordination of the laboratories’ network, data services, and Trans-National access to laboratory facilities.

In the framework of data services, TCS Multi-Scale Laboratories promotes FAIR (Findable-Accessible-Interoperable-Re-Usable) (FAIR) sharing of experimental research data sets through Open Access data publications. Data sets are assigned with digital object identifiers (DOI) and are published under the CC BY license. Data publications are now conventionally citable in scientific journals and develop rapidly into a common bibliometric indicator and research metric. A dedicated metadata scheme (following international standards that are enriched with disciplinary controlled community vocabulary) facilitates ease exploration of the various data sets in a TCS catalogue (https://epos-msl.uu.nl/). Concerning analogue modelling, a growing number of data sets includes analogue material physical and mechanical properties and modelling results (raw data and processed products such as images, maps, graphs, animations, etc.) as well as software (for visualization, monitoring and analysis). The main geoscience data repository is currently GFZ Data Services, hosted at GFZ German Research Centre for Geosciences (https://dataservices.gfz-potsdam.de), but others are planned to be implemented within the next years.

In the framework of Trans-National access (TNA), TCS Multi-scale laboratories’ facilities are accessible to any researchers, creating new opportunities for synergy, collaboration and scientific innovation, according to TNAtrans-national access rules. TNA can be realized in the form of physical access (on-site experimenting and analysis), remote service (sample analysis) and virtual access (remotely operated processing). After three successful TNA calls, the pandemic has forced a moratorium on the TNA program.

The EPOS TCS Multiscale Laboratories framework is also providing the foundation for a comprehensive database of rock analogue materials, a dedicated bibliography, and facilitates the organization of community-wide activities (e.g., meetings, benchmarking) to stimulate collaboration among analogue laboratories and the exchange of know-how. Recent examples of these community efforts are also the contributions to the monthly MSL seminars, available on the MSL YouTube channel (https://www.youtube.com/channel/UCVNQFVql_TwcSBqgt3IR7mQ/featured), as well as the Special Issue on basin inversion in Solid Earth that is currently open for submissions  (https://www.solid-earth.net/articles_and_preprints/scheduled_sis.html#1160). 

How to cite: Funiciello, F., Rosenau, M., Dominguez, S., Willingshofer, E., ter Maat, G., Zwaan, F., Corbi, F., Eisermann, J. O., Guillaume, B., Souloumiac, P., Brizzi, S., Mastella, G., Reitano, R., Druguet, E., Schreurs, G., and Faccenna, C. and the EPOS Multi-Scale Laboratories Team: Sharing data and facilities in the analogue modelling community: the EPOS Multi-Scale Laboratories Thematic Core Service, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4212, https://doi.org/10.5194/egusphere-egu22-4212, 2022.

EGU22-5076 | Presentations | TS9.1

Numerical modelling of lithosphere-asthenosphere interaction and intraplate deformation in the Gulf of Guinea 

Jaime Almeida, Nicolas Riel, Marta Neres, Susana Custódio, and Stéphanie Dumont

Despite extensive research, intraplate deformation and associated earthquakes remain elusive. We argue that one potential reason for its occurrence is the interplay between the lithosphere and the upper mantle dynamic processes, specifically the lithosphere-asthenosphere interaction. To explore this possibility, we targeted the Gulf of Guinea and adjacent Western Africa, a region with low plate velocities and clear asthenosphere dynamics, which allows for the isolation of the underlying dynamic constraints which govern intraplate deformation. An in-depth understanding of intraplate deformation mechanisms will contribute towards the improvement of seismic hazard assessment away from plate boundaries.

Thus, here we present exploratory 3D numerical geodynamic models of the asthenosphere-lithosphere interaction in the Gulf of Guinea, ran with the state-of-the-art modelling code LaMEM. We employ different initial/boundary conditions such as: (a) different spreading rates for the Atlantic mid-ocean ridge (from 5 to 25 mm/yr), (b) rheological/lithological configurations (accounting for the cratonic/mobile nature of the region), (c) the presence/absence of weak zones (e.g., the Romanche/Central-African shear zones), and (d) the effect exerted by an active mantle plume. Seismicity data was employed to rank the models to ensure the validity of our results.

Preliminary results suggest that intraplate deformation within the Gulf of Guinea is influenced by the spreading rate of mid-ocean ridge, with stress being localized around the ocean-continent transition and existing shear zones.

This work was developed in the frame of SHAZAM (POCI-01-0415-FEDER-031475). FCT is further acknowledged for support through project UIDB/50019/2020-IDL.

How to cite: Almeida, J., Riel, N., Neres, M., Custódio, S., and Dumont, S.: Numerical modelling of lithosphere-asthenosphere interaction and intraplate deformation in the Gulf of Guinea, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5076, https://doi.org/10.5194/egusphere-egu22-5076, 2022.

EGU22-5879 | Presentations | TS9.1

The Expander: Growing fault networks under pure shear conditions 

Jun Liu, Matthias Rosenau, Sascha Brune, Ehsan Kosari, Onno Oncken, Michael Rudolf, and Thilo Wrona

The growth of faults is well studied with field methods, experiments and theoretical models. Fault evolution is largely established from a geometrical and kinematic point of view with respect to the growth of isolated faults and their mutual interaction. However, the dynamics of fault growth (e.g. stress shadowing, damage zone evolution, energy budgets) and the emergence of interactions over various spatial and temporal scales in larger fault networks is a topic of recent interest less illuminated so far. We here introduce a new experimental setup allowing to study “large-n” fault networks evolving in crustal-scale brittle and brittle-ductile analogue models. We document preliminary results helping to demonstrate and verify the capability of the approach.

The setup, called “The Expander”, builds on a traditional extensional setup with a basal rubber sheet expanded in one direction. The aspect ratio of the rubber sheet controls its lateral contraction (“Poisson’s effect”) and thus the bulk strain ratio under pure shear conditions. We can thus realize constrictional (prolate) to plane to flattening (oblate) kinematic basal boundary conditions depending on the sheet’s aspect ratio and whether we expand or relax the sheet. Evolving fault networks vary from anastomosing fold-and-thrust belts to conjugate sets of strike-slip fault networks to quasi-parallel normal fault populations, respectively. We apply digital image correlation (DIC) to track the kinematic surface evolution and photogrammetry (structure from motion, SFM) for topography evolution.

First observations suggest that strike-slip fault networks in a purely brittle crust under basal pure shear conditions evolve into compartments of synthetic faults, the size of which scale with brittle layer thickness similar to fault spacing. The scaling seems to be controlled by slip partitioned onto the individual faults and mediated by stress shadows. Numerical simulation of the experiment suggests that the compartmentalization might evolve further through sequential de-activation of smaller faults and collapse of deformation into a single regional scale master fault with or without prescribing a zone of crustal weakness (a “seed”). Further experiments are planned to test the fault pattern evolution for different mechanical stratigraphy (brittle-viscous layers, seeds) and kinematic boundary conditions.

How to cite: Liu, J., Rosenau, M., Brune, S., Kosari, E., Oncken, O., Rudolf, M., and Wrona, T.: The Expander: Growing fault networks under pure shear conditions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5879, https://doi.org/10.5194/egusphere-egu22-5879, 2022.

EGU22-6358 | Presentations | TS9.1

Lithospheric-scale experiments of continental rifting monitored in an X-Ray CT scanner 

Frank Zwaan and Guido Schreurs

When simulating lithosphere-scale rifting processes, analogue modellers have their model lithosphere float on top of a dense fluid representing the sub-lithospheric mantle (i.e. the asthenosphere). Such models provide crucial insights into rift evolution, but monitoring model-internal deformation has always been a major challenge. Here we present the results of new rifting experiments performed with a novel lithospheric-scale modelling machine that allows for X-ray CT-scanner, uniquely revealing the models’ internal evolution.

Our models involve a 4-layer lithosphere, with brittle layers for the competent upper crust and upper lithospheric mantel, and viscous layers for the ductile lower crust and lower lithospheric mantle. This model lithosphere is placed in a basin of glucose syrup simulating the asthenosphere and contained by mobile sidewalls. When stretching the model by moving these sidewalls apart (inducing either orthogonal or oblique extension), deformation is accompanied by syrup flow and isostatic compensation. A weakness within the upper mantle serves to localize deformation along the central axis of the model. We use photogrammetry and PIV techniques for detailed analysis of surface deformation, whereas CT imagery and PIV analysis of CT-sections provide unprecedented insights into internal model evolution.

We find that early on in orthogonal extension models, deformation initiates along the weakness in the upper mantle layer. This deformation is then transferred into the upper crust via shear zones in the lower crust, generating a dual graben structure there. In parts of the model, one of the grabens can become dominant and as extension progresses, so that a large shear zone cutting through the whole lithosphere forms (asymmetric, simple-shear rifting). In other parts of the model deformation may be more distributed so that both grabens are well-developed (symmetric, pure shear rifting). Meanwhile, the on-going stretching and thinning of the lithosphere splits the upper mantle layer, and the simulated lower mantle (and especially the asthenosphere) rises towards the model surface, bringing the lower mantle layer in contact with the lower crustal layer (i.e. necking of the lithosphere).

In oblique extension models initial deformation also localizes in the upper mantle layer, but no clear surface structures develops (except for a broad topographic depression along the central model axis). By increasing the extension velocity and thus the coupling between the upper mantle and upper crust, faulting initiated in the upper crust, creating two bands of en echelon grabens. Also in these models, we observe lithospheric necking.

Our (final stage) model results are similar to previous works. Yet the new CT-imagery provides the first-ever direct insights (both qualitative and quantitative) into the internal evolution of lithospheric-scale rift models. Furthermore, this new and versatile modelling machine in combination with our CT-scanning abilities provides a broad range of opportunities for advanced future lithospheric-scale modelling studies.

 

 

Figure: 3D CT image of an oblique extension model. UC: upper crust, LC: Lower crust, ULM: upper lithospheric mantle, LLM: lower lithospheric mantle, As: asthenosphere

 

How to cite: Zwaan, F. and Schreurs, G.: Lithospheric-scale experiments of continental rifting monitored in an X-Ray CT scanner, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6358, https://doi.org/10.5194/egusphere-egu22-6358, 2022.

Cases where multiple tectonic regimes acted closely in space and time have been long recognized. The coexistence of thrust, strike-slip, and normal faulting has been documented in thick orogenic regions, in oblique convergent settings associated with strain partitioning, in areas of indentation tectonics and lateral escape, and synorogenic foreland rifting/transtension settings, where extension-transtension takes place in close spatiotemporal relation with plate-margin shortening. Here, we use analogue models to test how parameters like the crustal strength, basement inheritances, and relative rate of extrusion/indentation can be effective mechanisms to explain the coeval emplacement of thrust, strike-slip, and normal faults. We also investigate their effect on fault reactivation in previously extended basins.

We show that a strong crust can exhibit coeval thrust faults, strike-slip faults and normal faults for ratios of extrusion over indentation rates in between 1.4 and 2, as orientation and magitude of principal stresses spatially vary within the model. For a weaker crust, normal faults and thrusts faults cannot coexist at the same time. Inheritance, which is implemented through the presence of a seed simulating a preexisting weakness zone or through an initial phase of extension, controls the geometry of strike-slip faults, whose orientation departs from the Coulomb fracture criterion. Reactivation of former normal faults as normal faults is only possible for ratios of extrusion over indentation rates over 1, for both weak and strong crusts. For lower rates, pre-existing normal faults are reactivated as indentation-parallel strike-slip faults. Our experimental results are then compared with the tectonic evolution of the Eastern Anatolia, the Alps and the Central Patagonia.

How to cite: Guillaume, B. and Gianni, G.: Control of inheritance, crustal strength and relative rate of extrusion/indentation on 3D strain distribution and basin reactivation: insights from laboratory models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7095, https://doi.org/10.5194/egusphere-egu22-7095, 2022.

EGU22-7776 | Presentations | TS9.1 | Highlight

Stochastic Chaos in Laboratory Earthquakes 

Adriano Gualandi, Davide Faranda, Chris Marone, and Gianmarco Mengaldo

Earthquakes are a complex natural phenomenon. They typically are the result of frictional instabilities along preexisting weakness zones called faults. The strain slowly builds up in the fragile Earth crust because of the presence of an external loading counterbalanced by friction forces at the faults’ interface. When the load cannot be balanced by the friction any further, the fault slips releasing the accumulated strain. Friction is a nonlinear phenomenon, and as such frictionally controlled systems may be subject to chaotic behavior. Seismic cycle analogs can be reproduced with rock friction experiments in the laboratory with a double direct shear apparatus. We show that laboratory earthquakes follow a low-dimensional random attractor. We explain the observations with a model of stochastic differential equations based on the rate- and state-friction framework. We show that small perturbations (less than 1‰) on the shear and normal stress can induce laboratory earthquakes aperiodic behavior with coefficient of variations of the order of some percent. The nonlinear nature of friction amplifies small scale perturbations, making mid-long term predictions of the system possible only statistically even for stick-slip events in a well controlled environment like the laboratory.

How to cite: Gualandi, A., Faranda, D., Marone, C., and Mengaldo, G.: Stochastic Chaos in Laboratory Earthquakes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7776, https://doi.org/10.5194/egusphere-egu22-7776, 2022.

EGU22-8331 | Presentations | TS9.1

Analogue experiments of normal fault formation in multi-layers of alternating strength 

Utomi Izediunor, Susanne Buiter, and Joyce Schmatz

 As normal faults accumulate displacement, smearing of weaker fine-grained materials, such as clays, along their fault plane can reduce fault permeability and thus affect fluid flow in subsurface reservoirs, making clay smear development relevant for groundwater, geothermal and CO2 storage applications. Here we use analogue experiments to investigate the potential of smearing of weaker layers along fault planes in a multi-layer sequence of granular materials.  

The natural prototype is the interbedded limestone and marl sedimentary units of the Malm formation in a quarry in southern Germany. The normal faults in the quarry have small offset (usually < 50 cm) and dip between 40° – 65° predominantly trending NE – SW. We observe discontinuous marl smearing along the fault planes, which are surrounded by deformation zones with a dense tensile fracture population. Average limestone and marl bed thicknesses on both footwall and hanging wall is 32 cm and 4.5 cm, and 33 cm and 2.5 cm respectively.

Our analogue experiments are scaled to represent layers at quarry scale. We tested several sand and gypsum plaster mixtures using empirical and ring shear methods to find cohesive strength contrasts suitable for simulating the limestone-marl sequences. The material tests show that with increasing plaster content and confining pressure, cohesion increases, while the angle of internal friction shows a non-linear behaviour for plaster/sand mixtures. We here use sand for marl layers and gypsum for limestone. We sieve the materials in a 50 x 30 cm box of which half the base plate can drop down along a prescribed angle. We analyse deformation from 2D-timelapse and 3D-CT image data, using PIV and image analysis.

Models with sand (marl) layers within gypsum (limestone) without overburden show numerous mode I fractures at the free surface with localized fault planes. Shear zones are steep with dip angles in the range of 66° - 84°. Models with overburden form shear zones with dips ranging from 65° - 83°, forming less mode I fractures, but instead mainly shear fractures that cut across each cohesive layer. Sand smearing is observed to vary in models without overburden, while it is a consistent component of the fault zones at depth in models with overburden. We find that the quantity of sand smear is a function of the thickness of the embedded sand layers. The sand pours into large openings formed between cohesive gypsum powders with simultaneous mixing of the materials during fault displacement. This process causes an accumulation of sheared granular materials along the fault zone and in turn expands the shear zone width.

The experiments with overburden show steep dipping fragmented fault zones, as well as the formation of tensile fractures that form in, and cut through cohesive beds, similar to what is observed in the quarry. Sand smearing processes of rolling and mixing in dilatant portions during displacement is however more brittle in nature than ductile smearing observed in the quarry.

How to cite: Izediunor, U., Buiter, S., and Schmatz, J.: Analogue experiments of normal fault formation in multi-layers of alternating strength, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8331, https://doi.org/10.5194/egusphere-egu22-8331, 2022.

EGU22-8822 | Presentations | TS9.1

Transform versus non-transform offsets controlled by offset length and the variation in magmatic accretion within the offset zone 

Jana Schierjott, Garrett Ito, Mark Behn, Thomas Morrow, Xiaochuan Tian, and Boris Kaus

Transform faults and non-transform offsets define the bounds of mid-ocean ridge spreading segments, but tectonic and magmatic controls on the length of segments and the morphology of intervening offsets are poorly understood. A general observation at intermediate and slow-spreading oceanic environments is that localized strike-slip motion along transform faults tends to occur on larger offsets in space or crustal age, whereas more diffuse deformation at non-transform zones occurs at shorter offsets distances. In addition, variables such as lithospheric thickness, the size and spacing of faults, and the fraction (M) of extension accommodated by magmatic accretion (rather than faulting) are known to influence the overall morphology of the ridge segment and its vicinity. We hypothesize that the decrease in the amount of magmatic extension along the ridge segment towards the discontinuity along with the ridge segment offset play a role in defining the transition between transform and non-transform offsets.

In this study, we employ a 3D-numerical model to investigate how the relative amounts of fault- or magma-accommodated spreading and distance offset (D) between ridge segments control the development of transform versus non-transform offsets. Our model employs a ridge-like initial temperature structure, with magma intrusion simulated by adding a divergence to the right-hand-side of the continuity equation within a magmatic accretion zone at the ridge axis. M, the fraction of magmatically compensated spreading inside the magmatic accretion zone, can be varied along strike. By using a visco-elasto-plastic formulation the model can simulate the spontaneous formation and evolution of normal faults that accommodate part of the spreading. The temperature field is allowed to evolve and the model accounts for an increased, temperature-dependent conductivity around each ridge segment. We vary both the offset distance D separating two axes of magmatic accretion as well as the length L over which M decreases along the ridge axes towards the discontinuity. We find that increasing L leads to non-transform offsets, particularly for small offset distances D. As D increases, the occurrence of the offset zone is less prominently dominated by L. Depending on M, the style of faulting differs along the magmatic segments. While for M>0.5 we observe migrating faults creating topography similar to abyssal hills, values for M that are smaller or equal to 0.5 lead to stationary faults which are located closer to the ridge axis. 

How to cite: Schierjott, J., Ito, G., Behn, M., Morrow, T., Tian, X., and Kaus, B.: Transform versus non-transform offsets controlled by offset length and the variation in magmatic accretion within the offset zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8822, https://doi.org/10.5194/egusphere-egu22-8822, 2022.

EGU22-9653 | Presentations | TS9.1

Ultrasonic imaging of analogue scale models 

Jasper Smits, Fred Beekman, Ivan Vasconcelos, Ernst Willingshofer, Kasper Van Wijk, and Liviu Matenco

Since the 19th century pioneering work of Sir James Hall, physical analogue modelling has been proven a valuable method for the study of geological phenomena and has significantly contributed to understanding fundamental mechanisms of crust and lithosphere deformation. Traditionally, in such analogue scale models, structural deformation is monitored and quantified using top-view images or cross-sections, where the latter allow for portraying the final state of internal deformation of the model in great detail. Monitoring the evolution of internal deformation while the experiment is running is however a major challenge, and currently is possible only with X-ray scanning using medical-type CT scanners. These, however, put stringent limitations on size of the model and, thus, the possible geometric configurations related to different modelling setups.

To tackle these limitations, we are developing a novel method to image the evolving interior of analogue scale models using ultrasonic techniques. Similar to reflection seismology used in field studies, the internal structure of the analogue model can be imaged using sound waves. We employ a completely non-contact and non-invasive method, utilizing a laser Doppler vibrometer to detect the arrivals of seismic body waves at the model surface. A laser pulse from a powerful pulsed laser acts as a point source and is used to introduce acoustic waves in the model. By moving the detector and source, acoustic data is recorded for a number of source-recorder combinations, allowing the reconstruction of the internal layering and structure along cross sections, as will be illustrated by the results of several tests with analogue models and other samples. By developing this technique, we provide novel tools to characterize the acoustic behaviour of subsurface structures under well-controlled laboratory conditions with the aim of improving our understanding of waveforms and wave propagation in analogue models and earth materials in general.

How to cite: Smits, J., Beekman, F., Vasconcelos, I., Willingshofer, E., Van Wijk, K., and Matenco, L.: Ultrasonic imaging of analogue scale models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9653, https://doi.org/10.5194/egusphere-egu22-9653, 2022.

The South Atlantic played a key role in the formulation of plate tectonic theory, and plate modelling has come a long way since the very first computer-assisted reconstructions of this ocean basin in the 1960s. This basin remains an active area of exploration interest as well as an excellent case study to discuss the past, present and future of plate modelling and to reflect on the reasons why discrepancies still remain, decades later, between alternative models reconstructing its geological history.

Today, high-resolution studies featuring multiple closely spaced static reconstructions give the opportunity to determine plate motions and their changes through time in more detail than ever before. They act as the foundation stones for many modern-day interpretations and simulations, providing context for regional geological and tectonic studies, and constraints for predictions of past climates, depositional environments, the evolution of stress regimes and, ultimately, the location of natural resources. Defining accurate sets of rotations that describe plate motion, as well as quantifying the uncertainties in them, is thus increasingly important.

As well as becoming more sophisticated, modelling techniques have also somewhat diversified in recent years. This is well illustrated by the fact that, for any one region on the planet, it is relatively easy to find alternative (and often irreconcilable) plate reconstructions built either on the basis of different data, different methodologies, or both. This prompts the question “how does one choose the right plate model” (and is there even such a thing as the “right” plate model). Focusing on the South Atlantic basin and using recently released version 6.0 of the Neftex plate model, I will discuss how unlocking the next generation of plate models requires implementing a global approach anchored on the principles of geodynamics.

How to cite: Perez Diaz, L.: From deep time to the future: unlocking the next generation of plate models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9952, https://doi.org/10.5194/egusphere-egu22-9952, 2022.

EGU22-10156 | Presentations | TS9.1

New granular rock-analogue materials for simulation of multi-scale fault and fracture processes 

Luigi Massaro, Jürgen Adam, Elham Jonade, and Yasuhiro Yamada

Dynamically scaled experiments allow the direct comparison of geometrical, kinematical and mechanical processes between model and nature. The geometrical scaling factor defines the model resolution, which depends mainly on the density and cohesive strength ratios of model material and natural rocks. Granular materials such as quartz sands are ideal for the simulation of upper crustal deformation processes as a result of similar nonlinear deformation behaviour of granular flow and brittle rock deformation. We compared the geometrical scaling factor of common analogue materials applied in tectonic models and identified a gap in model resolution corresponding to the outcrop and structural scale (1–100 m).

In this study, we present a new granular rock-analogue material (GRAM) with a dynamic scaling suitable for the simulation of fault and fracture processes in analogue experiments. The proposed material is composed of silica sand and hemihydrate powder and is suitable to form cohesive aggregates capable of deforming by tensile and shear failure under variable stress conditions. Based on dynamical shear tests, GRAM is characterized by a similar stress-strain curve as dry silica sand, has a cohesive strength of 7.88 kPa and an average density of 1.36 g cm−3. The derived geometrical scaling factor is 1 cm in model = 10.65 m in nature. For a large-scale test, GRAM material was applied in strike-slip analogue experiments. Early results demonstrate the potential of GRAM to simulate fault and fracture processes, and their interaction in fault zones and damage zones during different stages of fault evolution in dynamically scaled analogue experiments.

How to cite: Massaro, L., Adam, J., Jonade, E., and Yamada, Y.: New granular rock-analogue materials for simulation of multi-scale fault and fracture processes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10156, https://doi.org/10.5194/egusphere-egu22-10156, 2022.

EGU22-10624 | Presentations | TS9.1

Stretch and fold: Multistage analogue experiments of rifting, inversion, and orogenesis 

Anindita Samsu, Peter Betts, Fatemeh Amirpoorsaeed, Alexander Cruden, and Weronika Gorczyk

Analogue models are powerful tools for investigating extensional and convergent tectonic processes in 4D and at multiple scales. However, rarely do we introduce two successive phases of tectonism in a single analogue experiment to study the interaction between structures from two kinematically distinct tectonic events. Here we showcase a series of analogue experiments in which lithospheric-scale models are extended and subsequently shortened, simulating rifting followed by inversion and mountain building.

In our experiments, we simulate rifting by extending a multi-layer, brittle-ductile model lithosphere; this initial model is analogous to a hot, thickened lithosphere immediately after orogenesis. We demonstrate that the absence or presence of a narrow, pre-existing weakness in the lithospheric mantle results in end-member models of either wide or narrow rifting, respectively. Extension is immediately followed by shortening of the model, where we observe that contractional structures are localised along pre-existing rift basins. Analyses of particle imaging velocimetry (PIV) data reveal that shortening is accommodated by several mechanisms, including reverse reactivation of normal faults and buckling and/or inversion within pre-existing basins. We also show that these findings are consistent with field and geophysical observations from northern Australia as well as previous numerical experiments.

How to cite: Samsu, A., Betts, P., Amirpoorsaeed, F., Cruden, A., and Gorczyk, W.: Stretch and fold: Multistage analogue experiments of rifting, inversion, and orogenesis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10624, https://doi.org/10.5194/egusphere-egu22-10624, 2022.

EGU22-10849 | Presentations | TS9.1 | Highlight

Experimental study on the conditions of inclusions capturing during diamond growth in the upper mantle 

Nadezda Chertkova, Anna Spivak, Anastasiia Burova, Egor Zakharchenko, Yuriy Litvin, Oleg Safonov, and Andrey Bobrov

Primary inclusions in natural diamonds provide unique information about deep-seated mantle minerals and fluids. Findings of the VI and VII modifications of H2O-ice as inclusions in diamonds show the presence of aqueous fluids at different depths in the diamond-bearing mantle (Kagi et al., 2000; Tschauner et al., 2018). In this work, we apply various experimental techniques for the investigation of mineral associations and H2O phases, captured as inclusions in diamonds, in the pressure range from 4 to 8 GPa and at temperatures from 500 °C to 1250 °C. In situ observations using diamond anvil cell (DAC) technique revealed crystallization of ice VII in association with ilmenite and olivine minerals upon cooling from 890 °C at 4 GPa, in agreement with the data, obtained from natural samples by Tschauner et al. (2018). Heating of this assemblage to 1200 °C at 6 GPa results in the formation of another mineral association, which includes ilmenite, pyroxene and clinohumite. Obtained experimental results can be used to reconstruct the pressure and temperature conditions of mineral and fluid inclusions capturing upon diamond growth and transfer in the lithosphere.  

This work was supported by grant No. 20-77-00079 from the Russian Science Foundation.

How to cite: Chertkova, N., Spivak, A., Burova, A., Zakharchenko, E., Litvin, Y., Safonov, O., and Bobrov, A.: Experimental study on the conditions of inclusions capturing during diamond growth in the upper mantle, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10849, https://doi.org/10.5194/egusphere-egu22-10849, 2022.

EGU22-11034 | Presentations | TS9.1

Condition for the formation of the Mozambique ridge (physical modelling) 

Anastasiia Tolstova, Evgene Dubinin, and Andrey Grokholsky

The Mozambique Ridge is located in the southwestern Indian Ocean between
two Mesozoic ocean basins: the Natal Basin and the Mozambique Basin. The
Mozambique ridge is formed from several bathymetric plateaus rising to 3500 m from
the seabed. It is believed that the origin of the ridge is associated with its partial
separation from the outskirts of the African continent due to the activities of the Karoo
hotspot. Recent studies show that the northeastern part of the ridge is thinned
continental crust covered with sediments, and the southern part is characterized by a
large number of extrusion centers indicating increased igneous activity. Experimental
studies described in this work showed that the formation of the Mozambique ridge
occurred in the context of the destruction of the Afro-Antarctic continent with
structural heterogeneities in the lithosphere of the African continent and the influence
of the Karoo hotspot.
This work was supported by the Russian Science Foundation
(project no. № 22-27-00110).

How to cite: Tolstova, A., Dubinin, E., and Grokholsky, A.: Condition for the formation of the Mozambique ridge (physical modelling), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11034, https://doi.org/10.5194/egusphere-egu22-11034, 2022.

EGU22-11360 | Presentations | TS9.1

Effects of multiple detachments in thin-skinned fold and thrust belts: insights from analogue modelling 

Bianca Copot, Dan M. Tamas, Alexandra Tamas, Csaba Krezsek, Zsolt Schleder, Alexandru Lapadat, and Sorin Filipescu

Thin-skinned fold and thrust belts present exploration challenges in many places worldwide. The presence of multiple detachments in the stratigraphic sequence also adds to the complexity of such fold and thrust belts. This study aims to understand more about the effects of multiple detachments in thin-skinned fold and thrust belts through scaled analogue modelling experiments. Our main area of interest is Romania's prolific onshore hydrocarbon area, the foreland of the Eastern Carpathian Bend Zone. Here, one of the large uncertainties is if the Oligocene to lower Miocene strata experienced any shortening before salt deposition. If so, what would be the difference in the observed geometries?

Scaled sandbox models with layered brittle and ductile materials were used to gain critical insights into the structural evolution of this fold and thrust belt (ECBZ) and to reduce the above-mentioned uncertainties. The materials used in these experiments are: coloured dry quartz sand (for modelling brittle behaviour), silicone (for ductile behaviour of the salt), 200-300 μm glass microspheres and a mixture of silicone and granular materials (for the other detachment levels).

The experimental setup consists of a computerized deformation device that pulls a mobile plate at a constant rate beneath a fixed deformation box with one glass sidewall, one end of the box acting as a static buttress. Deformation monitoring has been achieved using top-view 3D digital image correlation techniques (DPIV- Digital Particle Image Velocimetry). The models were serially sectioned and photographed after post-experiment treatment (wetting and consolidation). The sections were used to build and interpret 3D digital models of the experiments.

Duplex structures mainly characterize the deformation in the sub-silicone. Some particular geometries observed in the sub-silicone (salt) sequence are buckle folds and lift-off folds. These mainly occur when the detachments within the sub-silicone mechanical stratigraphy consist of silicone/granular mixture. Although not traditionally interpreted and observed in the area, these results raise the possibility of alternative interpretations. The supra-silicone (salt) deformation is less complex, characterized by both fore- and backthrusts, most of them initiating as detachment folds, similar to what is seen in our area of interest.

Experimental results reduce exploration uncertainties by bringing more insights into the control and effects of multiple detachments on the structural development of fold and thrust belts. These modelling results also bring new possible interpretations in areas poorly constrained by seismic and well data.

How to cite: Copot, B., Tamas, D. M., Tamas, A., Krezsek, C., Schleder, Z., Lapadat, A., and Filipescu, S.: Effects of multiple detachments in thin-skinned fold and thrust belts: insights from analogue modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11360, https://doi.org/10.5194/egusphere-egu22-11360, 2022.

EGU22-11517 | Presentations | TS9.1

Large scale detachment folding of thermally softened crust within a closing orocline in the Chinese Altai - insights from analog modeling 

Tan Shu, Prokop Závada, Ondřej Krýza, Yingde Jiang, and Karel Schulmann

The ribbon-like Altai accretionary sedimentary wedge, representing the SW exteriors of the the Tuva-Mongol Orocline, suffered important Devonian and Permian deformation, metamorphism and melting. The last Permian deformation was associated with massive lower crustal melting, granulitization and lateral lower crustal flow of anatectic material. This lateral transfer was controlled by upwelling of the mantle below the extended parts of the crust. The subsequent Permian shortening led to development of a series of crustal scale detachment folds cored by migmatite-magmatite complexes and surrounded by weakly metamorphosed rocks in marginal synforms.

 

The current study aims to understand the geometry, kinematics and dynamics of such large scale folding in the Chinese Altai during compression of thermally softened crust confined in the Tuva-Mongol Orocline. In such a setting, the angle of convergence is progressively increasing during collision, as the curvature of the orocline increases. To visualize and quantify this process, we employed analog modeling by using paraffin wax for ductile lower crust and sand-cenosphere mixture for brittle upper crust. The model domains (60cm×70cm×3cm) are preheated for 15 hours to attain a stable initial thermal and rheological gradient. The base of the models sustains the temperature at 51 °C (the melting point for the paraffin wax) while the top part of the model is heated to 48 °C by convective air. Strain in the models is quantified from the top view using the stereoscopic digital image correlation system from Lavision GmbH. The models are shortened by movement of indenter wall driven by a step-motor. Three series of experiments were designed to simulate the above detachment folds. In the first series of models, the indenter wall is perpendicular to the shortening direction. In the second scenario, the indenter wall is initially obliquely oriented to the shortening direction. As for last scenario, the angle of convergence α (defined as the angle between the plate motion vector and the plate boundary) is continuously increased from initial 60° to 90°. This last mode mimics the effect of the closing orocline confining the thermally softened crust. All models display progressive development of an array of folds with crestal grabens that are cored by molten and partially molten wax. We describe how the style of folding, degree of strain partitioning and distribution of transcurrent movements differ between the modes of convergence.

How to cite: Shu, T., Závada, P., Krýza, O., Jiang, Y., and Schulmann, K.: Large scale detachment folding of thermally softened crust within a closing orocline in the Chinese Altai - insights from analog modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11517, https://doi.org/10.5194/egusphere-egu22-11517, 2022.

EGU22-3730 | Presentations | GD9.1

Gravity kernel method for implicit geological modeling 

Zhouji Liang, Miguel De La Varga, and Florian Wellmann

Gravity is one of the most widely used geophysical data types in subsurface exploration. In the recent developments of stochastic geological modeling, gravity data serves as an additional constraint to the modeling construction and can be included in the modeling process as the likelihood function in a Bayesian workflow. A fast but also precise forward gravity simulation is key to the success of the geological modeling inverse problem.

In this study, we present a gravity kernel method, which is based on the widely adopted analytical solution on a discretized grid. As opposed to a globally refined regular mesh, we construct local tensor grids for each sensor, respecting the gravimeter locations and the local sensitivities. The kernel method is efficient in terms of both computing and memory use for meshless implicit geological modeling approaches. This design makes the method well suited for many-query applications like Bayesian machine learning using gradient information calculated from Automatic Differentiation (AD). Optimal grid design without knowing the underlying geometry is not straightforward before evaluating the model. Therefore, we further provide a novel perspective on a refinement strategy for the kernel method based on the sensitivity of the cell to the corresponding receiver. Synthetic results are presented and show superior performance compared to the traditional spatial convolution method.

How to cite: Liang, Z., De La Varga, M., and Wellmann, F.: Gravity kernel method for implicit geological modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3730, https://doi.org/10.5194/egusphere-egu22-3730, 2022.

It is broadly accepted that magmatism plays a key dynamic role in continental and oceanic rifting. However, these dynamics remain poorly studied, largely due to the difficulty of consistently modelling liquid/solid interaction across the lithosphere. The RIFT-O-MAT project seeks to quantify the role of magma in rifting by using models that build upon the two-phase flow theory of magma/rock interaction. A key challenge is to extend the theory to account for the non-linear rheological behaviour of the host rocks, and investigate processes such as diking, faulting and their interaction (Keller et al., 2013). Here we present our progress in consistent numerical modelling of poro-viscoelastic-viscoplastic (VEVP) flow. We show that a VEVP model with a new, hyperbolic yield surface can help to robustly simulate both shear and tensile modes of plastic failure in a two-phase system. 

Failure of rocks (plasticity) is an essential ingredient in geodynamics models because Earth materials cannot sustain unbounded stresses. However, plasticity represents a non-trivial problem even for single-phase flow formulations with shear failure only. In two-phase systems, tensile failure of rocks can also occur due to an overpressured liquid phase. Robustly solving a discretised model that includes this physics presents severe challenges, and many questions remain as to effective solvers for these strongly nonlinear systems.

An appropriate rheological model is required to meet this challenge. The most straightforward choice is a Maxwell visco-elasto-plastic model, but this leads to grid-scale localisation and hence mesh-dependence. To obtain mesh-independent shear localisation, we employ the visco-elasto-viscoplastic model by introducing a viscous dashpot in parallel to the plasticity element. Whilst this formulation has shown promise in regularising shear failures in a single-phase flow model (de Borst and Duretz, 2020), its incorporation within two-phase systems has not been examined. We will show that the linear Griffith criteria for the tensile failure can lead to convergence issues whereas a new, hyperbolic yield surface is proposed to resolve these numerical issues. This yield surface provides a smooth transition between the two modes of failure.

The underlying PDEs are discretised using a conservative, finite-difference, staggered-grid framework implemented with PETSc (FD-PDE) that supports single-/two-phase flow magma dynamics. Here, we present simplified model problems using the FD-PDE framework for poro-viscoelastic-viscoplastic models designed to characterise the solution quality and assess both the discretisation and solver robustness. It has been observed that employing the hyperbolic yield surface improved the robustness in simulating plastic failures in both modes.

 

References

Keller, T., May, D. A., & Kaus, B. J. P., (2013). Numerical modelling of magma dynamics coupled to tectonic deformation of lithosphere and crust, Geophysical Journal International, v195, 1406-1442, https://doi.org/10.1093/gji/ggt306.

de Borst, R., Duretz, T., (2020). On viscoplastic regularisation of strain-softening rocks and soils. International Journal for Numerical and Analytical Methods in Geomechanics, v44, 890-903. https://doi.org/10.1002/nag.3046.

How to cite: Li, Y., Pusok, A., May, D., and Katz, R.: Simulation of partially molten rocks with visco-elasto-viscoplastic rheology and a hyperbolic yield surface for plasticity, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5594, https://doi.org/10.5194/egusphere-egu22-5594, 2022.

EGU22-5704 | Presentations | GD9.1 | Highlight

How composable software tools in Julia help developing multi-physics codes in geodynamics 

Boris Kaus, Nicolas Berlie, Valentin Churavy, Matias Cosarinsky, Thibault Duretz, Daniel Kiss, Jeremy Kozdon, Albert de Montserrat, Lucas Moser, Nils Medinger, Samuel Omlin, Ludovic Räss, Patrick Sanan, Arne Spang, Marcel Thielmann, and Ivan Utkin

Julia(https://julialang.org) recently emerged as a very powerful high-level computer language for (parallel) scientific computing, which allows you to “write codes like in MATLAB”, while “achieving the speed of Fortran/C”. A particular strength of Julia is that it is easy to write composable software packages that talk to each other. Here we will discuss our efforts in making Julia a development platform for geodynamic applications that significantly simplifies the process of going from a working solver to a production code which runs on massively parallel (GPU) machines.  We are working on a number of open-source packages that simplify certain steps that many geodynamics codes have in common:

  • GeoParams.jl (https://github.com/JuliaGeodynamics/GeoParams.jl) is a package in which you can specify constitutive relationships (e.g., creeplaws). It automatically handles the (non-)dimensionalization of all input parameters, includes pre-defined creep laws (e.g., dislocation and diffusion creep laws), plotting routine and includes computational routines that can be directly integrated in your code.
  • PETSc.jl (https://github.com/JuliaParallel/PETSc.jl) is the main interface from Julia to PETSc, including MPI support and automatic installations of PETSc (one of the main hurdles that existing users faced). We have recently extended the package to include an interface to DMSTAG, such that you create a staggered finite difference grid and assemble the stiffness matrix in a straightforward manner. You can use automatic differentiation tools in Julia to create the Jacobians for nonlinear equations, which again minimizes the required lines of code (compared to their C counterparts). At the same time, the full range of (nonlinear multigrid) PETSc solvers is available. This is thus very well suited to write implicit solvers.
  • ParallelStencil.jl (https://github.com/omlins/ParallelStencil.jl) and ImplicitGlobalGrid.jl (https://github.com/eth-cscs/ImplicitGlobalGrid.jl) are packages that are devoted to solving stencils in a very efficient manner on (parallel) GPU or CPU machines, which scales to very large GPU-based computers. It is particularly efficient in combination with pseudo-transient iterative solvers and allow running codes on modern architectures.
  • GeophysicalModelGenerator.jl (https://github.com/JuliaGeodynamics/GeophysicalModelGenerator.jl) is a package that gives you a simple way to collect geophysical/geological data of a certain region and combine that to construct a 3D geodynamic input model setup.

Ongoing efforts include the development of a grid generation and a marker and cell advection package that work, seamlessly with both ParallelStencil and PETSc. This will allow developers to apply both direct-iterative and pseudo-transient implicit solvers to the same problem, while only having to make minimal changes to the model setup. Combined, these packages will make the step from developing a new (nonlinear) solver to having an efficient (3D) production code much easier.

How to cite: Kaus, B., Berlie, N., Churavy, V., Cosarinsky, M., Duretz, T., Kiss, D., Kozdon, J., de Montserrat, A., Moser, L., Medinger, N., Omlin, S., Räss, L., Sanan, P., Spang, A., Thielmann, M., and Utkin, I.: How composable software tools in Julia help developing multi-physics codes in geodynamics, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5704, https://doi.org/10.5194/egusphere-egu22-5704, 2022.

One of the great challenges involved in modelling the lithosphere is its plastic behaviour, especially when dealing with compressible materials. Shear fractures are designated as mode 2 and 3 and can be described using a Linear Mohr Coulomb envelope  or a simplification of it like Drucker-Prager. Meanwhile, mode 1 fractures are created when the normal stresses become tensile  and require another yield function, such as the Griffith criterion or a tension cap function.

While the governing equations are well known and widely employed in engineering codes, they are usually expressed with a displacement formulation. Most geodynamic codes, on the other hand, use pressure and velocity as their primary variables. A numerically robust method that takes all plasticity modes into account in a staggered finite difference discretization remains an open task. Here we present a composite yield function implemented with pressure-velocity formulation, capable of producing produce shear and tensile failure.

We have implemented this in a new code that employed PETSc through the recently updated PETSc.jl Julia interface, while utilizing the automatic differentiation tools in julia. We found this workflow to significantly reduce the development time of complex nonlinear coupled codes.  

We will describe the implementation, propose regularization schemes and discuss benchmark cases and simple applications. We demonstrate Newton convergence for most cases and will discuss different methods to combine multiple plastic flow laws.

How to cite: Berlie, N., Kaus, B., Popov, A., Kiss, D., and Riel, N.: How to break the lithosphere: a compressible pressure-velocity formulation for elasto-visco-plastic rheologies that includes shear and tensile failure with dilation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6566, https://doi.org/10.5194/egusphere-egu22-6566, 2022.

EGU22-8816 | Presentations | GD9.1

GPU-based pseudo-transient finite difference solution for 3-D gravity- and shear-driven power-law viscous flow 

Emilie Macherel, Yuri Podladchikov, Ludovic Räss, and Stefan M. Schmalholz

Power-law viscous flow describes the first-order features of long-term lithosphere deformation. Due to the ellipticity of the Earth, the lithosphere is mechanically analogous to a shell, characterized by a double curvature. The mechanical characteristics of a shell are fundamentally different to the characteristics of plates, having no curvature in their undeformed state. The systematic quantification of the magnitude and the spatiotemporal distribution of strain, strain-rate and stress inside a deforming lithospheric shell is thus of major importance: stress is, for example, a key physical quantity that controls geodynamic processes such as metamorphic reactions, decompression melting, lithospheric flexure, subduction initiation or earthquakes. Calculating these stresses in a three-dimensional (3-D), geometrically and mechanically heterogeneous lithosphere requires high-resolution and high-performance computing.

 

Here, we present numerical simulations of 3-D power-law viscous flow. We employ the pseudo-transient finite difference (PTFD) method, which enables efficient simulations of high-resolution 3-D deformation processes by implementing an iterative implicit solution strategy of the governing equations. The main challenges for the PTFD method are to guarantee convergence, minimize the required iteration count and speed-up the iterations. We implemented the PTFD algorithm using the Julia language (julialang.org) to enable optimal parallel execution on multiple CPUs and GPUs using the ParallelStencil.jl module (https://github.com/omlins/ParallelStencil.jl). ParallelStencil.jl enables execution on multi-threaded CPUs and Nvidia GPUs using a single switch.

 

We present PTFD simulations of mechanically heterogeneous (weak and less dense spherical inclusion), incompressible 3-D power-law viscous flow under gravity in cartesian, cylindrical and spherical coordinates systems. The viscous flow is described by a linear combination of a linear viscous and a power-law viscous flow law, representing diffusion and dislocation creep, respectively. The iterative solution strategy builds upon pseudo-viscoelastic behavior to minimize the iteration count by exploiting the fundamental characteristics of viscoelastic wave propagation. We performed systematic numerical simulations to investigate the impact of (i) buoyancy versus shear forces and (ii) linear versus power-law viscous flow on the vertical velocity of the spherical inclusion under bulk strike-slip shearing. We report the systematic results using the controlling dimensionless numbers and compare the numerical results with analytical predictions for buoyancy-driven flow of inclusions in a power-law matrix. We also aim to unveil preliminary results for a vertically and locally loaded power-law viscous lithosphere showing the impact of different lithosphere curvatures on the resulting stress field.

How to cite: Macherel, E., Podladchikov, Y., Räss, L., and Schmalholz, S. M.: GPU-based pseudo-transient finite difference solution for 3-D gravity- and shear-driven power-law viscous flow, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8816, https://doi.org/10.5194/egusphere-egu22-8816, 2022.

EGU22-8849 | Presentations | GD9.1

Mass-Conserving Thermal Structure for Slabs in Instantaneous Models of Subduction 

Magali Billen, Menno Fraters, and Magalie Babin

Subduction is driven by difference in mass between the sinking plate and the surrounding mantle. The deformation calculated in numerical models of subduction is strongly dependent on the magnitude of the mass difference. The mass difference depends on the temperature of the slab. As the tectonic plate sinks it heats up, but it also cools down the surrounding mantle. The amount of heating and cooling is determined by conservation of thermal energy. Because the temperature also determines the thermal mass, conversing thermal energy also leads to conserving mass. For some studies, models of subduction are made to match the present day structure of a sinking plate. In this case, the temperature is defined to follow the observed geometry. In some previous studies, the temperature structure did not explicitly enforce conservation of energy or mass, and thus the density of the slab was not physically consistent, which is added source of uncertainty when analyzing the resulting flow and sensitivity of model results to mantle and slab rheology. Here we present a mass-conserving thermal structure for slabs that also creates a smoothly varying temperature structure. The thermal structure is based on a 1-D half-space cooling model (bottom) and an infinite space cooling model (top). It uses the age of the plate at the trench to determine the initial mass anomaly of the slab. The sinking velocity modifies the rate of heating and migration of the minimum temperature into the slab interior. The thermal model is calibrated against simple 2D subduction models in which the age and subduction velocity are held fixed. The new thermal structure has been implemented in the Geodynamic WorldBuilder (1), which can be used with different mantle convection software and is distributed as a plugin for ASPECT (2). Comparison of model results with the mass conserving slab thermal structure to the "plate" model from McKenzie (1970) is used to illustrate the differences in modeled results. References: 1. Fraters, M. R. T. et al., Solid earth, 2019. 2. Bangerth, W. et al., https://doi.org/10.5281/ZENODO.5131909, 2021.

How to cite: Billen, M., Fraters, M., and Babin, M.: Mass-Conserving Thermal Structure for Slabs in Instantaneous Models of Subduction, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8849, https://doi.org/10.5194/egusphere-egu22-8849, 2022.

Transient superstructures in mantle convection whose life and morphology vary with Rayleigh and Prandtl number have recently been demonstrated. These superstructures appear to be a two-scale phenomenon where smaller scale rolls organize into larger scale convection cells. Simulation of such superstructures requires the ability to model 3D convection in box with very large width/height ratio of order greater than 10, and with resolution to resolve the thermal boundary layer at Rayleigh numbers of 108 to 1010, respectively at least 100 height levels and 200 height levels. We achieve this with an efficient parallel implementation of the Lattice Boltzmann Method using Python which operates with high efficiency and linear speedup on thousands of cores. We present simulations with Rayleigh numbers of up to 1010 and Prandtl numbers from 1 to 100 to illustrate covering regimes from a magma ocean to solid mantle convection. We further present simulations using the LBM to model variable viscosity – specifically, temperature dependent– and illustrate the existence of pulsating plumes. We further demonstrate power law scaling between Nusselt number and Rayleigh number Nu  ~ Rag, which to first order is consistent with the Grossmann and Lohse theory.

How to cite: Mora, P., Morra, G., and Yuen, D.: Simulation of 3D transient superstructures in mantle convection and variable viscosity via the Lattice Boltzmann Method, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9069, https://doi.org/10.5194/egusphere-egu22-9069, 2022.

EGU22-9133 | Presentations | GD9.1

Testing a (quasi-)free base for modelling core-mantle boundary topography 

Tobias Rolf, Fabio Crameri, Björn H. Heyn, and Marcel Thielmann

The core-mantle boundary (CMB) is the most prominent compositional boundary inside the Earth. Its topography provides insight on lower mantle flow and the thermochemical structure above the CMB. Yet, CMB topography remains challenging to observe and estimates from seismology vary substantially. Numerical models of mantle convection provide complementary means to estimate CMB topography. Classically, topography is determined from the normal stresses acting on the CMB. However, this is known to face severe complications when applied to the surface boundary of the mantle, leading to non-Earth-like topographic scales and a different style of subduction. A (quasi-)free surface yields more Earth-like predictions, but for the CMB this comparison has never been made.

Here, we compare CMB topography predicted from mantle convection modelling using different treatments of the CMB. Specifically, we test the role of a ‘sticky core’, a quasi-fluid approximation the core. We compare results predicted by different codes (with either sticky core or true free base) and compare to a simple analytical case. Also, we simulate the evolution of subduction and deep thermochemical provinces to compare the topography of the (quasi-)free CMB and the free-slip approach. Initial results indicate that the sticky core approach can reproduce CMB topography reasonably well, but has rather high computational cost (grid resolution, number of particles). In analogy to the sticky air at the surface, the viscosity contrast of the sticky core layer determines the quality of predicted topography, with larger contrasts (≥103) leading to acceptable levels of artificial CMB topography. In dynamic flow cases with vigorous mantle convection, entrainment by plumes further complicates application of the sticky core, but can be tackled with an unmixing procedure. A true free base tends to better accuracy than the sticky core approach and avoids the problem with entrainment, but it also comes with additional computational costs as various forces at the CMB have to be taken into account.

How to cite: Rolf, T., Crameri, F., Heyn, B. H., and Thielmann, M.: Testing a (quasi-)free base for modelling core-mantle boundary topography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9133, https://doi.org/10.5194/egusphere-egu22-9133, 2022.

EGU22-9232 | Presentations | GD9.1

Automatic generation of the adjoint of the StagYY mantle convection model 

Nicolas Coltice, Simon Blessing, Ralf Giering, and Paul Tackley

Motions within the Earth mantle and tectonics constitute a single self-organized system which is cooling the planet over its geological history. Since the end of the XXth century, models of mantle convection self-generating plate tectonic behavior have progressed to a state that makes them applicable to global tectonic problems. The possibility of combining geological and geophysical data with dynamic models to retrieve the recent history of mantle flow and tectonics becomes realistic. Therefore, it is a challenge to build inverse methods to study inverse and sensitivity problems in the Earth's mantle convection. We have automatically generated the tangent-linear and the adjoint source code from the StaggYY code (Tackley, Phys. Earth Planet. Int. 171, 7-18, 2008). The Fortran code of the model was translated to the corresponding derivative codes using TAF (Transformation of Algorithms in Fortran), source-to-source translator. All codes run in parallel mode, using MPI (Message Passing Interface). The economic taping strategy of TAF, including re-computations, and checkpointing, helps to keep the memory footprint of the adjoint code low and the performance high. We highlight some key features of the automatic differentiation, evaluate the performance of the adjoint code, and show first results from 2D and 3D sensitivity fields, focusing on the relationships between temperature in the mantle and tectonics. Ultimately the addjoint code shall be applied to inversion and assimilation problems using a bayesian framework.

How to cite: Coltice, N., Blessing, S., Giering, R., and Tackley, P.: Automatic generation of the adjoint of the StagYY mantle convection model, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9232, https://doi.org/10.5194/egusphere-egu22-9232, 2022.

EGU22-9815 | Presentations | GD9.1

Assessing the robustness and scalability of the accelerated pseudo-transient method towards exascale computing 

Ivan Utkin, Ludovic Rass, Thibault Duretz, Samuel Omlin, and Yury Podladchikov

The development of highly efficient, robust, and scalable numerical algorithms lags behind the rapid increase in massive parallelism of modern hardware. In this work, we address this challenge with the accelerated pseudo-transient iterative method. This method is motivated by the physical analogy between numerical iterations and transient processes converging to a steady state.

We analytically determine optimal iteration parameters for a variety of basic physical processes such as diffusion, diffusion-reaction and non-inertial viscous fluid flow featuring Maxwell viscoelastic rheology. We further confirm the validity of theoretical predictions with numerical experiments.

We provide an efficient numerical implementation of various pseudo-transient solvers on graphical processing units (GPUs) using the Julia language. We achieve a parallel efficiency over 96% on 2197 GPUs in distributed memory parallelisation weak scaling benchmarks. 2197 GPUs allow for unprecedented terascale solutions of 3D variable viscosity Stokes flow involving over 1.2 trillion degrees of freedom.

We verify the robustness of the method by handling contrasts up to 9 orders of magnitude in material parameters such as viscosity, and arbitrary distribution of viscous inclusions for different flow configurations. Moreover, we show that this method is well suited to tackle strongly nonlinear problems such as shear-banding in a visco-elasto-plastic medium.

We additionally motivate the accessibility of the method by its conciseness, flexibility, physically motivated derivation, and ease of implementation. This solution strategy has thus a great potential for future high-performance computing applications, and for paving the road to exascale in the geosciences and beyond.

How to cite: Utkin, I., Rass, L., Duretz, T., Omlin, S., and Podladchikov, Y.: Assessing the robustness and scalability of the accelerated pseudo-transient method towards exascale computing, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9815, https://doi.org/10.5194/egusphere-egu22-9815, 2022.

EGU22-10412 | Presentations | GD9.1

Rate and state friction on spontaneously evolving faults 

Casper Pranger, Patrick Sanan, Dave May, Laetitia Le Pourhiet, Ludovic Räss, and Alice Gabriel

The rate- and state-dependent friction (RSF) laws (Dieterich, 1979; Ruina, 1983) have been widely successful in capturing the behavior of sliding surfaces in laboratory settings, as well as reproducing a range of natural fault slip phenomena in numerical models.

Studies of exhumed fault zones make it clear that faults are not two-dimensional features at the junction of two distinct bodies of rock, but instead evolve into complex damage zones that show clear signs of multi-scale fracturing, grain diminution, hydro-thermal effects and chemical and petrological changes. Many of these observed factors have been experimentally verified, and several studies have furthered our theoretical understanding of earthquakes and other seismic phenomena as volumetric, bulk-rock processes, including Sleep (1995, 1997), Lyakhovsky and Ben-Zion et al. (2011, 2014a,b, 2016), Niemeijer and Spiers et al. (2007, 2016, 2018), Roubicek (2014), and Barbot (2019).

While the established numerical modeling approach of simulating faults as planar features undergoing friction can be a useful and powerful homogenization of small-scale volumetric processes, there are also cases where this practice falls short -- most notably when studying faults that grow and evolve in response to a changing tectonic environment. This is mainly due to the computational challenges associated with automating the construction of a fault-resolving conformal mesh.

Motivated by this issue, we formulate a generalization of RSF as a plastic or viscous flow law with generation, diffusion, and healing of damage that gives rise to mathematically and numerically well-behaved finite shear bands that closely mimic the behavior of the original laboratory-derived formulation (Pranger et al., submitted). The proposed formulation includes the well-known RSF laws for an infinitely thin fault as a limit case as the damage diffusion length scale tends to zero. We will show the behavior of this new bulk RSF formulation with results of high-resolution 1D and 2D numerical simulations.

Dieterich, J.H. (1979), J. Geophys. Res., 84 (B5), 2161.
Ruina, A. (1983), JGR: Solid Earth, 88 (B12), 10359–10370.
Sleep, N.H. (1995), JGR, 100 (B7), 13065–13080.
Sleep, N.H. (1997), JGR: Solid Earth 102 (B2), 2875–2895.
Roubíček, T. (2014), GJI 199.1, 286–295.
Lyakhovsky, Hamiel and Ben-Zion (2011), J. Mech. Phys. Solids, 59, 1752-1776.
Lyakhovsky and Ben-Zion (2014a), PAGeoph 171.11, 3099–3123.
Lyakhovsky and Ben-Zion (2014b), J. Mech. Phys. Solids 64, 184–197.
Lyakhovsky, Ben-Zion et al. (2016), GJI 206.2, 1126–1143.
Barbot (2019), Tectonophysics 765, 129–145.
Niemeijer and Spiers (2007), JGR 112, B10405,
Chen and Spiers (2016), JGR: Solid Earth 121, 8642–8665.
van den Ende, Chen et al. (2018), Tectonophysics 733, 273-295.
Pranger et al. (202X), ESSOAr (https://www.essoar.org/doi/10.1002/essoar.10508569.1)

How to cite: Pranger, C., Sanan, P., May, D., Le Pourhiet, L., Räss, L., and Gabriel, A.: Rate and state friction on spontaneously evolving faults, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10412, https://doi.org/10.5194/egusphere-egu22-10412, 2022.

EGU22-11131 | Presentations | GD9.1

The Face-Centered Finite Volume method for Geodynamic Modelling 

Thibault Duretz, Ludovic Räss, and Rubén Sevilla

The Face-Centered Finite Volume (FCFV) is a newly developed discretisation technique that has been applied to a variety of engineering problems. This approach is based on the hybridisable discontinuous Galerkin formulation with constant degree approximations. The FCFV is particularly attractive approach since it meets numerous essential criteria for successful geodynamic modelling. It offers full geometric flexibility, natural free surface boundary condition, second order accuracy velocity-field solutions, no oscillatory pressure modes, relatively low computational cost and adequate treatment of jump conditions at material interfaces. Here we present the implementation of Poisson and Stokes solvers in the Julia computing language. Here we present the implementation of Poisson and Stokes solvers using the performant Julia language. We discuss several solving strategies including direct-iterative and iterative pseudo-transient approaches, the latter executing efficiently on Graphical Processing Units. We extend the original FCFV Stokes formulation to account for discontinuous viscosity case and discuss the implementation of complex visco-elasto-plastic rheologies.

How to cite: Duretz, T., Räss, L., and Sevilla, R.: The Face-Centered Finite Volume method for Geodynamic Modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11131, https://doi.org/10.5194/egusphere-egu22-11131, 2022.

EGU22-11469 | Presentations | GD9.1

Strain localization in a visco-elasto-plastic medium using strain-dependent weakening and healing rheology 

Lukas Fuchs, Thibault Duretz, and Thorsten W. Becker

The formation and maintenance of narrow, lithospheric shear zones and their importance in plate-tectonics remain one of the major problems in geodynamics. While the cause and consequence of strain localization and weakening within the lithosphere remain debated, it is clear that these processes play an essential role in lithospheric deformation across a wide range of spatio-temporal scales. Here, we analyze the efficiency of strain localization in a 2-D visco-elasto-plastic medium for a strain-dependent weakening and healing (SDWH) rheology using 2-D numerical, thermo-mechanical experiments with kinematic boundary conditions. Such a parameterized rheology successfully mimics more complex transient weakening and healing processes, akin to a grain-size sensitive composite (diffusion and dislocation creep) rheology. In addition, the SDWH rheology allows for memory of deformation. This enables self-consistent formation and reactivation of inherited weak zones within the lithosphere and sustains those weak zones over an extended period of time. We further analyze the resulting shear zone patterns and seek to answer the questions: What is the typical, effective intensity of strain localization? What are the dimensions of the resulting shear zones? Are such shear zones mesh-dependent in numerical models and, if so, can we exploit existing regularization approaches for the SDWH rheology?

How to cite: Fuchs, L., Duretz, T., and Becker, T. W.: Strain localization in a visco-elasto-plastic medium using strain-dependent weakening and healing rheology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11469, https://doi.org/10.5194/egusphere-egu22-11469, 2022.

EGU22-11494 | Presentations | GD9.1

MAGEMin, a new and efficient Gibbs free energy minimizer: application to igneous systems 

Nicolas Riel, Boris Kaus, Eleanor Green, and Nicolas Berlie

Modelling stable mineral assemblage is crucial to calculate mineral stability relations in the Earth’s lithosphere e.g., to estimate thermobarometric conditions of exposed rocks and to quantify the fraction and composition of magma during partial melting. Accurate prediction models of stable phase are also fundamental to model trace element partitioning and to extract essential physical properties such as, fluid/melt/rock densities, heat capacity and seismic velocities. This thus forms a crucial step in linking geophysical observations with petrological constraints.

Here, we present a new Mineral Assemblage Gibbs free Energy Minimizer (MAGEMin). The package has been developed with the objective to provide a minimization routine that is easily callable and fulfilling several objectives. Firstly, the package aims to consistently compute for single point calculations at given pressure, temperature and bulk-rock composition with no needed a priori knowledge of the system. Secondly, the package has been developed for stability, performance and scalability in complex chemical systems. Finally, the code is fully parallel and we directly translate THERMOCALC formulation of solution models which yields easier and faster updates, less prone to implementation mistakes.

As a proof of concept we apply our new approach to the thermodynamic dataset for igneous systems of Holland et al. (2018). The database works in the NCKFMASHTOCr chemical system and has been updated to account for the new plagioclase model Holland et al. (2021).

How to cite: Riel, N., Kaus, B., Green, E., and Berlie, N.: MAGEMin, a new and efficient Gibbs free energy minimizer: application to igneous systems, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11494, https://doi.org/10.5194/egusphere-egu22-11494, 2022.

EGU22-12156 | Presentations | GD9.1

Dynamic mesh optimisation for efficient numerical simulation of density-driven flows: Application to the 2- and 3-D Elder problem 

Meissam L. Bahlali, Pablo Salinas, and Matthew D. Jackson

Density-driven flows in porous media are frequently encountered in natural systems and arise from the gravitational instabilities introduced by fluid density gradients. They have significant economic and environmental impacts, and numerical modelling is often used to predict the behaviour of these flows for risk assessment, reservoir characterisation or management. However, modelling density-driven flow in porous media is very challenging due to the nonlinear coupling between flow and transport equations, the large domains of interest and the wide range of time and space scales involved. Solving this type of problem numerically using a fixed mesh can be prohibitively expensive.  Here, we apply a dynamic mesh optimisation (DMO) technique along with a control-volume-finite element method to simulate density-driven flows. DMO allows the mesh resolution and geometry to vary during a simulation to minimize an error metric for one or more solution fields of interest, refining where needed and coarsening elsewhere. We apply DMO to the Elder problem for several Rayleigh numbers. We demonstrate that DMO accurately reproduces the unique two-dimensional (2D) solutions for low Rayleigh number cases at significantly lower computational cost compared to an equivalent fixed mesh, with speedup of order x16. For unstable high Rayleigh number cases, multiple steady-state solutions exist, and we show that they are all captured by our approach with high accuracy and significantly reduced computational cost, with speedup of order x6. The lower computational cost of simulations using DMO allows extension of the high Rayleigh number case to a three-dimensional (3D) configuration and we demonstrate new steady-state solutions that have not been observed previously. Early-time, transient 3D patterns represent combinations of the previously observed, steady-state 2D solutions, but all evolve to a single, steady-state finger in the late time limit.

How to cite: Bahlali, M. L., Salinas, P., and Jackson, M. D.: Dynamic mesh optimisation for efficient numerical simulation of density-driven flows: Application to the 2- and 3-D Elder problem, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12156, https://doi.org/10.5194/egusphere-egu22-12156, 2022.

EGU22-12398 | Presentations | GD9.1

Nonlinear solver acceleration based on machine learning applied to multiphase porous media flow 

Vinicius Silva, Pablo Salinas, Matthew Jackson, and Cristopher Pain

We present a machine learning strategy to accelerate the nonlinear solver convergence for multiphase porous media flow problems. The presented approach dynamically controls an acceleration method based on numerical relaxation. The methodology is implemented and demonstrated in a Picard iterative solver; however, it can also be used with other types of nonlinear solvers. The goal of the machine learning acceleration is to reduce the number of iterations required by the nonlinear solver by adjusting the value of the relaxation factor to the complexity/physics of the system. A set of dimensionless parameters is used to train and control the machine learning. In this way, a simple two-dimensional layered reservoir can be used for training while still exploring a large portion of the dimensionless parameter space. As a result, the training process is simplified, and the machine learning model can be applied to any type of reservoir models.

We demonstrate that the presented technique dramatically reduces the number of nonlinear iterations without sacrificing the quality of the results, even for models that are far more complex than the training case. The average reduction in the number of nonlinear iterations obtained due to the presented method is 24% and the reduction in runtime is 37%. It is worth noting that the optimum value of the relaxation factor is not known a-priori and it is problem specific. Hence, having an acceleration that adapts itself to the complexity/physics of the system throughout the numerical simulation is extremely valuable and has driven several publications in multiple fields.

The method presented here provides an easy way to deal with nonlinear system of equations that does not necessitate as much effort as a custom nonlinear solver while producing outstanding results. We believe that the machine learning acceleration is not limited to the multiphase porous media flow but extendable to any other system that can be studied based on dimensionless numbers, and that a relaxation technique can be used to stabilize the nonlinear solver.

How to cite: Silva, V., Salinas, P., Jackson, M., and Pain, C.: Nonlinear solver acceleration based on machine learning applied to multiphase porous media flow, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12398, https://doi.org/10.5194/egusphere-egu22-12398, 2022.

TS10 – Time scales, rates and age determinations of tectonic processes

EGU22-529 | Presentations | TS10.1

Sinistral Strike Slip Faults of the Kyrgyz Tien Shan 

Ian Pierce, Kanatbek Abdrakhmatov, Sultan Baikulov, Erkin Rakhmedinov, Gulkaiyr Tilek Kyzy, Ben Johnson, Gordon Seitz, Ramon Arrowsmith, Magali Rizza, and Richard Walker

The Tien Shan are an intracontinental mountain belt experiencing shortening as a result of far field deformation from the ongoing India-Eurasian collision. At the longitude of Kyrgyzstan the Tien Shan accommodate ~20 mm/yr of shortening. In central Kyrgyzstan, the most well studied faults include the northwest-striking right-lateral Talas Fergana fault and the series of east-striking reverse & thrust faults that form the basins and subranges that accommodate most of this compression. Yet in satellite imagery, some of the most prominent fault ruptures appear on a series of east-northeast-striking left-lateral strike slip faults. Little is known about the paleoseismology, rate of slip, or tectonic role of these faults. Here we present new drone-based high resolution topography and imagery along with geomorphic, geochronology, paleoseismic, and slip rate data for four of these sinistral faults. The studied faults are in the Aksay, Kazarman, Issyk Kul, and Song Kol basins. These data reveal that each fault has produced Holocene surface ruptures with single event displacements as great as 5-7 m along faults as long as ~100 km, corresponding to M~7.5 earthquakes. We propose a structural model to explain how these faults may have evolved from reverse faults that have rotated about their horizontal axis and then reactivated as strike slip faults due to their optimal alignment in the current stress field. How the existence of these faults affects seismic hazards is a question of discussion, as they are currently not considered in the regional strain budget that is largely based on compression.

How to cite: Pierce, I., Abdrakhmatov, K., Baikulov, S., Rakhmedinov, E., Tilek Kyzy, G., Johnson, B., Seitz, G., Arrowsmith, R., Rizza, M., and Walker, R.: Sinistral Strike Slip Faults of the Kyrgyz Tien Shan, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-529, https://doi.org/10.5194/egusphere-egu22-529, 2022.

EGU22-3222 | Presentations | TS10.1

Unraveling the role of ancient orogens in present-day rifting using tectonic geomorphology in Shanxi, North China 

Malte Froemchen, Ken McCaffrey, Mark Allen, Jeroen van Hunen, and Thomas Phillips

Many rifts are influenced by pre-existing structures and heterogeneities during their evolution, a process known as structural inheritance. During a rift’s evolution, these heterogeneities may aid the nucleation of the rift, growth and segmentation of faults, aid linkage of various segments or even inhibit the formation of faults in various places. Structural inheritance is well explored in offshore rift settings due to the availability of high-quality 3D seismic, which enables good constraint on the structural evolution. However, the degree of structural inheritance in onshore active rifts is more difficult to constrain due to a lack of subsurface datasets. Yet, understanding how structural inheritance influences early rift evolution is vital to better understand seismic risk in areas of active rifting. The Shanxi Graben in the North of China is a densely populated active rift system that is believed to have formed along the trend of the Precambrian Trans North China Orogen. However, the influence of these Precambrian structures on the present-day rifting is poorly constrained. Here we show how the impact of structural inheritance on a young active rift may be investigated using tectonic geomorphological techniques - e.g., hypsometric integral, channel steepness (KsN) and drainage network analysis (chi analysis). Using the geomorphic expression of active faults, we can quantify their geomorphic response and identify faults that show higher levels of activity. Our results show that large basin bounding faults broadly follow the trends of basement fabrics but show a lower geomorphic response, while smaller faults that link the main basins show higher levels of geomorphic response but seemingly crosscut the basement fabrics. We interpret that those large faults formed first in regions with basement fabrics that were preferably orientated to the principal stress direction. Faults in the linkage zones between major basins likely formed later due to local perturbations of the stress field by the major rift faults. This means that there is no need for a changing stress field during the evolution of the Shanxi Graben, as previously proposed, but that the graben evolved under a relatively uniform stress field. Using the hypsometric integral or drainage network analysis may prove useful when applied to other areas with active rifts influenced by structural inheritance such as East Africa. Due to the lack of data in these regions, geomorphic analysis might prove useful in the study of the temporal evolution of structural inheritance in young active rifts.

How to cite: Froemchen, M., McCaffrey, K., Allen, M., van Hunen, J., and Phillips, T.: Unraveling the role of ancient orogens in present-day rifting using tectonic geomorphology in Shanxi, North China, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3222, https://doi.org/10.5194/egusphere-egu22-3222, 2022.

Abstract: Most of the coastal areas along the South Pacific are mainly uplifting due to subduction processes. The geomorphology of the Mejillones Peninsula, located in one of the seismic gaps of northern Chile at 23°S, is characterized by Quaternary alluvial fans, marine terraces, coastal cliffs, and fault scarps, among others. These features are very well preserved due to hyper-aridity conditions recognized in the area from the Plio-Pleistocene and represent the evidence of the uplift during that time. Quaternary marine terraces (QMT) have been studied to understand the permanent deformation of the forearc, in particular the differences in the uplift rates along the coast. A morpho-metric analysis using ALOS-PALSAR remote sensors and local differential GPS data, besides the use of software, as well as fieldwork, allows us to define the best-preserved QMT sequences and the height at which they are found with respect to the current mean sea level. From this, we correlate the platforms of each marine terrace with the corresponding Marine Isotope Stage (MIS) during the Quaternary, and we estimate associated uplift rates in order to study the role of the Quaternary faults in the differential uplift along the coastal area. From our morpho-metric analysis we determined 3 representative areas with well-preserved marine terraces: Punta Angamos (~12x10 km²), Hornitos (8x4 km²) and Punta Chacaya (4x4 km²). Hornitos and Punta Chacaya are both located in the continent, while Punta Angamos is located in the north part of the peninsula. The results show significant differences both in the morpho-structural features and in the estimates of the uplift rates. We have identified at least 13 QMT in Punta Angamos that can be separated into 2 groups: the last 9 platforms would be associated to the last 570 ka, with uplift rates between 0.42 to 0.55 m/ka; and the highest 4 platforms, that would be associated with Early Pleistocene and Pliocene, where it is not possible to obtain reliable uplift rates for the moment. In Hornitos, we have identified 3 QMT, with uplift rates between 0.24 to 0.31 m/ka for the last 225 ka, and in Punta Chacaya, we identified 4 QMT, with uplift rates between 0.14 and 0.29 m/ka for the last 321 ka. We also identified a platform that could be correlated to the last interglacial (MIS 1) in Hornitos and Punta Angamos, with an estimated uplift rate of 0.92 m/ka and 1.7 m/ka respectively. These preliminary results suggest that, for the last ~20 ka, there has been an acceleration in the uplift rates. That change can be interpreted as the result of the distance to the trench – the closer to the trench, the subduction process affects the most –, which could indicate a change in the subduction regime, as well as the Quaternary activity of the Morro and Mejillones faults, among other faults, that allows differential uplift.

Keywords: Morro fault, Mejillones fault, MATLAB, TerraceM, differential GPS.

How to cite: Vergara, P. and Marquardt, C.: Uplift rates accelerations along 23°S Chilean coast in the Quaternary: preliminary results from the case of Mejillones Peninsula, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3299, https://doi.org/10.5194/egusphere-egu22-3299, 2022.

EGU22-3588 | Presentations | TS10.1

Refining rates of active crustal deformation in the upper plate of subduction zones, implied by geologic and geodetic data: The E-dipping West Crati Fault, southern Italy. 

Marco Meschis, Giordano Teza, Letizia Elia, Giovanni Lattanzi, Miriana Di Donato, and Silvia Castellaro

In order to investigate crustal deformation within the upper plate of the Ionian Subduction Zone (ISZ) at different time scales, we have (i) mapped and modelled sequence of Late Quaternary raised marine terraces tectonically deformed by the West Crati normal fault, in northern Calabria, and (ii) refined geodetic rates of crustal extension from continuous GNSS measurements. Indeed, this region experienced damaging earthquakes such as the “1184 Valle del Crati” (M 6.7) and the “1638 Crotonese” (M 6.7) events, possibly on the West Crati Fault; however, an in-depth evaluation of the deformation rates inferred from geologic and GNSS data has not yet been performed. Furthermore, fault slip-rates and earthquake recurrence intervals for the understudied West Crati Fault are still debated and poorly-constrained. Raised Late Quaternary marine terraces are preserved on the footwall of the West Crati Fault; however, it is still debated if the “local” effect of the footwall uplift is affecting the “regional” signal of uplift likely related to the deformation associated either with the subduction or mantle upwelling processes. Within the investigated region lying in the northern part of the uplifting Calabrian-Peloritani Arc there are 32 regionally distributed permanent GNSS stations, for 18 of which the coordinate time series are adequately long (at least 4.5 years) to allow the study of the crustal kinematics. The data of these 18 stations are used to geodetically estimate fault slip-rates and then earthquake recurrence intervals for the West Crati Fault, with the aim of at least partially solve the aforementioned problem of the poor constrains. In particular, velocity and strain across this fault, based on reasonable hypotheses about the fault dip and the mechanical properties of the involved material, are computed starting from GNSS data about the surface kinematics.

Our preliminary results show that GIS-based elevations of Middle to Late Pleistocene palaeoshorelines, as well as temporally constant uplift rates, vary along the strike of the West Crati Fault, mapped on its footwall. This suggests that the fault slip-rate governing seismic hazard has also been constant through time, over multiple earthquake cycles. We then suggest that our geodetically-derived fault slip-rate for the West Crati Fault may be a more than reasonable value to be used over longer time scales for an improved seismic hazard approach, allowing to derive new earthquake recurrence intervals. These results thus suggest a significant yet understudied seismic hazard for the investigated area also because the regional extension might be likely accommodated by a few more active faults across-strike in northern Calabria. These facts highlight the importance of mapping crustal deformation within the upper plate above subduction zones to avoid unreliable interpretations relating to the mechanism controlling regional uplift.

How to cite: Meschis, M., Teza, G., Elia, L., Lattanzi, G., Di Donato, M., and Castellaro, S.: Refining rates of active crustal deformation in the upper plate of subduction zones, implied by geologic and geodetic data: The E-dipping West Crati Fault, southern Italy., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3588, https://doi.org/10.5194/egusphere-egu22-3588, 2022.

EGU22-4432 | Presentations | TS10.1

Paleoseismological findings along the identified back thrust in the Eastern Himalayan foothills near the India-Bhutan border 

Chandreyee Chakrabarti Goswami, Manoj Jaiswal, Sujit Dasgupra, and Atul Singh

The tectonic landscape of the Himalayas is mainly depicted by the E-W trending major regional thrusts, the southernmost being the Himalayan frontal Thrust (HFT) or the Main Frontal Thrust (MFT. But there are also out of sequence transverse faults and back thrusts that play important role in strain adjustment.

The map traces of thrust faults make cuspate-lobate patterns suggesting differential fault growth. These orogen-scale curvatures at an intermediate scale are expressed as salients and recesses. Salients are normally associated with mountain fronts defined by frontal imbricate faults, whereas recesses are open to the foreland. Himalayan salients, recesses, and associated cross-structures help in determining the deformation kinematics along the length of the Himalayan arc over space and time.

In the Eastern Himalaya, east of the Tista River, the sequential and out-of-sequence structures are well observed in the Jaldhaka recess. Here the splay on the HFT is marked by southerly sloping Chalsa and Matiali scarps whereas the northerly sloping Thaljhora scarp represents the Frontal Back Thrust (FBT).

In this study, we are presenting the geometry and structural detail of the back thrust below the Thaljhora scarp. The attitude of the thrust plane, folding of the bedding, and displacement is evident from an excavated trench perpendicular to the strike of the fault scarp. The folded beds join against the thrust plane to form a piggyback structure. The thrust plane dips 20→ S. The maximum displacement of the bed is recorded at 4.5cm along the thrust plane. There are liquefaction structures, convolute laminations and flame structures within the deformed sediments. The attitude of the gentler limb of the fold is about 400→S and that of the steeper climb is around 55-60 degrees towards North.

From earlier works (Guha et al. 2010, Singh et al, 2016, Goswami et al., 2019) the age of deposition of different sediments of this area varies from 70ka to 22ka. The oldest sediment here from the north bank of Thaljhora River, below the deformed boulder bed, is around 70 ka., eastward from the same bank from an upper stratum, comprising of black sandy clay dated around 27ka, a black clay around 6m high from the river bed, on the Thaljhora scarp itself dated as around 37 ka whereas from somewhere within that scarp dated as around 22ka. From the present study, the sediments which are deformed and displaced gives the depositional dates varying from 14 to 17ka. So, it can be said that the faulting or thrusting which has formed the scarp is at least as young as 14ka.

The movement on the splay of HFT in the adjacent Matiali fan started earlier than 70 ka and the major upliftment forming the T2 terrace was around 20ka.

The movement along the Thaljhora fault started somewhere between 20-30ka. This movement may have started to adjust the stress along the northerly dipping fault. These two northerly and southerly dipping thrust systems may be interpreted as a conjugate thrust which maybe adjust the stress in this particular area.

How to cite: Chakrabarti Goswami, C., Jaiswal, M., Dasgupra, S., and Singh, A.: Paleoseismological findings along the identified back thrust in the Eastern Himalayan foothills near the India-Bhutan border, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4432, https://doi.org/10.5194/egusphere-egu22-4432, 2022.

EGU22-6740 | Presentations | TS10.1

Late Quaternary Stratigraphic Features in the Ilan Basin, an Active Tectonic Subsidence Basin in Taiwan 

Pin-Ju Su, Kuan-Yu Chen, and Yi-Jung Lin

The Ilan Basin, located at the southwestern end of the Okinawa Trough, was mostly believed to be formed due to the expansion of the Okinawa Trough. However, recent marine surveys show that they may not be directly related. On the other hand, existing terrestrial surveys concentrated on the Oligocene to Miocene formations instead of the tectonic activities during the Last Glacial period to Holocene, and contradictions remain in the interpretation of the paleo-environment. This study analyzed 40 cores of Ilan Plain, reconstructed the paleo-sedimentary environment, and interpreted the seismic profiles. We found that the transgression of the Ilan Plain in the Last Glacial period was controlled by tectonic activities. The subsequent main transgression that happened in 17.5 ka and 15~14ka was driven by the rapid sea-level rise after the Last Glacial Maximum and the Melting-water Pulse 1A event. The tectonic subsidence of the Ilan Basin was centered on the deepest part of the basement. The combination of subsidence rate and sediment supply was generally stable before 4,000 years ago, but the subsidence rate has increased significantly since then, and the sediments supply has also been increased. The sediments not only filled the deepest area in the north of Lanyang River but also left the seismic facies of forwarding propagation on the Ilan shelf. In addition, there may be another sinking center in the south before 10 thousand years ago. This study continues to establish the complete sedimentary model of the Ilan Basin and to discuss the timing and causes of the main changes in the sedimentary environment. This study will improve our understanding of the tectonic subsidence model of the Ilan Basin and the sedimentary system in the basins with significant tectonic subsidence.

How to cite: Su, P.-J., Chen, K.-Y., and Lin, Y.-J.: Late Quaternary Stratigraphic Features in the Ilan Basin, an Active Tectonic Subsidence Basin in Taiwan, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6740, https://doi.org/10.5194/egusphere-egu22-6740, 2022.

EGU22-11284 | Presentations | TS10.1

The topographic signature of relative sea level in numerical and real landscapes. 

Luca C. Malatesta and Kimberly L. Huppert

Crustal deformation along active coastline can be constrained with age and elevation of marine terraces. These are essentially the product of an erosive process (waves eroding bedrock) and a preservation process (rock uplift moving terraces up and away from subsequent wave erosion). The morphology that results from this combination depends nonlinearly on the characteristics of the two processes. In particular, variations in rock uplift rate can promote or hinder the creation of marine terraces at specific age and elevations (e.g., past sea level high stands).  While widespread and well-outlined in some coastal settings, marine terraces can be rare or absent from other areas despite the coexistence of the two driving processes. If they do not produce discrete terraces, wave erosion and rock uplift still contribute to shaping the coastal landscape in conjunction with subaerial processes, and their history is somehow encoded in the topography. Using the logic of a “sea level occupation map” that we introduced to describe the cumulative effect of wave erosion during the eustatic seesaw (Malatesta et al., 2022), we inspect the hypsometry of numerical and real landscapes whether or not they hold terraces. Hypsometry allows for a continuous representation, and inspection, of parameters in numerical models. In real landscapes, a hyspsometric survey does not require very high resolution digital elevation models, and produces tractable information from the entire topography. In this contribution we 1) explain our approach to create a metric that can be equally applied to numerical and real landscapes; 2) highlight threshold effects in numerical outputs that were difficult to identify previously; and 3) present preliminary results extracting valuable information about rock uplift rate and sea level occupation from coastal landscapes with limited or no marine terraces.

How to cite: Malatesta, L. C. and Huppert, K. L.: The topographic signature of relative sea level in numerical and real landscapes., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11284, https://doi.org/10.5194/egusphere-egu22-11284, 2022.

EGU22-11349 | Presentations | TS10.1

Quantifying active faulting using marine terraces, Kythira island, Greece 

Julius Jara-Muñoz, Konstantinos Tsanakas, Efthymios Karymbalis, Cengiz Yildirim, Kevin Pedoja, Dimitrios- Vasileios Batzakis, and Diamantina Griva

The coastal morphology of islands may furnish valuable information regarding deformation rates, their controlling mechanisms and the dynamics of the upper crust in offshore areas along subduction zones. Here we study active deformation and faulting at glacial-cycle time scales in the Kythira island, located at the western part of the Hellenic subduction zone, between Crete Island and the Peloponnese. The island exposes an outstanding sequence of more than twelve successive levels of marine terraces that depict the Pleistocene active uplift of the island. The marine terraces are offset by several NNW-SSE and NNE-SSW active faults. We use high-resolution topography combined with morphometric analysis to map the sequence of marine terraces and active faults. We divide the marine terrace sequence into two groups, the higher marine terraces (260 – 480 masl) include polygenic rasa surfaces, the lower terraces (20 – 220 masl) are characterized by staircase morphologies. Based on a proposed correlation with sea level curves, we estimated ages ranging between MIS 17 and MIS 22 (712 – 1000 ka) for the higher terraces and between MIS 5 and MIS 15 (125 – 620 ka) for the lower terraces. We focus on the two main faults of the island, defined as F1 and F2, they display right- and left-lateral and dip slip displacements, offsetting the marine terrace risers and treads and producing local drainage anomalies. Based on the proposed terrace ages we derived preliminary heave rates between 0.3 and 0.5 m/ka for the right-lateral fault F1 and between 0.8 and 1 m/ka for the left-lateral fault F2. Mean throw rates vary between 0.01 m/ka and 0.03 m/ka for F1 and F2 respectively. We link the activity of these faults with the occurrence of intermediate-depth and strong magnitude earthquakes such as the Mw 6.6 and 6.7 occurred in the area of Kythira in 1903 and 2006, respectively. Further dating of marine terrace deposits and surfaces, and structural analysis will be carried soon to refine our preliminary estimates. Our work emphasizes on the importance of studying islands to elucidate vertical and horizontal deformation rates in offshore areas of subduction zones.

How to cite: Jara-Muñoz, J., Tsanakas, K., Karymbalis, E., Yildirim, C., Pedoja, K., Batzakis, D.-V., and Griva, D.: Quantifying active faulting using marine terraces, Kythira island, Greece, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11349, https://doi.org/10.5194/egusphere-egu22-11349, 2022.

EGU22-11435 | Presentations | TS10.1

Tectonic processes responsible for various wavelengths of permanent deformation on the western coast of South America 

Roland Freisleben, Julius Jara-Muñoz, Daniel Melnick, Manfred Strecker, and Peter van der Beek

Abstract. The tectonically active western coast of South America is characterized by the accumulation of deformation that contributes to permanent uplift of the Andean forearc at glacial-cycle timescales. However, the individual mechanisms responsible for long-term coastal uplift are still debated, mostly because analyses at continental-scale have not been carried out as yet. In coastal realms, permanent deformation is often estimated from marine terraces, which depict the interplay between wave erosion, tectonic uplift, and sea-level changes. Based on ~2000 elevation measurements of last interglacial marine terraces, we performed wavelength analyses using fast Fourier transforms. We compared the resulting uplift-rate signal with various tectonic processes and subduction parameters associated with the accumulation of permanent deformation. We detected a constant background signal of uplift along the South American margin (median rate: 0.22 mm/yr), which is disturbed by short-, intermediate- and long-wavelength changes between ~20 and ~800 km wavelengths, with the most prominent wavelengths at scales of ~500 km. Similarities between the wavelength spectra of uplift rate and signals from tectonic parameters suggest potential correlations, although multiple individual mechanisms usually contribute to a larger wavelength peak or to a certain range of wavelengths. For instance, crustal faulting is responsible for short-wavelength deformation (<100 km) and strong megathrust earthquakes (MW>7.5) mostly cover wavelength ranges from ~100 to 200 km, despite reaching wavelengths over 600 km as well. The subduction of bathymetric anomalies and the extent of interseismic locking correlate with intermediate wavelengths (~200 to ~500 km), whereas residual gravity anomalies, basal friction, and background seismicity correlate with long-wavelength deformation (>500 km). We suggest that the constant background signal of uplift rate results from two possible mechanisms: (a) a combination of multiple processes acting at different wavelengths, times and locations over millennial timescales or (b) a single unidentified process acting homogeneously along the western South American margin. With this study, we highlight the application of novel signal analysis approaches to elucidate the mechanisms driving surface deformation in subduction zones on different spatial and temporal scales.

How to cite: Freisleben, R., Jara-Muñoz, J., Melnick, D., Strecker, M., and van der Beek, P.: Tectonic processes responsible for various wavelengths of permanent deformation on the western coast of South America, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11435, https://doi.org/10.5194/egusphere-egu22-11435, 2022.

The Salar de Atacama (SdA) endorheic basin is a low topographic anomaly located in the Central Andes forearc, and it has been suggested as an independent block that subsides with respect to their neighbouring morpho-structures: Cordillera de Domeyko at the west, and the Altiplano and Puna volcanic plateaus to the east. Within the SdA depression, we focus on the Cordillera de la Sal (CdS), a ridge that emerges at its western margin and extends to the northeast for more than 100 km towards the volcanic arc, where the SdA basin closes. The core of the CdS ridge is formed by a fold-and-thrust belt affecting the Oligocene-Miocene continental sedimentary sequences of the San Pedro Formation. Unconformably overlaying this sequence, Upper Miocene-Pliocene tuffs and clastics with varying intensities of deformation are recognised along the northern segment of CdS, where it ends covered by the volcanic arc.

The deformation of CdS and the western border of the SdA have been suggested as a consequence of the inversion of a normal fault that delimits the basin or as an eastward propagation of the thrusting of Cordillera de Domeyko. Moreover, the presence of salt intervals and domes within the San Pedro Formation made some authors propose the existence of halokinesis. In the present work, we aim to investigate the actual tectonic regime of the CdS fold-and-thrust belt. Our objective is to determine spatial and temporal strain variability of CdS to contribute to the understanding of how this mountain belt evolved and how deformation is partitioned at its northern prolongation under the volcanic edifices.

Detailed geological mapping and the construction of seriated cross-sections will allow us to determine variable spatial patterns of deformation affecting the tuff-rich succession, spanning from 9 to 1 Ma. In addition, we will obtain temporal patterns of deformation at the scale of 103 to 105 yr using tectonic geomorphology indicators, such as deformed strath terraces and Holocene salt cave conduits.

Our preliminary results suggest that a compressional tectonic regime is progressively deforming the Upper Miocene-Pleistocene succession of CdS. Moreover, the evolution of drainages from the south-facing slope of the volcanic arc towards the SdA competed with the folds and thrusts, and the major channels developed along thrusts and synclines. This competition is going on also in the Middle to Late Pleistocene as documented by deformed fluvial strath terraces, which we are currently dating with Infra-Red Stimulated Luminescence. The age assessment of deformed terraces and cave conduits will allow us to model the slip rates of the thrust structures at different time scales.

How to cite: Guzmán-Marín, P., Picotti, V., Schmidt, C., and King, G.: Variability of active deformation of the Cordillera de la Sal fold-and-thrust belt, Salar de Atacama, Central Andes, Chile. Preliminary data on deformed fluvial features., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12690, https://doi.org/10.5194/egusphere-egu22-12690, 2022.

The distal Andean foreland basin (Chaco-Pampean Plain) is thought to have been tectonically inactive during the Cenozoic. However, re-interpreted industry seismic reflection data, borehole information and gravity surveys document a rich and complex history of tectonic activity. Our new data synopsis and re-analysis reveals two, regionally extensive and approximately N-S oriented, basement highs beneath the flat present-day surface. The Quirquincho (or Rincón Caburé) and Pampeano-Chaqueño highs have been observed by previous authors, but the mechanism that elevated these features and the timing has remained elusive. Here, we discuss several viable mechanisms of their formation. The morphology, wavelength and stratal terminations suggest that the Quirquincho high could represent a forebulge due to Paleogene orogenic processes. In contrast, the Pampeano Chaqueño high farther east might correspond to a Neogene forebulge, implying forebulge migration. Alternatively, both highs could have been caused by blind and associated with a major crustal detachment. In this case these processes may have been facilitated by vertical mechanical strength contrasts in the foreland crust that have been invoked to drive spatially and temporally disparate thick-skinned deformation during the Andean orogeny. The fact that the arches occur in the vicinity of Cretaceous normal faults and rift basins suggests that these highs could also have been linked with extensional processes; in this case basement uplift and erosion would have been followed by sedimentary processes that finally caused the onlap of the Paleogene strata on the arches. Finally, we also consider the possibility they are Paleozoic, inherited features with posterior reactivation.

How to cite: Cortassa, V., Rossello, E., Back, S., del Papa, C., Ondrak, R., and Strecker, M.: Subsurface basement topography in the Cenozoic Andean foreland basin of northern Argentina: manifestations of long-wavelength deformation vs. inherited structures related to earlier orogeny and extensional processes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13302, https://doi.org/10.5194/egusphere-egu22-13302, 2022.

EGU22-13402 | Presentations | TS10.1

Cenozoic tectonic plate interaction registered in a South Atlantic passive margin basin (southern sector, Pelotas Basin) 

Marlise Colling Cassel, Tiago Jonatan Girelli, João Marcelo Medina Ketzer, and Farid Chemale Jr.

The South Atlantic present-day configuration is the result of remarkable paleogeographic and paleoclimate events that occurred during the Cenozoic. These tectono-climatic events include opening and closing ocean gateways, hyperthermal events, climate changes, and the rise of the Andean Mountain Chain. This work aims to define how these events affected the evolution of the Pelotas Basin in the southern Atlantic Ocean passive margin regarding their sedimentary and geomorphic records. To reach this objective, a multiproxy and multiscale analysis based on subsurface data and regional information using seismic interpretation, backstripping, and numerical modeling was performed to identify the influence of climatic, eustatic, and tectonic triggers. Our results point that the interaction between Naszca, South America, and Antarctic tectonic plates are the root to explain the Cenozoic events registered in the South Atlantic passive margins. The Andean Mountain Chain Uplift on the west side of South America and their retroarc foreland system, the forebulge and back-bulge provinces conducted a strong tectonic control over the Pelotas Basin. On the other hand, the climatic control resulting from the Drake Passage widening and consequent development of the Antarctic Circumpolar Current changed the contour currents dynamics. In response to these tectonic-induced climatic changes, the Pelotas Basin records over the Cenozoic: a) depocenter change, b) alterations in oceanic currents described through contourite deposits, and c) formation of a huge fan-like feature (Rio Grande Fan) during an accelerated increase in the sedimentation rate and consequent gravitational collapse driven by overpressure occurred in undercompacted shales.

How to cite: Colling Cassel, M., Girelli, T. J., Medina Ketzer, J. M., and Chemale Jr., F.: Cenozoic tectonic plate interaction registered in a South Atlantic passive margin basin (southern sector, Pelotas Basin), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13402, https://doi.org/10.5194/egusphere-egu22-13402, 2022.

EGU22-61 | Presentations | TS10.2

Central ages, mono-kinetic, or multi-kinetic? Assessing detrital AFT thermochronology in a Cretaceous foreland basin 

Jennifer Spalding, David Schneider, and Jeremy Powell

Apatite fission track (AFT) thermochronology can resolve thermal histories over a temperature window that spans 50–150°C. Herein, we present a case study from the Peel Plateau, a foreland basin of the Mackenzie Mountains, northern Canadian Cordillera, where we compare three interpretations from a single AFT sample: 1) the central age, and thermal history modelling of 2) a mono-kinetic population and 3) a multi-kinetic population. The AFT sample is derived from a lithic wacke with an Albian depositional age and yields an AFT central age of 67 ± 9 Ma (n: 39). Despite central ages often being interpreted to reflect a sample’s 'cooling age,' laboratory experiments have demonstrated that fission tracks anneal over a wide temperature range, corresponding to the partial annealing zone (PAZ). AFT ages from samples that have undergone multiple burial and exhumation events likely represent partial annealing due to their protracted residence in the PAZ and require thermal history modelling to derive a meaningful geologic interpretation. It is unlikely the Peel Plateau experienced a simple thermal history with rapid cooling through the PAZ, as a regional unconformity separates the Albian and Cenomanian strata across much of the region. Thus, the central age does not necessarily reflect a meaningful thermal event. Thermal modelling the data as a mono-kinetic population predict peak burial temperatures of 118–166°C at 65–92 Ma, however, the sample fails the χ2, indicating it does not comprise a single statistical age population. Intra-sample age dispersion is often indicative of samples that comprise multi-kinetic population and grain specific chemistry is known to strongly influence apatite’s annealing kinetics. Most notably apatite with high F content will undergo thermal annealing at lower temperatures than apatite with high Cl content, although numerous other elements (e.g. OH, Mn, Fe) are known to effect annealing kinetics. The rmro parameter was developed through laboratory annealing experiments, and accounts for compositional controls on apatite’s kinetic behaviour. Apatite grain chemistry was measured via EMPA methods to calculate rmro values and used to separate AFT samples into two kinetic populations (resulting in pooled ages of 36 ± 5 Ma and 103 ± 12 Ma) that both pass the χ2 test. Pooled ages incorporate information of the grains’ pre-depositional history and U-Pb dating can serve as an additional tool to decipher between different kinetic populations. These populations then act as independent thermochronometers capable of resolving different temperature windows. Compared to thermal history model results from mono-kinetic data, the multi-kinetic model predicts significantly lower burial temperatures of 83–93°C, which may have occurred over a longer duration (33–88 Ma). The central age for this sample overlaps with the timing of peak burial predicted by the multi-kinetic model, therefore does not inform us about the cooling history. Ultimately, the purpose of this study is to highlight the importance of assessing multi-kinetic behaviour in sedimentary samples, as these interpretations provide statistically significant age populations and robust thermal history models. Thermal history models that ignore multi-kinetic behaviour may lead to erroneous geologic interpretations.

How to cite: Spalding, J., Schneider, D., and Powell, J.: Central ages, mono-kinetic, or multi-kinetic? Assessing detrital AFT thermochronology in a Cretaceous foreland basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-61, https://doi.org/10.5194/egusphere-egu22-61, 2022.

EGU22-3510 | Presentations | TS10.2

Tectono-thermal evolution of the External Western Alps (France): evidence for rift-related thermal event 

Naïm Célini, Frederic Mouthereau, Abdeltif Lahfid, Claude Gout, and Jean-Paul Callot

Raman Spectroscopy on Carbonaceous Material (RSCM) approach is commonly used to calculate thermal peaks recorded by rocks. A first calibration of the RSCM was developed to measure temperatures ranging from 330°C to 640°C (Beyssac et al., 2002). Its applicability was later expanded to lower temperatures from 200°C to 350°C (Lahfid et al., 2010). Here, we apply the RSCM approach to Digne Nappe area - thrust front of the SW Alps - in order to evaluate the thermal evolution of the sub-Alpine domain from rift to the present. About 150 temperatures have been obtained along seven continuous stratigraphic sections sampled along the strike the whole Digne thrust sheet. The base of the Digne thrust sheet (i.e. the Lias syn-rift carbonates) shows temperatures ranging from 250°C to 330°C. These temperatures are 200-240°C in post-rift marls dated to Callovian-Oxfordian and rapidly drop upsection in the Kimmeridgian-Tithonian carbonates and younger Cretaceous rocks to temperatures below 100-120°C. While these temperatures are seen to decrease from bottom to top we note the lack of well-defined apparent geothermal gradients. One of our section (Serre-Ponçon) structurally positioned beneath the Embrunais-Ubaye thrust sheets is remarkable because the temperatures are rather homogeneous, ranging between 300°C and 350°C along the whole 5km-thick sedimentary pile from the Lias until the Eocene. The regional dataset suggests that the thermal history of the sub-Alpine fold-and-thrust belts varies along-strike and requires the succession of several thermal events. The drop of temperatures observed in the Late Jurassic sediments is interpreted to be related to increasing heat flow during crustal thinning associated to the formation of the Alpine Tethys rifted margin.  The high temperatures observed along the Serre-Ponçon specifically indicate a burial beneath the Embrunais-Ubaye thrust sheets during Alpine orogeny, possibly combined with high geothermal gradients inherited from the Mesozoic Alpine Tethys thinning phase.

How to cite: Célini, N., Mouthereau, F., Lahfid, A., Gout, C., and Callot, J.-P.: Tectono-thermal evolution of the External Western Alps (France): evidence for rift-related thermal event, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3510, https://doi.org/10.5194/egusphere-egu22-3510, 2022.

EGU22-6545 | Presentations | TS10.2

Thermal History of Miocene – Pliocene strata in the Well LKB, Kutei Basin, Indonesia 

Jamaluddin Jamaluddin, Michael Wagreich, and Mostafa Mohamed Sayed

Temperature is the most important parameter in hydrocarbon generation. Well LKB was drilled to test a section in the Sanga Sanga area of the Neogene Kutei Basin in East Kalimantan. The Sanga Sanga Block contains four large to giant hydrocarbon fields in mid- to upper Miocene deltaic sandstones of the Mahakam Delta, Eastern Kalimantan (Indonesia). Well LKB was drilled to a total depth of 2286 m within a Miocene deltaic sequence. Following the measurement of vitrinite reflectance, the samples are scanned in fluorescence and white light modes to obtain sample descriptions. The mean maximum vitrinite reflectance data provide a basis for inferring some aspects of the thermal history of the sedimentary sequence in well LKB. The well intersected with a small portion of the oil mature level. The conventionally defined principal zone of oil generation (oil window) probably lies in the section from about 1066 to 3962 m. The measured maximum formation temperature at 2286 m is 93,9 °C. Assuming a surface temperature of 26 °C, the bottom hole temperature (BHT) corresponds to a geothermal gradient of 34,55 °C/km. Temperature measurements at intermediate levels give a range of geothermal gradients. The highest temperature gradient results from a single mesurement at depth of about 225 m which would indicate a geothermal gradient of 158,1 °C/km. This value is more than three times higher than the gradients obtained from any other measurements downsection. The causes of this extremely high thermal gradient is unknown. Although the presence of faults, overpressured zones, and flux of hot formation water that expelled from deeper parts of the section are possible mechanism, such an extreme geothermal gradient may also be a product of measurement errors that may be related to older reworking and hence it would be more matured. The average geothermal gradient calculated from the other five measurements is more normal by 38,5 °C/km.  Modelling the measured levels of maturation using the logging run temperatures gives maturity levels different from those observed. A compromise model that approximately simulates the observed maturity levels can be obtained by assuming a cover loss of about 914 m of sediments since Pliocene, and geothermal gradients respectively of 38 °C/km and 30 °C/km for pre- and post- Pliocene times, respectively.

How to cite: Jamaluddin, J., Wagreich, M., and Mohamed Sayed, M.: Thermal History of Miocene – Pliocene strata in the Well LKB, Kutei Basin, Indonesia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6545, https://doi.org/10.5194/egusphere-egu22-6545, 2022.

EGU22-7383 | Presentations | TS10.2

The life cycle of a foreland basin: Insights from the Alborz Mountains (Arabia-Eurasia collision zone) 

Paolo Ballato, Daniel F. Stockli, Jamshid Hassanzadeh, Lisa D. Stockli, and Manfred R. Strecker

Flexural foreland basins represent first-order geological archives that preserve the record of orogenic processes. These detrital archives provide critical insights into tectonic, climatic and environmental evolution as well as variations in source lithologies, isostasy, eustasy and dynamic lithospheric processes. In this study, we combine published geological data (e.g., facies analysis, magnetostratigraphy, sediment provenance, and carbon and oxygen isotopic records from authigenic minerals) with new zircon U-Pb geochronologic and zircon and apatite (U-Th)/He thermochronologic data from the southern foreland basin of the Alborz Mountains in northern Iran. This orogen, resulting from the Neogene Arabia-Eurasia collision zone, experienced topographic growth and exhumation since ~20 Ma and foreland deposition of a thick pile (> 7 km) of continental red beds.

The foreland-basin fill consists of three major systematic coarsening-upward cycles that each exhibits fine-grained siliciclastic strata at the base with high sediment accumulation rates and younger detrital zircon U-Pb and (U-Th)/He ages (mostly Eocene), followed by coarse-grained sedimentary strata with decreased sediment accumulation rates and older detrital zircon U-Pb and (U-Th)/He ages (> 100 Ma).

The base of each cycle is interpreted as a pulse of enhanced subsidence driven by tectonic loading associated with the growth of new thrust sheets experiencing erosional unroofing. The top of each cycle is interpreted to reflect wanning tectonic subsidence in response to local intra-basinal uplift (cycle 1) as documented by the sedimentary stratal pattern; uplift of the proximal foreland (cycle 3) as suggested by the age distribution of the detrital zircon U-Pb ages, the shift from fluvial to alluvial fan deposits and recycled apatite (U-Th)/He ages from the deepest exhumed red beds. Within these systematic trends, the top of cycle 2 represents an exception as it appears to record an enhanced phase of sediment supply triggered by wetter climatic conditions as documented by oxygen isotope data from paleosols samples.

Overall, our multidisciplinary approach provides a comprehensive overview of the history of a collisional foreland basin, from the forcing mechanisms controlling its stratigraphic architecture and sedimentary composition to its final incorporation into the orogenic wedge associated with basin uplift and erosion.

How to cite: Ballato, P., Stockli, D. F., Hassanzadeh, J., Stockli, L. D., and Strecker, M. R.: The life cycle of a foreland basin: Insights from the Alborz Mountains (Arabia-Eurasia collision zone), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7383, https://doi.org/10.5194/egusphere-egu22-7383, 2022.

EGU22-8433 | Presentations | TS10.2

Geology, Geochronology and Geoenergy of Sedimentary Basins: Insights from the Midland Valley of Scotland, UK 

Mark Wildman, Cristina Persano, Eamon McKenna, Andrew Hattie, and Alison Monaghan

The Midland Valley Basin of Scotland (MVS) is a major NE-SW trending, fault-bounded sedimentary basin in central Scotland, UK, comprised predominantly of Carboniferous and Devonian sedimentary rocks. Changing palaeo-environments of the MVS produced alternating successions of sandstone, siltstone, mudstone, limestone and coal. The MVS also experienced folding, fault inversion and development of a widespread unconformity during the latest Carboniferous culmination of the Variscan Orogeny and minor tectonic events thereafter. The MVS’ geological resources played a major role in driving Scotland’s economic, industrial, and cultural development in the 19th - 20th. The region was heavily exploited for coal and hydrocarbon energy resources and material for construction, manufacturing, and agriculture. The MVS basin remains as relevant in the 21st century having been identified as a viable source of low-carbon geo-energy resources (e.g., geothermal energy) and potential for subsurface energy storage (Heinemann et al., 2019).

 

While the geology of the MVS has been well-studied, thermal and burial history reconstructions have typically relied on techniques focused on the maturation of organic matter (e.g., vitrinite reflectance, VR), which lack quantitative information on timing. Moreover, tracing sediment provenance can be challenging but crucial for understanding the tectonic evolution of the surrounding source region. Here, we present the results of a geochronological and thermochronological investigation of the MVS basin designed to better understand sediment pathways to the basin from surrounding upland regions and the post-depositional thermal history of the MVS. Our data includes zircon and apatite U-Pb data and apatite fission-track (AFT) data from across the basin and AFT data from a UK Geoenergy Observatories borehole in Glasgow.

 

With our U-Pb data, we identify distant source areas in Greenland, more local source areas in the Scottish Highlands, and recycling of older sedimentary rocks and reworked material in the basin that change through the tectono-magmatic evolution of the basin. Our AFT data and associated thermal history modelling identify three main thermal events: i) Carboniferous-Permian heating; ii) Permian-Mesozoic cooling, and iii) relatively rapid Cenozoic cooling (McKenna, 2021; Hattie, 2021). These are attributed to post-Carboniferous burial followed by post-Permian exhumation. However, ambiguity in some of our models suggests some heating in the Mesozoic may have occurred and, due to the limitations on the temperature sensitivity of the AFT technique, the timing and rate of Cenozoic cooling is poorly resolved. Through our modelling we explore the influence changing palaeo-geothermal gradients has on our thermal history and whether the lower temperature thermochronometer apatite (U-Th)/He can better resolve the most-recent cooling event.

 

Heinemann, N., Alcalde, J., Johnson, G., Roberts, J. J., McCay, A. T., & Booth, M. G. (2019). Low-carbon GeoEnergy resource options in the Midland Valley of Scotland, UK. Scottish Journal of Geology, 55(2), 93-106.

 

McKenna, Eamon (2021) The Provenance and thermal histories of the Carboniferous Midland Valley of Scotland, PhD thesis, University of Glasgow.

 

Hattie, Andrew (2021) Constraining the post-burial history of the central Midland Valley of Scotland using apatite fission track analysis: implications for geothermal energy. MSc(R) thesis, University of Glasgow.

How to cite: Wildman, M., Persano, C., McKenna, E., Hattie, A., and Monaghan, A.: Geology, Geochronology and Geoenergy of Sedimentary Basins: Insights from the Midland Valley of Scotland, UK, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8433, https://doi.org/10.5194/egusphere-egu22-8433, 2022.

EGU22-10007 | Presentations | TS10.2

Development of a Late Jurassic shallow marine system controlled by footwall uplift in the Froan Basin and Frøya High, offshore Mid-Norway 

Lise Nakken, Domenico Chiarella, and Christopher A-L. Jackson

The Froan Basin, located on the proximal platform area on the Mid-Norwegian Continental Shelf, contains petroleum-bearing Upper Jurassic syn-rift deposits. Additional isolated Upper Jurassic shallow marine sand bodies have been identified on the Frøya High, but the platform area remains poorly understood in terms of its Late Jurassic tectono-stratigraphic evolution. Improving our understanding, and in particular how fault activity and rift-shoulder uplift influenced rift physiography and the presence of shallow marine reservoirs, is crucial when assessing hydrocarbon prospectivity. In this study, we present a model for the Late Jurassic rift development of the Froan Basin and Frøya High based on seismic interpretation, well data, and reverse subsidence modelling. We show that during the Late Jurassic to Early Cretaceous, major footwall uplift and exposed the western margin of the Froan Basin and Frøya High formed an intra-rift footwall island. Shallow marine areas to the east, immediately adjacent to the footwall island, accumulated shoreface sediments supplied from the eroded footwall. We therefore suggest that the extent of the Late Jurassic shallow marine system was controlled by the magnitude of footwall uplift and geomorphology of the western margin of the platform area.

How to cite: Nakken, L., Chiarella, D., and Jackson, C. A.-L.: Development of a Late Jurassic shallow marine system controlled by footwall uplift in the Froan Basin and Frøya High, offshore Mid-Norway, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10007, https://doi.org/10.5194/egusphere-egu22-10007, 2022.

EGU22-11175 | Presentations | TS10.2

Alpine tectono-thermal evolution of the North African passive paleo-margin incorporated in the Western Rif belt (Northern Morocco) 

Achraf Atouabat, Sveva corrado, Dominique Frizon de Lamotte, Remi Leprêtre, Geoffroy Mohn, and Andrea Schito

Located in Northern Morocco, the Rif fold and-thrust belt is mainly made by the remnant of the north African paleo-passive margin and its sedimentary infill. We present in this contribution new field observations combined with paleo-thermal analysis to investigate the formation of the Rif orogenic wedge. Three structural domains are recognized from north to south, namely, the Alboran domain assigned to a meso-Mediterranean continental terrane, the Maghrebian flysch domain that corresponds to the sedimentary cover of the Maghrebian Tethys and the External domain (namely Intrarif, Mesorif and Prerif) that belongs to the former north African margin. The Rif fold and-thrust belt suffered an important Cenozoic Alpine compressional deformation starting from the Late Oligocene-Early Miocene, as a consequence of the closure of the Maghrebian Tethys and the westward translation and docking of the Alboran Domain onto the African margin.

To define the evolution and geometry of thrust sheet stacking and their burial-exhumation paths, a NE-SW regional transect crossing the Maghrebian flysch and the External domains is presented and discussed. A set of 32 samples have been collected for paleo-thermal analysis. The methodological approach consists in combining petrography and Raman micro-spectroscopy on dispersed organic matter, X-ray diffraction of clay minerals and 1D thermal modelling with viable cross section reconstruction and field structural survey.

The highest thermal maturity values along the section (1.00 and 1.15 Ro%) are concentrated in the Cretaceous Intrarif sub-domain (Loukkos and Tangier Intrarifain sub-units) that are structurally squeezed between the Maghrebian flysch domain and the Mesorifain sub-domain. The relationship between organic and inorganic paleo-thermal indicators plotted on Hillier diagram show a thermal signature for the Intrarifain sub-domain typical of continental rift thermal regime. The thermal evolution of the Tangier sub-unit, tectonically overlain by the Numidian-like sandstones has been modelled. The model shows a thermal jump between the two juxtaposed rock units indicating an allochthonous origin of the Numidian-like sandstones, probably detached from the Maghrebian Flysch domain. In the Mesorif sub-domain, data plots on Hillier diagram indicate a continental rift heating regime except for the Lower Miocene Zoumi siliciclastics at the top of it, cropping out between Intrarif and Mesorif sub-domains that falls in a very cold thermal regime, typical of synorogenic basins. The structural relationships between the Cenozoic Zoumi basin and its substratum (Upper Jurassic-Lower Eocene) shows an unconformity where the Paleocene-Eocene is missing, probably indicating a pre-Oligocene compressive phase.

These evidences constrain the geological timing of the Rif belt structuration. According to new models, the whole external Rif deformed between the Early Langhian and Late Tortonian with the front of the chain placed at the boundary between Intrarif and Mesorif, where the Zoumi basin developed during the Late Serravallian-Early Tortonian times.

How to cite: Atouabat, A., corrado, S., Frizon de Lamotte, D., Leprêtre, R., Mohn, G., and Schito, A.: Alpine tectono-thermal evolution of the North African passive paleo-margin incorporated in the Western Rif belt (Northern Morocco), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11175, https://doi.org/10.5194/egusphere-egu22-11175, 2022.

Maturity assessment of solid bitumen is significant for the construction of the thermal evolution history of Sinian carbonate reservoirs in the eastern and central Sichuan Basin because of the absence of vitrinite. Occurrence characteristics of solid bitumen in the Sichuan Basin were investigated by petrography observation. Based on Fourier transform infrared (FTIR) spectroscopy and Raman spectroscopy analyses of solid bitumen, the thermal maturity of solid bitumen in the Sinian reservoir was evaluated, and the thermal history of the Sinian reservoirs in the eastern and central Sichuan Basin was further reconstructed. The results show that solid bitumen occurred within intercrystalline pores, intercrystalline dissolution pores, karst caves, fractures, and stylolites in the eastern and central Sichuan Basin. The FTIR spectrums of solid bitumen are characterized by depleted aliphatic carbon and C=O group, and enrichment of aromatic carbon. The FTIR spectrums of solid bitumen indicate that the thermal maturity of solid bitumen in the Sichuan Basin exceeds at least 1.3%. The calculated Ro of solid bitumen in the eastern Sichuan Basin ranges from 3.8 to 4.09%, that of solid bitumen in the central Sichuan Basin ranges from 3.51 to 3.77%, and that of bitumen inclusions in the central Sichuan Basin varies from 3.54 to 3.64% inferred from Raman spectroscopy analysis. The thermal evolution history of Sinian reservoirs in the eastern and central Sichuan Basin can be divided into two heating–cooling stages. At the end of the second heating stage, that is, the Late Cretaceous, the Sinian reservoir reached the highest temperature of 250 °C in the eastern Sichuan Basin and 225 °C in the central Sichuan Basin.

How to cite: Chen, J. and Guo, X.: Maturity assessment of solid bitumen in the Sinian carbonate reservoirs of the eastern and central Sichuan Basin, China: insights from FTIR and Raman spectroscopy analyses, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11719, https://doi.org/10.5194/egusphere-egu22-11719, 2022.

The measurements of soil erosion, sediment transport, and soil deposition due to the tectonic activity regions retard the river basin development. The tectonic activity assessment in this area requires the identification of minimum eroded volume (MEV) and the soil loss (Sl) amount. The MEV, LS, and Hi indices have been used to develop relative tectonic activity Index (RTI) to identify probable zones of Hi, MEV, and SL in the Diyala River Basin (DRB). The results show that the north, north-eastern, and northwestern parts of the (DRB) are situated in the high (RTI) zone. The TIN model is used for estimating the MEV in the DRB and the (RUSLE) model is used for estimating the soil loss in the DRB. The MEV results in the DRB vary from 0 to 845 m3 in some areas. The result of soil loss in the DRB is varied from a minimum value of zero to a maximum of 91.34 t/h/y in some areas. The spatial distribution of MEV and SL in the (DRB) is classified into five types (Low Tectonic Activity, Slight Tectonic Activity, Moderate, High, and Extremely Tectonic Activity). From the results, it was observed that about 25.3% and 24.2% of the total study area are located in the very high relative tectonic activity and low relative tectonic activity zones, respectively. The large percentage of soil loss areas are 28.6% and 26.5% of the total study area are located in the very slight and slight, respectively.

How to cite: Ali, M.: The tectonic  activity assessment using minimum eroded volume and soil loss in Diyala river basin area, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12468, https://doi.org/10.5194/egusphere-egu22-12468, 2022.

EGU22-28 | Presentations | GMPV7.2

Preliminary investigation on PT path of garnet-bearing mafic rocks in the Neoproterozoic Ougda magmatic complex, Tuareg Shield, Algeria 

Chaouki Djallel Eddine Bendimerad, Abderrahmane Bendaoud, Julien Berger, Renaud Caby, and Nachida Abdallah

The mafic-ultramafic Ougda magmatic complex is located in the west part of Tuarge Shield, in Algeria, between Tassendjanet terrane in the east and Ahnet terrane in the west. It is composed of three successive generations of magmatic rocks (Dostal et al., 1996). The first generation located in the north, includes ultramafic rocks cut by dikes of cumulate garnet-bearing mafic rocks and quartz diorite sheets. It records high-temperature metamorphic conditions, granulite facies. The second and third generation located in the south, includes undeformed cumulate and non-cumulate gabbros and intermediate to mafic dikes. The three generations record a geochemical evolution from tholeiitic to calco-alkaline magmatism with subduction-related oceanic environment (Dostal et al., 1996). The age of the first generation is around 800 Ma and the second generation is dated at 680 Ma, considered as the ages of the inception to demise of the oceanic lithosphere (Dostal et al., 1996; Caby and Monié, 2003). Here, we focus on garnet-bearing rocks that show particular interest, as they are affected by high-grade metamorphism in this area. Understanding the pressure-temperature (P-T) evolution of those garnet-bearing rocks allow a crucial constrain of the evolution of the oceanic crust in this area during the Panafrican orogeny.

Petrographical investigation shows that all samples share similar mineralogical assemblages with garnet, plagioclase, amphibole, clinopyroxene, ilmenite and rutile. It is interpreted as typical of granulite facies. Garnet is the most dominate phase and show different textural types: Pokioblastic garnet with inclusions of amphibole, clinopyroxene, plagioclase, ilmenite and rutile. In some samples, garnet is very large (~2 cm), ilmenite is observed in garnet core and rutile appears with ilmenite in garnet rims. Clinopyroxene in garnet is a primary phase as it is surrounded by amphibole, which indicate a reaction with garnet. Garnet corona is around clinopyroxene and plagioclase and both are not in contact with each other. Modeling phase relationship using P-T pseudosections was calculated to constrain the P-T conditions and mineralogical evolution. For garnet growth, modal calculations with observed mineral assemblages are more consistent with a solid-state reaction where clinopyroxene and plagioclase are consumed to produce garnet. The PT path manifest with either cooling at high pressure or pressure increase stage, linked to garnet growth, 14-7 Kbar and 1000-700 °C. The P-T conditions are limited by the appearance of biotite at low temperature, solidus at high temperature and olivine at low pressure. The maximum pressure being recorded by rutile-ilmenite-bearing assemblage. This granulitisation stage is followed by a decompression in subsolidus conditions, amphibolites facies, where amphibole appears either as the product of clinopyroxene transformation or reaction between primary clinopyroxene and garnet through hydration. Lastly, hydration in low grade, greenschist facies, is recorded in garnet- and clinopyroxene-free domains with hydrous phases, chlorite, epidote and amphibole. Hence, P-T evolution recorded in garnet-bearing rocks of Ougda shows an anticlockwise PT path with granulitisation stage showing P-T peak recorded by rutile-ilmenite-bearing assemblage in garnet. Followed by a decompression in amphibolite facies with production of amphibole and ended up with late hydration in geenschist facies.

How to cite: Bendimerad, C. D. E., Bendaoud, A., Berger, J., Caby, R., and Abdallah, N.: Preliminary investigation on PT path of garnet-bearing mafic rocks in the Neoproterozoic Ougda magmatic complex, Tuareg Shield, Algeria, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-28, https://doi.org/10.5194/egusphere-egu22-28, 2022.

EGU22-186 | Presentations | GMPV7.2

Elastic thermobarometry on Zircon-in-Garnet (ZiG) from the Brossasco-Isasca unit (Dora-Maira Massif, Western Alps) 

Giulia Mingardi, Nicola Campomenosi, Mattia Luca Mazzucchelli, Christian Chopin, Marco Scambelluri, and Matteo Alvaro

Here we studied metapelites from the ultrahigh-pressure (UHP) Brossasco-Isasca unit in the Dora-Maira Massif, Western Alps, combining zircon-in-garnet elastic geo-thermobarometry and phase equilibria modelling. We determined the residual strain and pressure of zircon inclusions via micro-Raman spectroscopy and the dedicated softwares available online such as stRAinMAN [1] and EntraPT [2]. The entrapment isomekes obtained for 28 zircon inclusions in garnet from metapelites (Alm67-79-Py9-30-Grs1-6-Sps0-6) were combined with thermodynamic modelling to constrain the P-T range of garnet growth, assuming purely elastic behaviour.

The presence of chloritoid and/or staurolite inclusions at the garnet core-mantle and the presence of coesite inclusions only at the garnet rim suggest that most of the garnet volume formed during an early prograde path and only a small portion under UHP conditions. Most of the selected inclusions, however, come from the rim of the garnet. Since the rim is limpid, we could localize and target those inclusions that are spaced enough to be used reliably for elastic thermobarometry without corrections. The entrapment pressures obtained for most zircon inclusions do not match the previously published results obtained from conventional petrologic methods [3]. For example, combining our results with the available retrograde P-T paths of the UHP unit [3], we bracket the apparent entrapment conditions of zircon inclusions at 0.5 GPa and 600-650 °C, below the expected conditions in the coesite stability field. The same discrepancy between the elastic and chemical barometric methods has been documented for the pyrope-bearing whiteschists from the same metamorphic unit [4]. The observed misfit has been tentatively attributed to post-entrapment viscous relaxation of the garnet–zircon inclusion system, which cannot be accounted for by purely elastic models. These results provide further evidence of a general post-entrapment elastic resetting of the zircon-in-garnet pairs along the retrograde path at temperatures near 600-650°C.

This work was supported by ERC-StG TRUE DEPTHS (grant number 714936) to Matteo Alvaro. Nicola Campomenosi and Mattia L. Mazzucchelli are supported by the SIMP PhD Thesis Award and by the Alexander von Humboldt research fellowship. [1] Angel et al. (2019) Zeitschrift für Kristallographie, 234, 219. [2] Mazzucchelli et al. (2021) American Mineralogist, 106, 830. [3] Groppo et al. (2019) European Journal of Mineralogy, 31, 665. [4] Campomenosi et al. (2021) Contrib Mineral Petrol 176, 36.

How to cite: Mingardi, G., Campomenosi, N., Mazzucchelli, M. L., Chopin, C., Scambelluri, M., and Alvaro, M.: Elastic thermobarometry on Zircon-in-Garnet (ZiG) from the Brossasco-Isasca unit (Dora-Maira Massif, Western Alps), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-186, https://doi.org/10.5194/egusphere-egu22-186, 2022.

EGU22-1633 | Presentations | GMPV7.2

Graphite in granulite - characterization, origin, role of fluids and consequences for rheology 

Ane K. Engvik, Håvard Gautneb, Pål Tore Mørkved, Janja Knezevic, Muriel Erambert, and Håkon Austrheim

In a combined geological, petrological and isotopic study from the Lofoten-Vesterålen Complex, Norway, graphite is documented formed in the deep Proterozoic crust. Graphite schist is hosted in sequences of banded gneisses dominated by orthopyroxene-bearing quartzofeldspatic gneiss, interlayered with horizons of marble, calcsilicates and amphibolite. The schist displays a strong foliation and has a major content of graphite up to a modality of 39%. Quartz and plagioclase (Ab47-93An5-52), pyroxenes, biotite (Mg# = 0.67-0.91; Ti < 0.66 a.p.f.u.), and K-feldspar (Ab1-8Kfs92-99) or perthite (Ab35-64An3Kfs50-62) are additional major phases. Pyroxene is present either as orthopyroxene (En69-74Fs26-29; Mg#=0.70-0.74), as clinopyroxene (En33-53Fs1-14Wo44-53; Mg#=0.70-0.97), or both. Pseudosection modeling of the plagioclase + orthopyroxene (Mg#-ratio = 0.74) + biotite + quartz + rutile + ilmenite + graphite-assemblage constrains its stability field to pressure-temperature conditions of 810-835 °C and 0.73-0.77 GPa. Zr-in-rutile also supports a temperature of formation of 740-870°C.

Stable isotopic δ13C in graphite schist shows values from -38 to -17‰ while δ13C values of marbles range from +3‰ to +10‰. Mixed graphitic and calcite carbon samples give lighter values for the calcite (δ13Ccalcite = -8.65‰ to -9.52‰) and heavier values for graphite (δ13Cgrapite = -11.50‰ to -8.88‰) compared to the “pure” samples. δ18O for marble shows relatively light values for calcite ranging from -15.44‰ to -7.53‰ reflecting metamorphic and hydrothermal processes. From the stable C-isotopes we interpret the graphite origin as organic carbon accumulated in sediments contemporaneous with the Early Proterozoic global Lomagundi-Jatuli isotopic excursion.

From petrography and mineral composition, we deduce the reaction equations producing and consuming H2O- and CO2-fluids leading to the stabilisation of graphite and orthopyroxene. The high Mg#-ratio of biotite and pyroxenes is an indication of metasomatism, and together with a high Cl-content of apatite up to 2 a.p.f.u. show the importance of fluids during the high-grade formation of graphite.

The enrichment of graphite resulted in zones with strong schistosity and a sharp strain gradient towards host massive granulite gneiss; High-ordered graphite occurs as euhedral “flakes” (i.e., flake graphite) of fine- to medium grain size, with a strong preferred crystal orientation forming the well-developed foliation together with the crystal preferred orientation of biotite. The presence of graphite reduces crustal strength and causes strain localisation in the granulite facies crust.

How to cite: Engvik, A. K., Gautneb, H., Mørkved, P. T., Knezevic, J., Erambert, M., and Austrheim, H.: Graphite in granulite - characterization, origin, role of fluids and consequences for rheology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1633, https://doi.org/10.5194/egusphere-egu22-1633, 2022.

EGU22-3348 | Presentations | GMPV7.2

Duration of anatexis in a Neoproterozoic-Cambrian UHT terrane: constraints from prograde melt inclusions in zircon 

Kota Suzuki, Tetsuo Kawakami, and Shuhei Sakata

The duration of anatexis in high-grade metamorphism is essential to understand the crustal melting processes and the tectonic settings. In the case of Rundvågshetta, Lützow-Holm Complex, East Antarctica, the linkage between the U-Pb zircon ages and the metamorphic pressure-temperature (P-T) evolution is still unclear. Only the melt crystallization age of ca. 520 Ma is constrained. In this study, we aim to constrain the duration of anatexis by using petrochronological approaches to an ultrahigh-temperature (UHT) granulite sample from Rundvågshetta.

Garnet in the studied sample consists of the P-poor core, P-rich mantle and P-poor rim. Based on the detailed petrography of inclusion minerals in garnet, we interpret that the garnet core was formed as a peritectic product of biotite dehydration melting during prograde metamorphism, and that the garnet mantle and rim were formed in the peak and retrograde stages, respectively, in a clockwise P-T evolution.

Zircon in the rock matrix shows four microstructural domains; oscillatory-zoned inherited core, dark-CL annulus, slightly bright-CL inner rim and bright-CL outer rim. The inner rim was too thin for the LA-ICP-MS U-Pb zircon dating with 20 µm spot size. The inherited cores are always truncated by the dark-annulus with low Th/U ratios below 0.04. The dark-annulus includes muscovite, biotite, rutile, quartz and melt inclusions and yielded weighted mean age of 564.0 ± 4.9 Ma (2σ error, n = 4, MSWD = 1.8). The dark-annulus is further truncated by the outer rim with higher Th/U ratios (0.08-1.13). The outer rim includes sillimanite, K-feldspar and rutile and yielded weighted mean age of 530.5 ± 4.9 Ma (2σ error, n = 13, MSWD = 1.5).

The microstructures of inclusion zircon vary systematically with the phosphorus zoning of the host garnet. Zircon in the garnet rim show four microstructural domains that are common to the matrix zircon. Meanwhile, zircon in the garnet core always lacks the inner and outer rims. The dark-annulus and outer rim of zircon respectively showed steeply positive-sloping and negative-sloping heavy rare earth elements (HREE) patterns. Meanwhile, the garnet core, mantle and rim showed positive, flat and negative HREE patterns, respectively. Based on these systematic microstructures of inclusion zircon and on the partitioning of HREE between zircon and garnet, it is revealed that the outer rim of zircon grew simultaneously with the garnet rim during the retrograde metamorphism, and that the dark-annulus of zircon grew prior to the garnet core during the prograde metamorphism.

Inclusion minerals in the dark-annulus of zircon suggest the possible occurrence of muscovite dehydration melting at ca. 560 Ma. Therefore, microstructural observations of zircon enabled us to deduce the prograde anatexis prior to the attainment of UHT condition that is not recorded in garnet. Taking the melt crystallization age of ca. 520 Ma into account, the duration of anatexis in Rundvågshetta is constrained to be at least ~40 Myr. Further U-Pb dating of the thin inner rim of zircon may reveal the duration of the UHT itself precisely.

How to cite: Suzuki, K., Kawakami, T., and Sakata, S.: Duration of anatexis in a Neoproterozoic-Cambrian UHT terrane: constraints from prograde melt inclusions in zircon, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3348, https://doi.org/10.5194/egusphere-egu22-3348, 2022.

EGU22-4832 | Presentations | GMPV7.2

Lu-Hf dating of Jurassic eclogites of the Zagros hinterland, Iran: Implications for the timing of Neotethyan subduction initiation 

Rezvaneh Jamaliashtiani, Erik Scherer, Axel K. Schmitt, and Jamshid Hassanzadeh

The Sanandaj-Sirjan zone (SaSZ) on the northern edge of the Arabia-Eurasia suture in Iran includes a significant high-pressure (HP) metamorphic suite exposed along the upper Zayanderud River north of Shahrekord. Phengitic micas from eclogite in the Zayanderud metamorphic complex (ZMC) yielded 40Ar/39Ar dates ranging from 184 to 173 Ma [1], whereas zircon from an associated anatectic pegmatite gave an average U-Pb age of 176 ± 3 Ma [2]. These data are consistent with a subduction channel metamorphism and rapid exhumation during the Early to Middle Jurassic. To constrain the timing of high-pressure conditions, we have conducted Lu-Hf mineral-whole rock dating on two eclogite samples. The resulting garnet-controlled isochron dates of 171.4 ± 0.4 (MSWD = 1.2) and 175 ± 1 (MSWD = 0.43) Ma have important geodynamic implications as the Jurassic initiation of the Neotethyan subduction in Iran has recently been disputed [3][4]. The metamorphic ages of the ZMC eclogite now leave no doubt that subduction was ongoing along the SaSZ peri-Tethyan margin during the Middle Jurassic.

[1] Davoudian et al., 2016 Gondwana Research 37: 216-240; [2] Jamali Ashtiani et al., 2020 Gondwana Research 82: 354-366; [3] Azizi & Stern, 2019 Terra Nova 31: 415-423; [4] Lechmann et al., 2018 Contrib. Mineral. Petrol. 173 (12): 102

How to cite: Jamaliashtiani, R., Scherer, E., K. Schmitt, A., and Hassanzadeh, J.: Lu-Hf dating of Jurassic eclogites of the Zagros hinterland, Iran: Implications for the timing of Neotethyan subduction initiation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4832, https://doi.org/10.5194/egusphere-egu22-4832, 2022.

EGU22-6127 | Presentations | GMPV7.2

Using P-T-t estimates to identify and restore out-of-sequence thrusting in the lower part of the Kalak Nappe Complex (Nordkinnhalvøya, Sværholthalvøya), internal Scandinavian Caledonides, Finnmark, N. Norway 

A. Hugh N. Rice, Fred Gaidies, Olivier K. A. Heldwein, M. Thereza A. G. Yogi, Jamie A. Cutts, and Matthjis A. Smit

The tectonometamorphic evolution of the Kalak Nappe Complex in the northernmost Scandinavian Caledonides is currently uncertain; at least two pre-Caledonian events have been locally recognised within the complex, as well as Caledonian events. To help clarify the evolution of the complex, we document here the P-T-t paths of garnet growth, which represent the peak metamorphic conditions within this relatively unstudied external part of the complex.

Metamorphic P-T paths for the lower part of the Kalak Nappe Complex were obtained using the THERIA_G model of Gaidies et al. (CMP 2008). In the model, equilibrium in the MnNCKFMASHT system was established across the entire rock-volume during prograde metamorphism, except for garnet, which developed growth zoning preserved at levels controlled by the kinetics of intracrystalline diffusion. The mass and composition of material used in successive increments of garnet growth is cumulatively subtracted from the matrix bulk-rock composition before calculating the P-T conditions of the next increment of garnet growth.

There is some latitude with regards to the absolute metamorphic conditions determined using this model, due to the inherent uncertainty of the thermodynamic data and the approximation of the reactive volume composition. However, the slopes of the determined P-T paths, together with lithological, geochemical and Lu-Hf garnet whole-rock isotopic data and garnet crystal size frequency distributions, enabled the identification of three nappes in the study area; from lowest upwards, the Bekkarfjord, Veidnes and Kolvik nappes.

An early, low-pressure Barrovian-type metamorphic event at ∼464 Ma is preserved in the Veidnes Nappe, where garnet cores (Grt 1V) give a P-T gradient of ∼15 bar/°C, with peak conditions of ∼560 °C and 4.5 kbar. That was followed by moderate-pressure metamorphism in the Bekkarfjord Nappe at ∼423 Ma, resulting in garnet crystallization (Grt 1B, core growth) along a gradient of ∼20 bar/°C, with peak conditions of ∼570 °C and 6.0 kbar. All three nappes then experienced Barrovian-type metamorphism at ∼420 Ma on a steep P-T gradient of ∼40 bar/°C, with peak conditions of ∼560 °C and 6.7 kbar in the Bekkarfjord and Veidnes nappes (Grt 2B, V, rim growth), while the overlying Kolvik Nappe was metamorphosed at peak conditions of ∼590 °C and 7.5 kbar (Grt 1K, core growth). We consider the latter two episodes (423, 420 Ma) to be different stages of the Scandian phase of the Caledonian Orogeny.

The juxtaposition of the three nappes, with the youngest event having occurred in the structurally highest unit and the oldest event now being sandwiched between the two younger events indicates out-of-sequence thrusting associated with the final continent-continent collision. This has been modeled in “balanced” cross-sections of the ductile thrusting.

How to cite: Rice, A. H. N., Gaidies, F., Heldwein, O. K. A., Yogi, M. T. A. G., Cutts, J. A., and Smit, M. A.: Using P-T-t estimates to identify and restore out-of-sequence thrusting in the lower part of the Kalak Nappe Complex (Nordkinnhalvøya, Sværholthalvøya), internal Scandinavian Caledonides, Finnmark, N. Norway, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6127, https://doi.org/10.5194/egusphere-egu22-6127, 2022.

EGU22-6214 | Presentations | GMPV7.2

Petrology, geochemistry, and petrogenesis of calcic-ferroan-metaluminous garnetiferous magmatic charnockites from eastern Chhotanagpur Gneissic Complex, Eastern Indian Craton 

Bapi Goswami, Susmita Das, Ankita Basak, Chittaranjan Bhattacharyya, and Chandreyee Goswami

We report calcic-ferroan-metaluminous garnetiferous magmatic charnockites that are extremely rare in nature and hence interesting to study. The garnetiferous porphyritic granite pluton of the Tilaboni area of Chhotanagpur Gneissic Complex of Eastern Indian shield contains older enclaves of enderbite-charnoenderbite-charnockite (charnockitic suite). Garnetiferous metagabbro are spatially associated with charnockitic rocks. Plagioclase, K-feldspar, quartz, ortho-, and clinopyroxene, garnet, biotite ± amphibole, ilmenite ± magnetite are major mafic phases. Biotite is sub-alkaline to alkaline. Plagioclase compositions vary from andesine to oligoclase. Garnet is rich in almandine (70.28–74.04 mol%) and grossular (17.77–21.41 mol%) but contains low pyrope (2.83–7.67 mol%) and spessartine (4.09–4.59 mol%). Amphibole formed through the hydration of hypersthene, clinopyroxene, and garnet.

Garnet-clinopyroxene and orthopyroxene-clinopyroxene geothermometry and garnet-orthopyroxene-plagioclase-quartz geobarometry give granulite-facies (750-850°C; 7.5-8.0 kb) of metamorphism of the charnockitic rocks. Amphibole-plagioclase thermobarometry yields temperature and pressure (733−795 °C; 5−6 kbar) that suggest amphibolization of the mafic minerals at a relatively shallower level. Pseudosection modeling shows that the garnets and orthopyroxene finally equilibrated at around 560°C temperature and 5.8 kb.

Primary ilmenite and high Fe/(Fe+Mg) ratios of amphibole-biotite indicate these charnockites metamorphosed under reduced conditions (ΔNNO −2).

These charnockites are dominantly calcic and ferroan to slightly magnesian (Fe-number: 0.74–0.97); dominantly metaluminous to weakly peraluminous (A/CNK: 0.84–1.08); high- and medium-K calc-alkaline and shoshonite series.

These exhibit moderate variations of Al2O3 (12.44–18.19 wt.%), K2O (1.16–5.7 wt.%), and CaO (1.01–5.72 wt.%) contents. Na2O (3.71–3.89 wt.%) show a slight variation in concentration. Abundances of Fe2O3(total) (2.45–7.88 wt.%) and TiO2 (0.21–1.11 wt.%) are generally moderate, whereas the concentration of MgO (0.08–1.99 wt.%) remains low.

These rocks show enrichments of the Rb, Ba, Th, K, Zr, and Hf but depletion in Nb, Ta, and Ti relative to the primitive-mantle composition. They also show strong depletions in Sr and P, whereas enrichment in Pb. LaN/SmN (2.68–12.95) and GdN/YbN ratios (1.57–2.89) of these rocks are high. Five of the six samples show negative Eu-anomalies (0.29–0.91), one sample shows pronounced positive Eu-anomaly (3.09).

These rocks exhibit similar multicationic trace-element and REE patterns and a nearly collinear array of sample plots in Harker diagrams. Further, these samples follow a calcic to alkali-calcic trend in SiO2 vs. MALI diagram. These factors are the result of magmatic differentiation. Decreases in CaO and Fe2O3t with increasing SiO2 but increasing agpaitic index with increasing silica alkalis are due to fractional crystallization from a common parental magma. Decreasing modal plagioclase following the calc-alkaline trend also supports magma differentiation. High Nb/U (av. 22.48) and Ce/Pb (av. 12.64) ratios but low Th/U (average 7.76) ratios suggest mantle source of the magma parental to these charnockites.

Their ferroan and reduced characters resulted from intense fractionation of early-formed allanite, magnetite, etc. Geochemical modeling shows the calcic charnockites evolved by fractionation of garnet and clinopyroxene from basaltic magma derived from a depleted mantle.

How to cite: Goswami, B., Das, S., Basak, A., Bhattacharyya, C., and Goswami, C.: Petrology, geochemistry, and petrogenesis of calcic-ferroan-metaluminous garnetiferous magmatic charnockites from eastern Chhotanagpur Gneissic Complex, Eastern Indian Craton, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6214, https://doi.org/10.5194/egusphere-egu22-6214, 2022.

EGU22-6405 | Presentations | GMPV7.2

Detrital garnet Lu-Hf and U-Pb geochronometry coupled with compositional analysis: Possibilities and limitations as a sediment provenance indicator 

Chris Mark, Laura Stutenbecker, Sergio Andò, Marta Barbarano, Gary O'Sullivan, Stijn Glorie, Alexander Simpson, and J. Stephen Daly

Detrital geochronology is a powerful tool to interrogate the sedimentary archive of (paleo-)hinterland tectonic, metamorphic, and climatic processes, and can also be applied to modern river sediment as a first-pass tool to establish regional bedrock ages. The popular zircon U-Pb detrital geochronometer has seen widespread adoption for these tasks (3,626/4,471 results for the search term detrital geochronology also contain the term zircon U-Pb; Clarivate Analytics Web of Science). However, zircon fertility is strongly biased to intermediate to felsic source rocks. Moreover, zircon crystallization is volumetrically limited in metamorphic terranes which do not achieve anataxis (e.g., Moecher & Samson, 2006), and is typically restricted to rim overgrowths which are vulnerable to mechanical destruction during fluvial transport, and which are challenging to detect and analyse (e.g., Campbell et al., 2005).

Therefore, it is desirable to develop complementary provenance tools for metamorphic settings. Garnet group minerals are rock-forming in several common metamorphic lithologies, and garnet is therefore a common constituent of clastic detritus from orogens. Moreover, single-grain in-situ dating of garnet by LA-ICPMS is possible using the U-Pb (e.g., Seman et al., 2017) and, by use of an online reaction cell, the Lu-Hf radioisotope systems (Simpson et al., 2021).    

Here, we present results from U-Pb and Lu-Hf double-dating, acquired by LA-ICPMS for detrital garnet recovered from the Oligo-Miocene pro-foreland basin of the European Alps, as well as modern Alpine river sediment. We integrate these data with compositional data acquired by Raman spectroscopy, and energy and wavelength-dispersive X-ray spectroscopy (Stutenbecker et al., 2019). We discuss the implications for Alpine tectonics and metamorphism, and future scope of detrital garnet geochronometry.   

Campbell, I., et al., 2005. Earth Planet. Sci. Lett. 237, 402-432,  doi: 10.1016/j.epsl.2005.06.043

Moecher, D., & Samson, S., 2006, Earth Planet. Sci. Lett. 247, 252–266, doi: 10.1016/j.epsl.2006.04.035

Seman, S., et al., 2017. Chem. Geol. 460, 106–116. doi: 10.1016/j.chemgeo.2017.04.020

Simpson, A., et al., 2021. Chem. Geol. 577, 120299. doi: 10.1016/j.chemgeo.2021.120299

Stutenbecker, L., et al., 2019, Solid Earth 10, 1581–1595, doi: 10.5194/se-10-1581-2019

How to cite: Mark, C., Stutenbecker, L., Andò, S., Barbarano, M., O'Sullivan, G., Glorie, S., Simpson, A., and Daly, J. S.: Detrital garnet Lu-Hf and U-Pb geochronometry coupled with compositional analysis: Possibilities and limitations as a sediment provenance indicator, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6405, https://doi.org/10.5194/egusphere-egu22-6405, 2022.

EGU22-6734 | Presentations | GMPV7.2

Deciphering Neoarchean polymetamorphism and crustal melting in the northern Wyoming Province using garnet petrochronology 

Besim Dragovic, Victor Guevara, Mark Caddick, Jeremy Inglis, Tom Raimondo, and Andrew Kylander-Clark

High-grade metamorphic rocks can record the dynamic processes that lead to crustal heating and a departure from normal crustal geothermal gradients. High temperatures in the Archean crust led to particularly significant melt generation and cratonic stabilization, and understanding the depths, temperatures and rates of Archean metamorphism may reflect our clearest window into possible tectonic styles at this time. However, several Archean metamorphic terranes record polymetamorphism, and unravelling the pressure-temperature-time (P-T-t) histories of such terranes has proven difficult, with complexity inherent in both chronologic and petrologic data.

Here we synthesize results of a multi-analytical study in which garnet and monazite petrochronology, coupled with thermodynamic and diffusion modeling, were applied to Archean granulites from the Beartooth Mountains in the northern Wyoming Province, U.S.A. The data reveal two phases of garnet growth and high-temperature metamorphism. Garnet cores grew coeval with emplacement of a granitoid batholith at ~2.78-2.76 Ga. This was followed by a distinct, second phase of peritectic garnet rim growth at ~2.71 Ga, during biotite breakdown melting at peak temperatures of ~750˚C. Diffusion modeling of chemical zoning in garnet rims shows that this second event was brief: near-peak temperatures were maintained for < 1 Myrs. In contrast, core and rim dates of garnet from a meta-granitoid from the same outcrop record only the initial phase of growth, most likely because a lack of grain boundary fluids inhibited further crystallization in these rocks. Evidence for this second event is cryptic in other granitoid samples, such that this period of heating to at least 750˚C, ~50-100 Myrs after initial batholith emplacement, is poorly recorded in the broader rock record of the Beartooths.

The results of our study show that different parts of the metamorphic history of a rock may be recorded differently between garnet and accessory phases. Lastly, while field and petrologic evidence for polymetamorphism may be cryptic, direct dating of distinct garnet growth zones with preserved major and trace element zonation allows for a clear interpretation between isotopic dates and the metamorphic history of the rock.

How to cite: Dragovic, B., Guevara, V., Caddick, M., Inglis, J., Raimondo, T., and Kylander-Clark, A.: Deciphering Neoarchean polymetamorphism and crustal melting in the northern Wyoming Province using garnet petrochronology, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6734, https://doi.org/10.5194/egusphere-egu22-6734, 2022.

EGU22-7532 | Presentations | GMPV7.2

Repeated metamorphism and deformation localized in a shear zone recording the formation-subduction-exhumation history of the continental crust 

Sascha Zertani, Luca Menegon, Giorgio Pennacchioni, Fernando Corfu, and Bjørn Jamtveit

A prominent natural laboratory to deduce the interplay of seismic and aseismic deformation in the lower continental crust is exposed on the Lofoten archipelago (northern Norway). A key feature to unravel its tectonic history is the ~600 m thick Ramberg-Flakstad shear zone (RFS) that is interpreted as a retrogressed eclogite-facies shear zone. However, the rest of the lower crustal section preserves evidence of cyclicity between seismic rupture (pseudotachylytes) and viscous shear at amphibolite-facies conditions, while the record of high-pressure deformation and metamorphism is less clearly preserved. The RFS is thus a key structure to understand the subduction-exhumation history of the Lofoten crustal section, providing insight into the localization of metamorphism and strain during orogenesis. Here we report field observations combined with mineral chemical, microstructural, and textural observations of this long-lived multistage shear zone. The shear zone is heterogeneous with the main foliation wrapping around weakly to non-foliated blocks. These blocks are dissected by millimeter to centimeter-thick shear zones. The RFS is hosted by Paleoproterozoic gabbroic rocks that were intruded by anorthositic and charnockitic plutons at ~1.8 Ga. Granulite-facies metamorphism, indicated by the crystallization of garnet, recrystallization of orthopyroxene, and a locally preserved migmatitic fabric is likely related to pluton emplacement. Later eclogite-facies metamorphism (age disputed) is evidenced by inclusions of omphacitic clinopyroxene in garnet and clinopyroxene + plagioclase symplectites after omphacite within the main foliation. Inclusion distributions in garnet are patchy and electron backscatter diffraction (EBSD) analysis reveals that individual garnet grains can be divided into multiple domains, indicating various growth phases. The main foliation is dominantly formed by the preferred orientation of amphibole and plagioclase, consistent with amphibolite-facies P-T conditions reported from shear zones and pseudotachylytes elsewhere in Lofoten. The symplectites after omphacite are aligned with this main foliation but internally preserve a vermicular microstructure indicating that retrogression actually occurred statically after alignment. Additionally, plagioclase within the symplectites is more albitic than in the matrix, precluding that significant element redistribution occurred during or after retrogression. Lastly, the main fabric is crosscut by undeformed (to locally weakly folded) pegmatite dykes of Caledonian age which provides a lower age boundary on RFS deformation at ~413 Ma. These observations indicate that the RFS is long-lived (~1.4 Ga), established during Proterozoic granulite-facies metamorphism and repeatedly exploited as a site of metamorphism at varying P-T conditions, hydration/dehydration reactions, and deformation. Key minerals and mineral assemblages reveal these modifications through a history of stable lower continental crust, subduction, and exhumation.

How to cite: Zertani, S., Menegon, L., Pennacchioni, G., Corfu, F., and Jamtveit, B.: Repeated metamorphism and deformation localized in a shear zone recording the formation-subduction-exhumation history of the continental crust, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7532, https://doi.org/10.5194/egusphere-egu22-7532, 2022.

EGU22-7573 | Presentations | GMPV7.2

Decompression of host-inclusion systems in UHP rocks: insights from observations and models 

Cindy Luisier, Thibault Duretz, Philippe Yamato, and Julien Marquardt

Polymorphic transformations are key tracers of metamorphic processes, also used to estimate the pressure and temperature conditions reached by a rock. In particular, the quartz-coesite transition is commonly used to define the lower boundary of the ultrahigh-pressure (UHP) metamorphic field. The partial preservation of coesite included in garnets from UHP rocks bring considerable insights into the burial and exhumation mechanisms of the continental crust involved in convergent zone. Coesite was first described in the Western Alps by Chopin[1], in the Dora-Maria whiteschist, one of the most emblematic UHP rock worldwide. Although the partial preservation of coesite inclusions in garnet has long been attributed to the pressure vessel effect, the interrelationship and relative timing between fracturing and retrogression is still contentious.

Here we study the reaction-deformation relationships of coesite inclusions initially enclosed in garnet and transforming into quartz during the decompression process. We combine 2D numerical thermo-mechanical models constrained by pressure-temperature-time (P-T-t) estimates from the Dora-Maira whiteschist. The model accounts for a compressible visco-elasto-plastic rheology including a pressure-density relationship of silica based on thermodynamic data. This allows us to study the effect of reaction-induced volume increase during decompression. Our results capture the typical fracture patterns of the host garnet radiating from retrogressed coesite inclusions and can be used to study the relative role of volume change associated with a change of P-T conditions on the style of deformation during decompression.

The mechanisms of the coesite-quartz transformation and geodynamic implications are presented and validated against geological data. The effect of fluids on the phase transition and the conditions of access of fluids during the transformation are discussed in the light of the results of the thermo-mechanical models.

This study demonstrates the high potential of thermo-mechanical modelling in enhancing our understanding of the processes involved in the formation and evolution of metamorphic minerals.

 

[1]Chopin (1984) Contributions to Mineralogy and Petrology 86, 2, 107-118

How to cite: Luisier, C., Duretz, T., Yamato, P., and Marquardt, J.: Decompression of host-inclusion systems in UHP rocks: insights from observations and models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7573, https://doi.org/10.5194/egusphere-egu22-7573, 2022.

The Woodroffe Thrust (WT) in the Musgrave Ranges (central Australia) is a shallowly south-dipping crustal-scale mylonitic zone extending E-W for over 600 km. The WT, developed during the intracontinental Petermann Orogeny (630-520 Ma), placed hanging wall lower-crustal granulite to upper-amphibolite facies rocks of the Fregon Subdomain (FS) over footwall amphibolite-facies mid-crustal gneisses and granitoids of the Mulga Park Subdomain (MPS). The WT mylonites largely affect the MPS and to a minor extent the FS. Towards the WT, the hanging wall hosts the largest volumes of supposedly deep-seated, tectonic pseudotachylytes (pst) worldwide, also partially involved in mylonitization adjacent to the WT. The WT has been inferred to have only a very small difference in pressure (depth) over the ca. 60 km of N-S exposure along the transport direction, from 1.0 – 1.3 GPa to 0.8 – 1.1 GPa, thus representing effectively a very shallowly dipping structure[1]. However, it was noted that these pressure estimates had to be considered with some caution due to not always ideal mineral compositions. Here we present new pressure constraints in northern outcrops from the eastern segment of the thrust suggesting a more complex geometry than previously inferred, with significant variation in depth along the structure.

Pseudotachylyte-bearing peraluminous gneisses, from two localities ca. 80 km apart (Sentinel Bore, SB, to the east and Kelly Hills, KH, to the west) in the immediate hanging wall of the WT, were investigated to establish the ambient conditions during seismic faulting. The gneisses display mm-thick alternation of quartz-feldspar and cordierite-sillimanite-rich layers, including sparse garnet, magnetite, ilmenite, and biotite. Along microfractures of the pst damage zone (i) sillimanite was fractured and remained unaltered; (ii) cordierite broke down to either an andalusite + quartz + biotite symplectite overgrown by kyanite (SB), or just kyanite (KH); and (iii) K-feldspar developed flame perthites. The pst at SB and KH also show a different mineralogy. At SB, pst assemblages include (i) andalusite (pseudomorphosed by biotite) + quartz intergrowths rimmed by plagioclase and K-feldspar; (ii) sillimanite microlites overgrowing sillimanite clasts; (iii) microlitic kyanite, and (iv) poikilitic garnet as the latest grown phase. At KH, pst assemblages include (i) cordierite + quartz intergrowths; (ii) sillimanite microlites overgrowing sillimanite; (iii) microlites of kyanite, and (iv) poikilitic garnet. Andalusite is absent at KH.

The newly identified andalusite, stable in pst, sheared pst and along microfractures in the host rock at SB indicates pressures ≤ 0.5 GPa during seismic faulting, i.e. significantly lower than in the more southern portion close to Mount Woodroffe (ca. 60 km to the SW of SB)[2]. The absence of andalusite at KH implies a complex undulating geometry for the WT.

 

 

1: Wex et al., 2017, Geometry of a large‐scale, low‐angle, midcrustal thrust (Woodroffe Thrust, central Australia). Tectonics36(11), 2447-2476.

2: Hawemann et al., 2018, Pseudotachylytes as field evidence for lower-crustal earthquakes during the intracontinental Petermann Orogeny (Musgrave Block, Central Australia). Solid Earth, 9, 629-648

How to cite: Toffol, G., Pennacchioni, G., Camacho, A., and Mancktelow, N.: Geometric complexity of the Woodroffe Thrust (Musgrave Ranges, central Australia) recorded in hanging wall Al-silicate-bearing peraluminous gneisses and hosted pseudotachylytes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8678, https://doi.org/10.5194/egusphere-egu22-8678, 2022.

EGU22-8700 | Presentations | GMPV7.2

A new compositional estimate for refractory lower continental crust 

Robert Emo, Balz Kamber, Hilary Downes, and John Caulfield

Compared to the well-studied upper continental crust, the composition of the lower crust is much more poorly constrained. Geophysical constraints and geochemical data from granulite xenoliths indicate that the lower crust is, on average, mafic and depleted in most incompatible elements, including the heat-producing elements (HPE). However, the extent of this depletion is not well known. The large uncertainties associated with lower crustal estimates have important implications for the Earth’s evolution, as the lower crust is often proposed to be a “hidden reservoir” (e.g., for unradiogenic Pb) needed to close mass balance discrepancies for the Bulk Silicate Earth.

In this study, we analysed granulite xenoliths from Queensland, eastern Australia, and the Kola Peninsula, northwest Russia, using a reconstitution approach that corrects for host magma contamination. This method also provides detailed insight into which minerals control elemental distribution and concentrations of the xenoliths. The major element compositions of both suites of granulite xenoliths highlight their mafic nature, with SiO2 contents similar to previously published estimates. However, the concentrations of the most incompatible elements, including the large ion lithophile elements (LILE) and HPE, are very low. Some elements are more depleted by an order of magnitude than the most popular composites used in the literature. Zircon and monazite are rare in these mafic granulites, while apatite and rutile have relatively low Th and U concentrations. The absence of hydrous silicates (e.g., mica and amphibole) and the relatively high anorthite contents of feldspar in the xenoliths is a controlling factor in the low LILE concentrations, particularly for Rb and Cs. If this composition is representative of typical lower continental crust, then such highly refractory compositions limit the ability of the lower crust to act as a significant contributor for planetary mass balance considerations because it does not contain enough Pb, Nb, Ta, Cs and Rb to balance other inventories of the differentiated bulk silicate Earth.

How to cite: Emo, R., Kamber, B., Downes, H., and Caulfield, J.: A new compositional estimate for refractory lower continental crust, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8700, https://doi.org/10.5194/egusphere-egu22-8700, 2022.

EGU22-8722 | Presentations | GMPV7.2

Sulphur and carbon signatures of metamorphic processes in the Nepal Himalayas 

Sandeep Thapa, Frédéric Girault, Damien Deldicque, Jabrane Labidi, Jana Börner, Christian France-Lanord, Pierre Agrinier, Élodie Muller, Lok Bijaya Adhikari, Mukunda Bhattarai, Kabi Raj Paudyal, Sudhan Singh Mahat, Rémi Losno, and Frédéric Perrier

The Nepal Himalayas result from the India-Eurasia collision and the actual shortening is accommodated by a detachment ramp, the Main Himalayan Thrust (MHT). Separating high-grade metamorphic rocks from the Greater Himalayan Sequence to the north and low-grade metamorphic rocks from the Lesser Himalayan Sequence to the south, the Main Central Thrust (MCT) shear zone, is related to the MHT at depth where large Himalayan earthquakes nucleate. The MCT zone occurs from Far-Western to Eastern Nepal, associated at mid-crustal depth with active seismicity and high electrical conductivity; it exhibits carbon-rich rock layers and numerous active hydrothermal systems. Here, based on a multidisciplinary approach that includes geology, geochemistry and geophysics, we study the various sulphur and carbon signatures in the MCT zone in the Nepal Himalayas. First, we characterise the upper LHS rocks that include alternation of graphite-rich mica-schists (the so-called “black schists”) and carbonates (mainly siliceous dolomite). In the laboratory, we determine organic and inorganic carbon contents, as well as complex electrical conductivity. Second, we concentrate on numerous thermal springs in which we measure dissolved carbon and sulphur concentrations and their isotopic compositions (δ13C and δ34S). Third, we study the surface gaseous emissions, directly observed in the vicinity of hot springs, with the measurements of carbon dioxide (CO2) and hydrogen sulphide (H2S) fluxes and isotopic compositions. By comparing the signatures of carbon and sulphur sequestration and carbon and sulphur release at a large spatial scale, our work provides insights into the carbon source-to-sink duality of large orogens, the metamorphic processes and the carbon and sulphur geochemical cycles.

 

How to cite: Thapa, S., Girault, F., Deldicque, D., Labidi, J., Börner, J., France-Lanord, C., Agrinier, P., Muller, É., Adhikari, L. B., Bhattarai, M., Paudyal, K. R., Mahat, S. S., Losno, R., and Perrier, F.: Sulphur and carbon signatures of metamorphic processes in the Nepal Himalayas, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8722, https://doi.org/10.5194/egusphere-egu22-8722, 2022.

EGU22-8736 | Presentations | GMPV7.2

Dolomite-and magnesite-bearing pelites: poorly investigated, yet significant, sources of CO2 in collisional orogens. 

Shashi Tamang, Chiara Groppo, Franco Rolfo, and Frédéric Girault

Calcite-bearing sediments (calcareous pelites, marls, impure limestones) are among the most investigated sources of carbon in collisional settings (e.g. Groppo et al., 2017, 2021, 2022; Rapa et al., 2017). Dolomite- and magnesite-bearing sediments, however, can also be important constituents of evaporitic sequences deposited along passive margins and involved in collisional orogenic processes. So far, decarbonation reactions in dolomite- and magnesite-bearing rocks have been rarely investigated, and their contribution to the orogenic carbon cycle substantially neglected.          

As a contribution to the understanding of the influence of dolomite- and magnesite-bearing lithologies on the global Earth's carbon cycle, a petrologic study was focused on the Lesser Himalayan Sequence (LHS) in central Nepal. The LHS is a thick Proterozoic sedimentary sequence originally deposited on the northern margin of the Indian plate, metamorphosed during the Himalayan orogeny. Abundant dolomite- and magnesite–bearing lithologies occur in the Upper-LHS, whose protoliths can be grouped in: (1) a dolomitic series (dolostones, dolomitic marls, dolomitic pelites), and (2) a magnesitic series (sparry magnesite ores, magnesitic pelites). The magnesite deposits associated to dolomitic lithologies are interpreted as the evidence of evaporitic environments during the Proterozoic.

The schists derived from dolomitic pelites show mineral assemblages similar to those of normal metapelites, but with significant amounts of Ca-rich minerals (e.g. plagioclase) and with biotite anomalously enriched in Mg. The schists derived from magnesitic pelites are, instead, characterized by uncommon assemblages such as orthoamphibole + kyanite + garnet + phlogopite. Thermodynamic forward modelling (P/T-X(CO2) pseudosections) applied to these schists allowed to: (1) understand the nature of the main decarbonation reactions; (2) constrain the P-T conditions at which these reactions occurred, and (3) estimate the amounts of dolomite/magnesite consumed during prograde metamorphism, and the correspondent amounts of released CO2. The main results are:

  • the observed assemblages formed during a heating decompression stage, at P-T conditions of 620 ± 20°C, 8.5 ± 0.2 kbar, consistent with those registered by the associated metapelites;
  • the observed peak assemblages are predicted to be stable in equilibrium with a CO2-bearing fluid, even in those samples where carbonates are no more preserved;
  • the overall results point to an internally buffered P/T-X(CO2) evolution. The amount of carbonates consumed during prograde metamorphism varies in the range 7-20 vol%, corresponding to 3-10 wt% of CO2 These CO2 amounts are nearly double the CO2 released by calcareous pelites (Groppo et al., 2021).

The main consequence of this study is that the CO2 productivity of dolomitic and magnesitic pelites is significant and that these lithologies could be relevant sources of CO2, possibly contributing to the diffuse Himalayan CO2 degassing (e.g. Girault et al., 2014, 2018).

 

References

Girault et al. (2014). Geoph. Res. Lett. 41, 6358–6366

Girault et al. (2018). Nat. Comm. 9, 2956

Groppo et al. (2017). J. Petrol. 58, 53-83.

Groppo et al. (2021). J. metam. Geol. 39, 181-207.

Groppo et al. (2022). Comm. Earth Environ, doi: 10.1038/s43247-022-00340-w

Rapa et al. (2017). Lithos, 292–293, 364–378.

How to cite: Tamang, S., Groppo, C., Rolfo, F., and Girault, F.: Dolomite-and magnesite-bearing pelites: poorly investigated, yet significant, sources of CO2 in collisional orogens., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8736, https://doi.org/10.5194/egusphere-egu22-8736, 2022.

EGU22-9119 | Presentations | GMPV7.2

Mesozoic titanite U–Pb age from mafic granulites of the Wuhe Complex, southeastern North China Craton (NCC) 

Xu Kong, Jun-sheng Lu, Gang Liu, Qiang Feng, Yu-ting Li, and Yi-yi Zhang

As an important component of the lower crust, mafic granulites can provide a great deal of information about orogens’ metamorphic and tectonic evolution, and thus are studied extensively. According to the previous studies, the Wuhe Complex experienced the Late Paleoproterozoic metamorphic event. Here, we report the newly discovered Mesozoic metamorphic titanite age from the mafic granulites of Wuhe Complex and provide some clues to the Mesozoic metamorphic event of the southeastern NCC. Mafic granulite (sample 20BB44) is composed of garnet (12–15 vol.%), clinopyroxene (30–35 vol.%), hornblende (3–6 vol.%), plagioclase (40–50 vol.%), and quartz (1–2 vol.%) with minor ilmenite, pyrite, apatite, zircon, and titanite. Titanite grains are subhedral, euhedral, or homogeneous with grain sizes of 50–300 μm, and have inclusion minerals of hornblende, plagioclase, quartz, and ilmenite. Titanites have variable contents of U (1.0–17.2 ppm), Th (0.2–29.6 ppm), Pb (2.2–6.5 ppm), and Zr (20–259 ppm) with Th/U ratios of 0.07–4.53. According to the Zr-in-Titanite thermometer (Hayden et al., 2008: the estimated pressure was assumed as 0.5 GPa, and the activity of SiO2 (αSiO2) and TiO2 (αTiO2) were assumed as 1 and 0.8, respectively), the titanites may form at the temperature of 607–725 ℃ (689 ℃ on average). Thirty analysis spots on 29 titanite grains yield a lower intercept U–Pb age of 163 ± 28 Ma (MSWD = 1.17). Titanite U–Pb age of 163 Ma may represent the Mesozoic metamorphic event of southeastern NCC and may relate to the subduction of the Paleo-Pacific plate.

How to cite: Kong, X., Lu, J., Liu, G., Feng, Q., Li, Y., and Zhang, Y.: Mesozoic titanite U–Pb age from mafic granulites of the Wuhe Complex, southeastern North China Craton (NCC), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9119, https://doi.org/10.5194/egusphere-egu22-9119, 2022.

EGU22-9177 | Presentations | GMPV7.2

Metamorphic P-T-t paths of Neoarchean pelitic granulites from the Qingyuan terrane, eastern North China Craton 

Gang Liu, Jun-sheng Lu, Xu Kong, Qiang Feng, Yu-ting Li, and Yi-yi Zhang

Precambrian high-pressure (HP) granulites can provide crucial information for reconstructing ancient continental nuclei. Here we report the pelitic granulites from Qingyuan terrane, eastern North China Craton (NCC), which are archean supracrustal rocks occurred as enclaves in gneisses. Two samples from the pelitic granulites both record clockwise P-T paths involving prograde stage (M1), peak stage (M2) and post-peak stage (M3). Prograde stage is represented by biotite, plagioclase, quartz, rutile and ilmenite, preserved as mineral inclusions whthin garnet porphyroblasts, formed at P-T conditions of 8-9 kbar/670-700 ℃ constrained by mineral assemblages within garnet porphyroblasts and Ti-in-quartz geothermometer. The peak stage (M2) can be represented by the garnet cores, matrix rutile, kyanite, K-feldspar and the P-T conditions are constrained to be ~12 kbar/800-820 ℃ by the isopleths of XPy and XGrs from the core of garnet grains. The followed post-peak stage (M3) can be represented by matrix minerals assemblages including garnet, biotite, K-feldspar, sillimanite, ilmenite, quartz and plagioclase, revealing isothermal decompression process to ~9 kbar constrained by the isopleths of XPy and XGrs from inner rims of garnet grains. Monazite age dating suggests that the pelitic granulites possibly reached the peak metamorphic stage at ~2.47 Ga, slightly later than TTG magmatic events. The clockwise P-T paths including sequential isothermal decompression (ITD) segments recorded by the pelitic granulites may be caused by a subduction-collision event during the late Neoarchean in the eastern NCC.

How to cite: Liu, G., Lu, J., Kong, X., Feng, Q., Li, Y., and Zhang, Y.: Metamorphic P-T-t paths of Neoarchean pelitic granulites from the Qingyuan terrane, eastern North China Craton, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9177, https://doi.org/10.5194/egusphere-egu22-9177, 2022.

EGU22-9282 | Presentations | GMPV7.2

LA-ICP-MS U-Pb dating on zircons from the Lepontine Dome (Central European Alps) 

Alessia Tagliaferri, Filippo Luca Schenker, Stefan Markus Schmalholz, Alexey Ulianov, and Silvio Seno

The Lepontine Dome is a structural and metamorphic dome formed by crystalline basement nappes belonging to the Penninic domain of the European Alps (Switzerland). The mineral-zone boundaries of the Barrovian Tertiary metamorphism show an asymmetric concentric zonation not coinciding with the dome shape defined by the regional attitudes of foliation and thrust sheets. The related Barrovian isogrades locally dissect the tectonic nappe contacts suggesting a post-thrusting thermal event. However, the extremely pervasive and NW-SE directed mineral and stretching lineation, also developed during the upper amphibolite facies metamorphism, suggests non-coaxial deformation during thrusting at peak metamorphic conditions. This apparent paradox may be explained with several geodynamic scenarios that are still debated by the scientific community. One crucial element helping to evaluate the different scenarios is the timing of the upper amphibolitic, non-coaxial deformation along the tectonic contacts, which is still poorly constrained. Hence, the goal of our work is to date this deformation with a multidisciplinary approach that aims to solve the relation between the geologic structures and the distribution of heat in the nappe pile.

In the studied domain, the lower unit (the Simano nappe) is formed by metagranitoids and by minor paragneiss. The upper thrusted unit (the Cima Lunga/Adula nappe) is made of metasediments, mainly quartz-rich gneiss intercalated with amphibole-gneiss, peridotitic lenses and, locally, calcschist and/or marble. The alternation of lithotypes is mostly parallel to the nappe boundary, and constant over its kilometer-scale length. Below the Cima Lunga/Adula, the transition to the Simano nappe is marked by a progressive change in gneiss texture: more stretched towards the top of the sequence, indicating a strain increase. Migmatitic leucogneisses have been found parallel to the tectonic contacts. Field observations indicate that their deformation is syn-tectonic, hence suggesting partial melting conditions during nappe emplacement. Their foliation is locally crosscut by granitic dikes of aplitic and pegmatitic texture.

To define the temporal duration of melting, U-Pb zircon dating with LA-ICP-MS (Laser Ablation Inductively Coupled Plasma Mass Spectrometry) has been performed on migmatites, paragneiss, gneiss, and granitic dikes. The results show two main groups of (metamorphic) ages centring at ca. 31 and 22 Ma. The younger ages date the intrusion of the post-tectonic dikes found exclusively in the southernmost area, proximal to the roots of the Lepontine nappes, likely related to the melt production along the Southern Steep Belt which lasted until ca. 22 Ma (according to U-Pb zircon dating by other authors). Ages indicating ca. 31 Ma are widespread from north to south, representing the nappe emplacement stage, coeval with migmatization.

Our results suggest the existence of two main heat sources: one related to thrusting and the other to fluid advection and/or diffusion of heat from the bottom along the Southern Steep Belt. Which heat source is responsible for the regional Barrovian metamorphism remains unclear. Our future studies will focus on the comprehension of the mechanisms of heat transfer and the relative roles of diffusion, advection and production to understand how these events are responsible for the net Barrovian heat budget of the Lepontine Dome.

How to cite: Tagliaferri, A., Schenker, F. L., Schmalholz, S. M., Ulianov, A., and Seno, S.: LA-ICP-MS U-Pb dating on zircons from the Lepontine Dome (Central European Alps), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9282, https://doi.org/10.5194/egusphere-egu22-9282, 2022.

EGU22-9332 | Presentations | GMPV7.2

"Too old" zircon (U-Th)/He ages in Austro- and Southalpine units of the European Alps: an overestimate of temperature or an underestimate of helium retention? 

Bianca Heberer, István Dunkl, Franz Neubauer, Sina Schulz, William Guenthner, Hannah Pomella, and Hilmar von Eynatten

Zircon (U-Th)/He (ZHe) dating has seen rapid growth and widespread application among low-temperature thermochronological methods. Complex diffusion kinetics, primarily due to radiation damage density, may substantially influence the diffusivity of He and cause a wide temperature range from ca. 220 to <25 °C for the transition from an open to a closed system. Complexities may augment for (meta-)sedimentary rock samples containing minerals of different initial ages with highly variable uranium content leading to differences in accumulated radiation damage and thus annealing behaviours. In such cases, individual grains may only share their postdepositional thermal path. Current diffusion models predict inheritance to play a role for those samples that remained at diagenetic temperatures below 200 °C during burial.

In this contribution, we address the question whether ZHe dates from anchizonal to very low-grade metamorphic units may be transformed into geologically meaningful age information and as such may enhance thermal history reconstructions. We applied ZHe dating on 37 samples from Austroalpine and Southalpine basement-cover series adjacent to the eastern part of the Periadriatic fault line. In an attempt to quantify maximum thermal overprint during Alpine burial we compiled evidence from paleothermal indicators (e.g. vitrinite reflectance, illite crystallinity, CM Raman spectroscopy), geological field observations, and geochronological dates. These data suggest overprint at diagenetic conditions up to low-grade metamorphism in our study area. According to current ZHe diffusion models anchizonal and higher thermal conditions should have harmonized the samples’ age response and thus should have reset the ZHe system leading to concordant Alpine ages.

However, our new thermochronological dataset is characterized by a large variability in intra- and intersample age dispersion. Most of our single grain ages ranging from 12 to 305 Ma are much older than predicted by forward modeling. Such mismatch may be explained either by an underestimate of He retention resulting from a still incomplete understanding of He diffusivity. In this scenario, metasedimentary samples with an overprint up to lower anchizonal conditions (≤270°C) are likely to preserve inherited detrital information and cooling ages will reflect both the previous and most recent thermal histories. Alternatively geothermal data compiled from the literature may have overestimated peak temperatures reached during Alpine burial.

Both alternatives will be discussed in detail as they bring up challenging methodical issues. We underline the need for combining thermal maturity studies with ZHe low-temperature thermochronology in order to extract thermal history information for such complex detrital datasets.

 

How to cite: Heberer, B., Dunkl, I., Neubauer, F., Schulz, S., Guenthner, W., Pomella, H., and von Eynatten, H.: "Too old" zircon (U-Th)/He ages in Austro- and Southalpine units of the European Alps: an overestimate of temperature or an underestimate of helium retention?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9332, https://doi.org/10.5194/egusphere-egu22-9332, 2022.

EGU22-9426 | Presentations | GMPV7.2

Fluid-rock interactions and amphibolitisation of the lower continental crust (The Kråkenes Gabbro, Western Gneiss Region, Norway) 

Saskia Bläsing, Timm John, Johannes C. Vrijmoed, Michael J. Henehan, and Daniel A. Frick

To understand numerous geological processes, like element recycling or plate dynamics, the quantification of fluid-induced reactions in the Earth’s crust and mantle is an important but challenging subject, especially for short-lived events including substantial mass exchange. Lithium can serve as a powerful tool to quantify timing and fluid-flow mechanisms that happen on short geological timescales, because it is a very fast diffusing element and usually appears as a trace element in both fluid and rock.

The Kråkenes Gabbro is part of a fossil continent-continent collision zone, located in the Western Gneiss Region in Norway, and shows the effects of fluid-rock interaction perfectly.  The low permeability gabbro is cross-cut by strictly N-S-trending fractures, which opened during exhumation, serving as a pathway for an aqueous fluid to infiltrate the rock. Metasomatism occurred under amphibolite-facies conditions, resulting in a sharp amphibolite-generating reaction front propagating on dm-scale into the magmatic gabbro. This reaction is driven by strong chemical gradients between the reactive fluid and the dry, metastable gabbro. Samples were taken as continuous profiles (~ 30 cm length) perpendicular to the vein and analyzed using a) SEM automated quantitative mineralogy mapping to quantify evolving mineral assemblages during amphibolite-facies metamorphism and b) MC ICP-MS to determine variations in bulk rock lithium concentrations and isotope compositions along the profile.

To understand fluid-flow mechanisms, reactive flow-based diffusion models were created, and model accuracy was checked by integrating measured mineral and lithium data. Mass balance calculations and recalculations of the gabbro and amphibolite mineral assemblages give information on the fluid composition and its transported elements, showing that the fluid-induced reaction is not diffusion-limited only. Furthermore, these models portray the evolving reaction front and the evolution of physical parameters such as mineral assemblage, density or porosity within it. Our investigations into lithium concentrations and δ7Li values show that lithium is transported by the fluid into the formerly almost dry system and thus propagated into the gabbro. Reaction-induced variations in e.g. porosity and partition coefficients are included into lithium-diffusion models to find the minimum misfit between measured and modelled lithium data to estimate the duration of the fluid-induced reaction.

How to cite: Bläsing, S., John, T., Vrijmoed, J. C., Henehan, M. J., and Frick, D. A.: Fluid-rock interactions and amphibolitisation of the lower continental crust (The Kråkenes Gabbro, Western Gneiss Region, Norway), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9426, https://doi.org/10.5194/egusphere-egu22-9426, 2022.

EGU22-9763 | Presentations | GMPV7.2

Coupling pressure-temperature and time constraints in greenschist- and amphibolite-facies polymetamorphic rocks: a case study from the Austroalpine Unit (Eastern Alps, Austria) 

Marianne Sophie Hollinetz, Benjamin Huet, David A. Schneider, Christopher R. M. McFarlane, and Bernhard Grasemann

In low-grade metamorphic units, precise thermobarometric and geochronologic data are often ambiguous or entirely lacking, thus complicating the temporal interpretation of metamorphism and hampering the identification of complex polymetamorphic histories. We present new P-T-t-D data from samples collected in two Austroalpine nappes exposed in the Eastern Alps, Austria: the structurally upper greenschist-facies Schöckel Nappe (“Graz Paleozoic,” Drauzug-Gurktal Nappe System) and the structurally lower amphibolite-facies Waxenegg Nappe (Koralpe-Wölz Nappe System). Although polymetamorphism was previously inferred from garnet zonation indicating multiphase growth in the Waxenegg Nappe, the timing of metamorphism is poorly resolved and only limited geochronology exists in the Schöckel Nappe.

Detailed petrographic investigations revealed that the chloritoid-bearing phyllite and micaschist of the Schöckel Nappe contain allanite that occasionally show partial replacement by small (<10 µm) monazite and thorite. Large (up to 500 µm) monazite exhibiting distinct core-rim chemical zoning were observed in the garnet-bearing micaschist of the Waxenegg Nappe. Careful documentation of the microstructural phase relations, thermodynamic modeling in the MnCNKFMASHT system, Raman spectroscopy of carbonaceous matter and in-situ LA-ICPMS U-(Th)-Pb dating of the accessory phases allow us to reconstruct a first metamorphic imprint at ~560°C and 4 kbar in the Waxenegg Nappe at c. 270 Ma (Permian event). Overprinting occurred at ~540°C and 8-10 kbar at c. 90 Ma (Eo-Alpine event). In the Schöckel Nappe, peak metamorphic conditions of ~470°C and 3-4 kbar existed during the Permian event at c. 260 Ma and the Eo-Alpine event in the upper part of the nappe did not exceed lower to middle greenschist-facies conditions.

Our results provide unequivocal evidence for Permian metamorphism in the Schöckel Nappe, which was hitherto unknown in this part of the Austroalpine Unit. Moreover, it demonstrates that the main metamorphic signature in this unit occurred during the Permian event and that the Eo-Alpine overprint is relatively lower grade than previously proposed. Combined with the data from the Waxenegg Nappe, there is an obvious marked increase in the Eo-Alpine peak conditions of ~130°C and 5 kbar across the nappe contact with higher grade in the footwall compared to the hanging wall. This is consistent with the existence of a major normal fault between the Drauzug-Gurktal Nappe System and the Koralpe-Wölz Nappe System in the easternmost part of the Austroalpine Unit, as already identified in its central and western parts. Modern thermobarometric analytical approaches coupled with high spatial resolution geochronology on accessory minerals is allowing a more thorough assessment of the subtle metamorphic histories recorded in the fundamentally important low-grade units of orogens.

How to cite: Hollinetz, M. S., Huet, B., Schneider, D. A., McFarlane, C. R. M., and Grasemann, B.: Coupling pressure-temperature and time constraints in greenschist- and amphibolite-facies polymetamorphic rocks: a case study from the Austroalpine Unit (Eastern Alps, Austria), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9763, https://doi.org/10.5194/egusphere-egu22-9763, 2022.

EGU22-11750 | Presentations | GMPV7.2

Isothermal compression of an eclogite from the Western Gneiss Region (Norway): a multi-method study 

Martin Simon, Pavel Pitra, Philippe Yamato, and Marc Poujol

The Western Gneiss Region in Norway is constituted by a crustal nappe stack that comprises some of the best-preserved exhumed ultra-high pressure (UHP) terranes on Earth. The UHP rocks result from the subduction of the western edge of the Baltica craton beneath Laurentia during the Caledonian orogeny. Mafic eclogites form lenses within granitoid orthogneisses and show the best record of the pressure and temperature evolution. Their exhumation from the UHP conditions has been largely studied, but the prograde evolution has been rarely quantified in the eclogites although it constitutes an important constraint on the tectonic history of this area. This study focused on an unaltered eclogite sample from Vågsøy in the Nordfjord region. This sample was investigated using a large panel of methods including phase-equilibria modelling, trace-element analyses of garnet, trace- and major-element thermo-barometry and quartz-in-garnet barometry by Raman spectrometry. The eclogite comprises omphacite, garnet, white mica, epidote and amphibole and accessory rutile, quartz, zircon, carbonates and kyanite. Garnet shows a grossular-rich core with inclusions of quartz, epidote, white mica and amphibole, while grossular-poor rims are enriched in pyrope and middle rare-earth elements and include omphacite and rutile. Inclusions in garnet core point to crystallisation conditions in the amphibolite facies at 550–600 °C and 11–15 kbar, while chemical zoning in garnet suggests growth during isothermal compression up to the peak pressure of 28 kbar at 600 °C, followed by near-isobaric heating to 640–680 °C. Isothermal decompression to 8–13 kbar is recorded in fine-grained clinopyroxene-amphibole-plagioclase symplectites. The absence of a temperature increase during compression seems incompatible with the classic view of crystallization along a geothermal gradient in a subduction zone and may question the tectonic significance of eclogite-facies metamorphism. Two main tectonic scenarios are discussed to explain such an isothermal compression: (1) either the mafic rocks were originally at deep level within the lower crust and were then buried along the isothermal part of the subducting slab, or (2) the mafic rocks recorded significant tectonic overpressure at constant depth and temperature conditions during the collisional stage of the orogeny. A multi-chronometer geochronological study is currently performed and expected to bring additional, discriminant constraints on this P–T evolution. 

How to cite: Simon, M., Pitra, P., Yamato, P., and Poujol, M.: Isothermal compression of an eclogite from the Western Gneiss Region (Norway): a multi-method study, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11750, https://doi.org/10.5194/egusphere-egu22-11750, 2022.

EGU22-11826 | Presentations | GMPV7.2

Formation of garnet-clinopyroxene coronas at orthopyroxene–plagioclase contacts during high-pressure granulite facies metamorphism, Gföhl unit, Moldanubian zone 

Rene Asenbaum, Julian Portenkirchner, Martin Racek, Elena Petrishcheva, and Rainer Abart

Corona microstructures comprised of garnet (grt) and clinopyroxene (cpx) were observed at the contacts between plagioclase (pl) and Fe-rich orthopyroxene (opx) in meta-gabbroic rocks in a several 100 m sized (ultra-)mafic lens embedded in felsic granulite of the Gföhl unit (Moldanubian zone, Lower Austria).

The corona microstructures are formed around monomineralic aggregates of opx and they are comprised of two layers, an inner about 100 μm thick
layer of polycrystalline cpx and an outer, about 800 μm thick layer of polycrystalline garnet. The corona structures are surrounded by the pl-rich rock matrix. The cpx layer shows a weak but systematic chemical zoning characterized by increasing Mg and decreasing Na and Al contents from the contact with grt towards the contact with opx. The grt layer shows a pronounced and complex chemical zoning. There is a consistent trend of decreasing Mg and increasing Ca contents from the contact with the cpx layer, where the composition is Alm22 Prp67 Grs11 towards the contact with the rock matrix, where we observe Alm25 Prp48 Grs28. This pattern is interpreted as a primary growth zoning. Superimposed on the growth zoning there is a secondary zoning, which is evident from a decrease of the Ca content and a concomitant increase of the Mg content from the interior of the individual grains
of the grt polycrystal forming the grt layer towards the grt grain boundaries. The secondary zoning is most pronounced in the outermost portions of the garnet layer, where the primary growth zoning shows the highest Ca and the lowest Mg contents. Locally the garnet grains contain abundant primary melt inclusions. In most segments of the corona, secondary opx and pl form layers along the contact between the primary cpx and grt layer, where the opx partially replaces the cpx layer and the pl partially replaces grt. The secondary opx has higher Mg and lower Na, Al, and Ca contents than the opx
in the core of the corona structure. The secondary pl has the same composition as the matrix pl. At its outer edge, the garnet layer is locally replaced by spinel bearing cpx-pl symplectites. The primary compositional zoning of the garnet layer could be reproduced in equilibrium assemblage diagrams (pseudosections). Calculated equilibrium phase relations indicate that the grt-cpx corona formed at the contacts between opx and pl at supersolidus HP − HT conditions of P > 1.8 GPa and T > 900 °C and low H2O content. Growth of coronal grt and cpx requires the diffusive transport of Fe and Mg from the opx to the pl and concomitant transport of Ca and Al in the opposite direction. The secondary zoning of garnet, the back reaction forming secondary opx and pl at the contact between the primary grt and cpx layer and the spinel bearing pl-cpx symplectites locally replacing garnet at the outer edge of the grt layer are related to different decompression stages. Preservation of the secondary garnet zoning indicates relatively rapid cooling during late
stages of or immediately after decompression.

How to cite: Asenbaum, R., Portenkirchner, J., Racek, M., Petrishcheva, E., and Abart, R.: Formation of garnet-clinopyroxene coronas at orthopyroxene–plagioclase contacts during high-pressure granulite facies metamorphism, Gföhl unit, Moldanubian zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11826, https://doi.org/10.5194/egusphere-egu22-11826, 2022.

Methane (CH4) bubbles in muddy aquatic sediments threaten climate sustainability and sediment mechanical stability. Mechanical response of muddy sediment to bubble growth is described by Linear Elastic Fracture Mechanics (LEFM). Minor roles of mechanical sediment characteristics in CH4 bubble solute supply and growth rates were quantified compared to biogeochemical controls. We investigate them using a coupled single-bubble mechanical/reaction-transport numerical and analytical models. We demonstrate that inner pressure of the growing bubble at fracturing, concentration at its surface, bubble size and spatial location, are uniquely defined by Fracture Toughness. However, a temporal evolution of the bubble inner pressure at expansion between the fracturing events depends on Young’s modulus. Fracture Toughness and Young’s modulus thus play complementary, spatial and temporal, roles in bubble growth. Their proportionality suggested by LEFM manages the bubble growth rates.  Fracture Toughness controls development of longer flatter bubbles in the deeper sediments. A substantial role of mechanical muddy sediment characteristics in the CH4 bubble growth dynamics and solute exchange is demonstrated, comparable to the role of the biogeochemical controls. Their contribution to emergence of “no-growth” and competitive bubble growth conditions, affecting a macro-scale gas dynamics are discussed that encourages a proper experimental evaluation of muddy sediment mechanical characteristics.

How to cite: Zhou, X. and Katsman, R.: Mechanical controls on methane bubble solute exchange within muddy aquatic sediments and its growth characteristics, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1987, https://doi.org/10.5194/egusphere-egu22-1987, 2022.

EGU22-2293 | Presentations | GMPV6.4

Nanoparticles formed during mineral-fluid interactions 

Christine V. Putnis and Encarnación Ruiz-Agudo

Mineral-fluid replacement reactions occur ubiquitously throughout the crust of the Earth, often resulting in the formation of nanoparticles. Recent research highlights the formation of nanoparticles1, especially in the light of mineral/crystal growth by non-classical growth mechanisms, whereby solids form from prenucleation species or clusters within an aqueous solution from which solid nanoparticles precipitate. This is very often related to the dissolution of an existing mineral/solid phase that is coupled at the mineral-fluid interface with the precipitation of a new more stable phase2. This process will occur wherever aqueous fluids can penetrate and react with constituent minerals of a rock, that is, along fractures, grain boundaries and initial or reaction-induced interconnected porosity, all potential pathways for fluid-mediated reactions. Examples given here highlight fluid pathways and subsequent nanoparticle formation, an understanding of which can be useful for potential environmental remediation strategies, such as carbon mineralization and toxic element sequestration. Recent advances in analytical techniques, such as advances in atomic force microscopy, advanced scanning and transmission microscopies, are enabling the imaging of nanoparticles. Examples presented illustrate the conditions under which nanoparticles form during the coupling of dissolution and precipitation and enable a better understanding of the mechanisms that drive fluid-mineral reactions.

References

1Putnis C.V. and Ruiz-Agudo E. 2021. Nanoparticles formed during mineral-fluid interactions. Chem. Geol. 586, 120614.

2Ruiz-Agudo E., Putnis C.V., Putnis A. 2014. Coupled dissolution and precipitation at mineral-fluid interfaces. Chem. Geol., 383, 132-146.

How to cite: Putnis, C. V. and Ruiz-Agudo, E.: Nanoparticles formed during mineral-fluid interactions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2293, https://doi.org/10.5194/egusphere-egu22-2293, 2022.

EGU22-2307 | Presentations | GMPV6.4

Fluid-rock reaction mechanisms and the inevitable consequences for mass transport and texture formation. 

Andrew Putnis, Jo Moore, and Håkon Austrheim

It is well-established that the mechanism of re-equilibration of a mineral assemblage at temperatures where the spatial scale of solid-state diffusion is restricted to intra-crystalline processes, is by dissolution-transport-precipitation. When the dissolution and precipitation steps are spatially coupled, pseudomorphic mineral replacement, in the absence of deformation, is a common observation in both nature and experiment. External stress appears to uncouple the dissolution and precipitation steps, inevitably leading to mass transport and dissolution-precipitation creep as the dominant deformation mechanism. The precipitation process involves nucleation and, in deforming rocks, the minimisation of surface energy leads towards textural equilibration and metamorphic differentiation. The overall process can be considered as a sequence of recrystallisation steps that lead to minimisation of chemical and textural components of the overall free energy. Examples will be given from metamorphic reactions, diagenesis and sub-solidus texture formation in igneous rocks.

How to cite: Putnis, A., Moore, J., and Austrheim, H.: Fluid-rock reaction mechanisms and the inevitable consequences for mass transport and texture formation., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2307, https://doi.org/10.5194/egusphere-egu22-2307, 2022.

EGU22-2331 | Presentations | GMPV6.4

Grain boundaries as reactive fluid pathways in rocks 

Lorena Hernández-Filiberto, Christine V. Putnis, Andrew Putnis, and Håkon Austrheim

The presence of aqueous fluids is ubiquitous in the Earth’s crust. Grain boundaries play an important role in enabling fluids to penetrate through the rock system. Their influence in fluid-rock reactions that might lead to relevant processes such as mineral replacements, the formation of new minerals and dissolution of others, element mobilization, variations in rock density, changes in stress distribution, mass transfer, etc., are commonly observed in many rock samples as well as generated and observed in laboratory experiments. As a product of these reactions, porosity and fractures might also be generated and potentially allow the fluid to penetrate even further.

Here we present our first analyses on different rock samples where the fluid-rock interaction has been induced through hydrothermal laboratory experiments using either Carrara Marble or plagioclase samples. The evidence for such interactions having previously occurred in natural rocks has been investigated in a sequence of a granulite rock samples from the Bergen Arcs in Norway. Using light microscopy as well as SEM, EDX and Electron Microprobe analysis we have investigated possible fluid pathways and evidence of fluid-mineral reactions as well as the mechanisms that could explain such processes.

How to cite: Hernández-Filiberto, L., Putnis, C. V., Putnis, A., and Austrheim, H.: Grain boundaries as reactive fluid pathways in rocks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2331, https://doi.org/10.5194/egusphere-egu22-2331, 2022.

EGU22-2361 | Presentations | GMPV6.4

The effect of cadmium on calcium carbonate growth and dissolution 

Maude Julia, Christine V.Putnis, Helen E.King, and François Renard

Calcium carbonates are ubiquitous minerals in nature and have been recently studied for potential environmental remediation as a toxic element retainer following reaction with contaminated water. This work aims to study the effect of cadmium ions, a major pollutant in soil and waterways, on calcium carbonate dissolution and growth using different experimental and analytical methods. Firstly, calcite growth and dissolution in the presence of varied Cd2+ concentrations have been observed with in situ atomic force microscopy (AFM). Then hydrothermal experiments have been conducted to compare calcite and Carrara marble samples to study the effect of grain boundaries on calcium carbonate dissolution in the presence of solutions containing Cd2+. Results indicate that a new (Ca,Cd)CO3 phase is formed on the calcite surfaces that become increasingly covered and possibly passivated by the presence of this new layer. This is observed in both the AFM experiments as well as hydrothermal experiments using calcite crystals. However, the grain boundaries within Carrara marble act as fluid pathways within the rock allowing access for the Cd – rich solutions to penetrate within the sample. Surface passivation compared with coupled dissolution-precipitation replacement reactions are investigated in terms of molar volume changes and solubility differences between parent (CaCO3) and product ((Ca,Cd)CO3) phases as well as reaction kinetic considerations.

How to cite: Julia, M., V.Putnis, C., E.King, H., and Renard, F.: The effect of cadmium on calcium carbonate growth and dissolution, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2361, https://doi.org/10.5194/egusphere-egu22-2361, 2022.

EGU22-7619 | Presentations | GMPV6.4

Effect of normal fault activity on carbonate reservoir diagenetic evolution (Urgonian facies, SE France) 

Irène Aubert, Phillippe Léonide, François Fournier, Hugues Bitault, Juliette Lamarche, Nicolas Godeau, Pierre Deschamps, Rodigo Correa, and Lionel Marié

Normal fault zones can have a significant role on fluid flows as they can form barriers or drains (Agosta et al., 2010; Bense et al., 2013; Brogi and Novellino, 2015). In carbonates rocks, which are very sensitive to fluid-rock interactions, these fault-related fluid flows can strongly enhance or alter carbonate reservoir properties (Deville de Periere et al., 2017; Fournier and Borgomano, 2009).

This work aims at determine fluid flow evolution in a carbonate reservoir affected by a normal fault. For this purpose, we studied structural and diagenetic properties of the Esperelles normal fault and the surrounding Barremian and Aptian formations located on the northern flank of Nerthe anticline (SE France). Esperelles fault developed during the Durancian uplift (Albian) and was weakly reactivated during the opening of Liguro-Provençal basin during Oligo-Miocene times.

We defined seven different cements under cathodoluminescence (C0 to C6), their distributions along the outcrop, their geochemical properties (18O and 13C stable isotopes, Δ47 thermometry), and their ages (U-Pb). Diagenetic properties have been correlated with petrophysical measurements. We determined the paragenetic sequence, as well as the nature and temperature of the fluids that led to the formation of C1 and C6 cements. Four U-Pb ages have been obtained using an ELEMENT XR (Thermo-Fisher) SF-ICP-MS coupled to a 193 nm Excimer Laser (ESI) at CEREGE (Aix-en-Provence, France).  These ages allowed to relate the C6 cementing phase with the opening of Liguro-Provençal basin. This study shows that fault zone development impacted reservoir fluid flows, leading to significant diagenetic events and development of heterogeneous reservoir properties.

 

References

Agosta, F., Alessandroni, M., Antonellini, M., Tondi, E. and Giorgioni, M.: From fractures to flow: A field-based quantitative analysis of an outcropping carbonate reservoir, Tectonophysics, 490(3–4), 197–213, doi:10.1016/j.tecto.2010.05.005, 2010.

Bense, V. F., Gleeson, T., Loveless, S. E., Bour, O. and Scibek, J.: Fault zone hydrogeology, Earth-Science Rev., 127, 171–192, doi:10.1016/j.earscirev.2013.09.008, 2013.

Brogi, A. and Novellino, R.: Low Angle Normal Fault (LANF)-zone architecture and permeability features in bedded carbonate from inner Northern Apennines (Rapolano Terme, Central Italy), Tectonophysics, 638(1), 126–146, doi:10.1016/j.tecto.2014.11.005, 2015.

Deville de Periere, M., Durlet, C., Vennin, E., Caline, B., Boichard, R. and Meyer, A.: Influence of a major exposure surface on the development of microporous micritic limestones - Example of the Upper Mishrif Formation (Cenomanian) of the Middle East, Sediment. Geol., 353, 96–113, doi:10.1016/j.sedgeo.2017.03.005, 2017.

Fournier, F. and Borgomano, J.: Critical porosity and elastic properties of microporous mixed carbonate-siliciclastic rocks, Geophysics, 74(2), E93–E109, doi:10.1190/1.3043727, 2009.

How to cite: Aubert, I., Léonide, P., Fournier, F., Bitault, H., Lamarche, J., Godeau, N., Deschamps, P., Correa, R., and Marié, L.: Effect of normal fault activity on carbonate reservoir diagenetic evolution (Urgonian facies, SE France), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7619, https://doi.org/10.5194/egusphere-egu22-7619, 2022.

EGU22-8313 | Presentations | GMPV6.4

Using Raman spectra of isotopically enriched transformation products to trace mineral reactions 

Helen E. King, Aleksandar Živković, Markus Ohl, and Oliver Plümper

Isotopic doping is a powerful tool to identify newly formed mineral phases during fluid-mediated mineral transformation reactions. In particular, Raman spectroscopy of isotopically doped minerals can reveal incorporation of the isotopes into the structure of the minerals themselves, rather than enrichment of a fluid within a pore (1). In fluid mediated mineral transformations, dissolution of the reactant mineral enables O isotope exchange between water and dissolved oxyanions (e.g., CO3). Incorporation of the isotopically enriched oxyanions can result in crystals with different isotopic enrichments if the rate of the exchange in the fluid occurs on a similar timescale to the duration of the experiment and the crystals form at different times. This means that the amount of isotopic enrichment can be used as an internal stop clock and demonstrates the relative timings of precipitation in ex-situ analysis (2). In this presentation we will use previous examples to explore how fluid-mediated mineral transformation reactions can be followed using isotopic enrichment traced with Raman spectroscopy, including new data after deformation experiments. Using new data obtained from in-situ analysis of 18O exchange into dissolved carbonate species we will also show the importance of the solution chemistry on exchange kinetics in the fluid. In addition, we will use density functional theory calculations to explore how the mineral structure may influence the isotopic signature obtained from the Raman spectra. 

(1) King H.E. & Geisler T. (2018) Minerals, 8. 158.

(2) King H.E., Mattner D.C., Plümper O., Geisler T., Putnis A., (2014) Crystal Growth & Design, 14, 3910.

How to cite: King, H. E., Živković, A., Ohl, M., and Plümper, O.: Using Raman spectra of isotopically enriched transformation products to trace mineral reactions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8313, https://doi.org/10.5194/egusphere-egu22-8313, 2022.

EGU22-8368 | Presentations | GMPV6.4

Estimation of the partial fluid composition after fluid-rock interaction: from mass balance calculations with an application to natural dolomitization 

Stephen Centrella, Guilhem Hoareau, Nicolas E. Beaudoin, Geoffrey Motte, Pierre Lanari, and Francesca Piccoli

Using the example of dolomitization where calcite is replaced by dolomite, estimation of the fluid composition in equilibrium with dolomite for major and trace elements was estimated based on EPMA and LA-ICP-MS data using a mass balance approach. The method consists in an analytical quantification of the mass transfer between the original calcite and the newly formed dolomite giving us which elements are coming in and out of the system. Chemical composition of the aqueous fluid in equilibrium with dolomite can be estimated such as the partition coefficient for each element involved in the reaction. This approach was tested using three existing datasets obtained from natural dolomite and original limestone in both Jurassic limestones of the Layens anticline in the Pyrenees (France), and two from the Middle Devonian Presqu’ile barrier from Pine Point (Canada). These are completed with data acquired in Cretaceous limestones of the Benicassim area of the Maestrat Basin (Spain). Using the result obtained with the mass balance calculation, the amount of fluid required to dolomitized a fixed amount of limestone can be obtained for different fluid source (brine and seawater). Results show that the four dolomitization reactions have similar solid volume variation (-14 to -10 vol.%) and the fluid in equilibrium with the dolomite have also similar concentration in trace element. Estimation of the partition coefficients for all trace elements for the three regions were determined and compared.

How to cite: Centrella, S., Hoareau, G., Beaudoin, N. E., Motte, G., Lanari, P., and Piccoli, F.: Estimation of the partial fluid composition after fluid-rock interaction: from mass balance calculations with an application to natural dolomitization, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8368, https://doi.org/10.5194/egusphere-egu22-8368, 2022.

EGU22-8827 | Presentations | GMPV6.4

Barite reactivity at solubility equilibrium as a function of [Ba2+]/[SO42-] ratios 

Chen Zhu, Jinting kang, jacky Bracco, and Lei gong

We carried out 137Ba and 34S-spiked experiments and measured barium attachment and detachment fluxes from and to barite crystal surfaces in solutions at solubility equilibrium with barite. The [Ba]/[SO4] ratios in solutions varied from 0.06 to 52. Both attachment and detachment fluxes increase with [Ba]/[SO4] ratios. As expected, since the solutions were near solubility equilibrium ( ), the attachment and detachment fluxes were nearly equal and net fluxes or reaction rates were zero.

The isotope flux data together with step velocity data from AFM studies by Kowacz et al. (2007) were simultaneously fit into the Zhang and Nancollas (1998) process-based AB crystal growth model, which describes crystal growth and dissolution through nucleation and propagation of kink sites. The Newton Conjugate Gradient Trust Region algorithm was used for simultaneously and optimally regressing both attachment and detachment rate coefficients. Simultaneous fitting step velocity data of Kowacz et al. (2007) significantly reduced the number of non-unique solutions. The excellent agreement indicates that attachment and detachment fluxes and step velocity are consistent and complement each other.

The results of this study demonstrate significant isotopic changes in solutions and solids from mineral-fluid interactions at solubility equilibrium. The Zhang and Nancollas (1998) model has been used as a foundation for interpreting isotopes and trace element data. Our results therefore have significant implications for extending it to the understanding in diagenetic and low temperature metamorphic processes.

How to cite: Zhu, C., kang, J., Bracco, J., and gong, L.: Barite reactivity at solubility equilibrium as a function of [Ba2+]/[SO42-] ratios, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8827, https://doi.org/10.5194/egusphere-egu22-8827, 2022.

EGU22-10265 | Presentations | GMPV6.4

The role of stable and traveling reactive waves in mineralization 

Daniel Koehn, Kelka Ulrich, Renaud Toussaint, Gary Mullen, and Adrian Boyce

Fluid mixing is interpreted as one of the main drivers for the development of hydrothermal mineralization whereby the actual physical processes that lead to mineral precipitation, and thus ore localization, are poorly understood. In this contribution, we will shed light on the mechanisms that are active in a simple fluid-mixing scenario by simulating the infiltration of a metal-rich fluid into a rock saturated with seawater derived pore-fluid and study the developing mineral saturation patterns.

We combine an advection-diffusion code in the microstructural model Elle with the geochemical module iphreeqc to study the distribution of enhanced saturation indices during fluid mixing. In the simulations the hot highly saline metal rich fluid enters the small 5x5m system through two high-permeable faults from below and percolates into the pore space. For the fluid we solve transport of temperature and 12 chemical species, giving us a fluid composition at every node in the model. We then use iphreeqc to calculate the mineral saturation indices for minerals in every node and we use these values as a proxy for reaction localization. In order to better understand the effects of fluid mixing on mineralization we specifically look at the saturation index of Baryte, which is a mineral in the investigated system that only precipitates when elements of both fluids are present. Our simulations show that the saturation index of Baryte is at a maximum in a fluid comprising 90 to 80 percent of pore fluid and 10 to 20 percent of metal rich fluid. During the infiltration into the permeable faults, the metal rich fluid pushes the pore fluid away, and mixing is occurring at the interface between the two fluids and is driven mainly by diffusion. With temperature diffusion being three orders of magnitude faster than matter diffusion, the temperature is negligible for the mixing, which is only driven by matter diffusion at the model scale.

We will show that two types of reactive waves with high saturation indices of Baryte develop in the system: travelling and stable waves. Traveling waves progress during advection through the permeable faults and layers and are potentially too fast for minerals to precipitate. Therefore, these areas probably remain permeable in a natural system during advection dominated transport. In contrast, areas with low fluid velocities, and hence low advection, are diffusion dominated with reaction waves that are stable over a long time. These areas are prone for mineral reactions, because there is enough time for the reactions to take place. Stable reactive waves and thus areas of mineralization are fault walls, areas below seals, and areas between two faults where fluid velocities are diverging. We discuss the implications of our results in light of hydrothermal mineral systems.

How to cite: Koehn, D., Ulrich, K., Toussaint, R., Mullen, G., and Boyce, A.: The role of stable and traveling reactive waves in mineralization, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10265, https://doi.org/10.5194/egusphere-egu22-10265, 2022.

EGU22-10527 | Presentations | GMPV6.4

What control hydrothermal dolomitization? Experimental replacement with time-step monitoring by X-ray microtomography 

Benjamin Lefeuvre, Nicolas Beaudoin, Stephen Centrella, and Jean-Paul Callot

Hydrothermal dolomitization of limestones, i.e. fluid-mediated stoichiometric substitution Casolid ↔ Mgfluid replacing CaCO3 with dolomite CaMg(CO3)2, plays a key role in the structural integrity and permeability of the rock that can have dramatic consequences for earthquake hazards, reservoir quality, civil engineering. This particular reaction creates km-scale geobodies usually related to ore deposits or hydrocarbons, and being very efficient bodies for carbon sequestration. As for numerous hydrothermal reactions, various chemo-physical models built from chemical analysis and experiments in analogous replacement compete to explain this mineralogical transformation. Yet, relevant comparison to natural systems remains limited, and the way to explain the creation of large dolomite geobodies remains unexplained. Only recently dolomitization has been successfully recreated in laboratory under a reasonable timescale [1, 2], a few hours to a week according to the fluid reactivity.

This project proposes to use non-destructive imagery methods (xCT) coupled with hydrothermal reactors to reproduce dolomitization in-situ. We choose to study two natural samples representing two end-members: (1) Carrara marble which contains homogeneous polymineralic calcite grains; (2) Layens limestones (French Pyrenees) which is a marble already dolomitized naturally. These two samples were incubated in hydrothermal Teflon reactors in a Mg-enriched aqueous solution [3] at 200°C for different time steps. Microtomography have been acquired at various stages of the reaction, allowing us to track the propagation of the dolomitization front within the samples. This approach allows us to mimic natural dolomitization over time and provides a detailed study of the morphology of the reaction front between calcite and dolomite. Quantifying and describing the microstructures related to replacements (pores, fractures, grains orientation and size) help unravelling how dolomitization can propagate in nature.

 

 

References

[1] L. Jonas, T. Müller, R. Dohmen, L. Baumgartner, B. Pultlitz, Geology (2015)

[2] J. Weber, M. Cheshire, M. Bleuel, D. Mildner, Y-J. Chang, A. Ievlev, K. Littrell, J. Ilavsky, A. Stack, L. Anovitz, Geochimica et Cosmochimica Acta 303 (2021)

[3] V. Vandeginste, O. Snell, M. Hall, E. Steer, A. Vandeginste, Nature communications (2019)

How to cite: Lefeuvre, B., Beaudoin, N., Centrella, S., and Callot, J.-P.: What control hydrothermal dolomitization? Experimental replacement with time-step monitoring by X-ray microtomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10527, https://doi.org/10.5194/egusphere-egu22-10527, 2022.

EGU22-10618 | Presentations | GMPV6.4

Sulfur and strontium isotopic geochemistry of the crust-mantle transition of the Oman Ophiolite: records of fluid circulation 

Ana P. Jesus, Harald Strauss, Mathieu Benoit, Mathieu Rospabé, Georges Ceuleneer, Mário Abel Gonçalves, and Delphine Bosch

The Samail ophiolite in Oman was sampled by scientific drilling targeting crucial sections of the oceanic crust and mantle during the Oman Drilling Project- OmanDP [1]. Drillhole CM1A aimed at characterizing the transition from the lower crust to the mantle Moho Transition Zone (MTZ), where both magmatic and hydrothermal exchanges took place. Four magmatic sequences were defined: SI- Layered Gabbro, with thin wehrlite and dunite layers (1.5-160.2 m); SII- fully serpentinized Dunite (160.2-250.0 m); SIII- Dunite with rodingitized gabbro (250.0-311.0 m) and; SIV- Mantle, harzburgite with opx-dunite levels (311.0-404.2 m).

We present a sulfur and Sr isotope profile to characterize the sulfur cycling during hydrothermal alteration within the MTZ (SI-SIII). Acid Volatile Sulfides (AVS), Cr-Reducible Sulfur (CRS) and acid-soluble sulfate (SO4) were sequentially extracted and analyzed for δ34S on the same whole-rock powders analyzed for Sr isotopes.

The crust-mantle transition records extreme and often decoupled variations in sulfur (δ34S=-25.8 to +56.9‰) and 87Sr/86Sr (0.703088-0.711688) signatures. Total extracted sulfur from sulfide (TS=AVS+CRS) contents increase gradually from the top to the bottom of SI from ca ~65-2820 ppm, to maximum of 5043 ppm in a Cpx-Pl-dunite layer ca. 16 m above SII. Sulfide assemblages comprises magmatic pyrrhotite+pentlandite+chalcopyrite and secondary pyrrhotite (in Fe-serpentine pseudomorphs)+bornite+cubanite+millerite+sphalerite±haezlewoodite. Excluding one dunite layer with δ34SAVS=+11.4‰, the δ34SAVS,CRS (-0.6 to +3.3‰) for SI are close to slightly elevated relative to mantle values. Scarce sulfates have identical δ34S relative to coexisting sulfides implying formation via abiotic oxidation of precursor sulfides. Despite widespread background alteration, olivine gabbros preserve primitive 87Sr/86Sr ratios (0.703088-0.703332) whereas serpentinised ultramafic layers have significantly more radiogenic signatures (0.707817-0.711688), close to or above Cretaceous seawater (87Sr/86Sr=0.70745). Gradual enrichment in sulfides by magmatic processes in SI, towards the MTZ, was followed by hydrothermal alteration with minor incorporation of seawater sulfate, leading to highly decoupled Sr-34S enrichment in the ultramafic layers due to their Sr-depleted nature. Narrow pegmatoid dikelets (amphibole+zoisite+prehnite+titanite) within SI have low TS (<80 ppm), mildly radiogenic 87Sr/86Sr (<0.704923) and a fracture-hosted, higher fS2sulfide assemblage (pyrite+Co-pentlandite+siegenite) with δ34SCRS down to -25.8‰ implying low-T (<110 C), open-system bacterial sulfate reduction (BSR) processes.

The Dunite Sequence-SII has decreasing TS towards its interior (2-1253 ppm), consistent with extensive desulfurization producing an assemblage (awaruite+pentlandite+Co-pentlandite+magnetite, coexisting with brucite), during extremely low oxygen and sulfur fugacities typical of early serpentinization stages. SIII is highly heterogenous and S-depleted (3-623 ppm), with a heazlewoodite-bearing assemblage and lower 87Sr/86Sr (0.703952) relative to SII dunites (0.707065). The MTZ upper limit (SII) marks the onset of large shifts in S-isotopic composition, tendentially increasing downward throughout SII (δ34SCRS=-2.5, +15.6‰; δ34SSO4=+19.2, +32.4‰) and SIII (δ34SCRS=+1.4, +56.9‰; δ34SSO4=+19.4, +36.5‰). The occurrence of both sulfides and sulfates with δ34S above Cretaceous seawater sulfate (~18‰) can be explained by input of fluids at the top of SII which composition progressed towards extreme heavy values via closed system BSR during multi-staged serpentinization events.

AJ acknowledges WWU International Visiting Scholars and EU-H2020 Marie Sklodowska-Curie #894599 Fellowships, FCT-project UIDB/GEO/50019/2020 

[1] Kelemen PB, Matter JM, Teagle DAH, Coggon JA, OmanDP Science Team (2020) Proceedings of the OmanDP: College Station, TX (IODP).

How to cite: Jesus, A. P., Strauss, H., Benoit, M., Rospabé, M., Ceuleneer, G., Gonçalves, M. A., and Bosch, D.: Sulfur and strontium isotopic geochemistry of the crust-mantle transition of the Oman Ophiolite: records of fluid circulation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10618, https://doi.org/10.5194/egusphere-egu22-10618, 2022.

EGU22-11236 | Presentations | GMPV6.4

Fracture, mechanics and chemistry: Intermittency and avalanche statistics in thermally activated creeping crack fronts along disordered interfaces 

Renaud Toussaint, Tom Vincent-Dospital, Alain Cochard, Stéphane Santucci, and Knut Jørgen Måløy

We propose a subcritical fracture growth model, coupled with the elastic redistribution of the acting mechanical stress along rugous rupture fronts. We show the ability of this model to quantitatively reproduce the intermittent dynamics of cracks propagating along weak disordered interfaces [1]. We assume that the fracture energy of such interfaces (in the sense of a critical energy release rate) follows a spatially correlated normal distribution. We compare various statistical features from the obtained fracture dynamics to that from experimental cracks propagating in sintered polymethylmethacrylate (PMMA) interfaces. In previous works, it has been demonstrated that such approach could reproduce the mean advance of fractures and their local front velocity distribution. Here, we go further by showing that the proposed model also quantitatively accounts for the complex self-affine scaling morphology of crack fronts and their temporal evolution, for the spatial and temporal correlations of the local velocity fields and for the avalanches size distribution of the intermittent growth dynamics. We thus provide new evidence that Arrhenius-like subcritical growth laws are particularly suitable for the description of creeping cracks.

Reference:

[1] Vincent-Dospital, T., Cochard, A., Santucci, S., Måløy, K.J., Toussaint, R.,  Thermally activated intermittent dynamics of creeping crack fronts along disordered interfaces. Sci Rep 11, 20418 (2021). https://doi.org/10.1038/s41598-021-98556-x

How to cite: Toussaint, R., Vincent-Dospital, T., Cochard, A., Santucci, S., and Måløy, K. J.: Fracture, mechanics and chemistry: Intermittency and avalanche statistics in thermally activated creeping crack fronts along disordered interfaces, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11236, https://doi.org/10.5194/egusphere-egu22-11236, 2022.

EGU22-12060 | Presentations | GMPV6.4

Nanoscale observations of periclase (MgO) hydration 

Encarnacion Ruiz-Agudo, Cristina Ruiz-Agudo, Concepción Lázaro-Calisalvo, Pedro Álvarez-Lloret, and Carlos Rodríguez-Navarro

Hydration of anhydrous minerals such as periclase (MgO) is a common process during retrograde metamorphism (mainly serpentinization) and, generally, during fluid-rock interactions. Changes in mineralogy due to hydration reactions may have an impact on rock properties (Kuleci et al. 2016) and implications for the rheology of the crustal rocks (Yardley et al., 2014). Also, the hydration of periclase is an important industrial reaction, particularly in the field of cement and lime mortars. Dolomitic lime used for building purposes contains significant amounts of periclase, which hydrates at a slower rate than lime (CaO), and commonly delayed MgO hydration and swelling occurs in hardened mortar eventually resulting in fracture formation (Jug et al. 2007). It also negatively impacts the durability of MgO-based refractory ceramics (Amaral et al., 2011). Hydration of periclase involves a volume increase of ~110%, resulting in very high stresses if the process occurs in a confined space, which can lead to reaction-induced fracturing of crustal rocks (Zheng et al., 2018). Hence, understanding the mechanisms of periclase hydration is crucial for technical applications, such as avoiding dolomitic lime mortars fracturing due to swelling, and for understanding the feedback between hydration and rock properties in nature.

 

The hydration of periclase to brucite was investigated experimentally. Here we show, using in situ atomic force microscopy (AFM) and complementary techniques, that upon the reaction of periclase cleavage surfaces with deionized water, spherical nanoparticles form initially oriented along the periclase step edges, subsequently covering the whole periclase surface. With increasing reaction time, nanoparticles develop straight facets and acquire hexagonal features consistent with the structure of brucite. Additionally, differences in adhesion between the outer part and the centre of the nanoparticles were observed, suggesting the initial formation of a precursor (possibly amorphous) that subsequently transforms into crystalline brucite. These results reveal a nonclassical particle-mediated reaction mechanism for the hydration of periclase into brucite.

 

Amaral, L. F., Oliveira, I. R., Bonadia, P., Salomão, R., & Pandolfelli, V. C. (2011). Chelants to inhibit magnesia (MgO) hydration. Ceramics International, 37(5), 1537-1542.

Jug K, Heidberg B, Bredow T (2007) Cyclic cluster study on the formation of brucite from periclase and water. J Phys Chem C 111(35):13,103–13,108

Kuleci, H., Schmidt, C., Rybacki, E., Petrishcheva, E., & Abart, R. (2016). Hydration of periclase at 350 °C to 620 °C and 200 MPa: Experimental calibration of reaction rate. Mineralogy and Petrology, 110(1), 1–10.

Yardley, B.W.D., Rhede, D., Heinrich, W.,  (2014). Rates of Retrograde Metamorphism and Their Implications for the Rheology of the Crust: An Experimental Study. Journal of Petrology, 55, (3), 623-641.

Zheng, X., Cordonnier, B., Zhu, W., Renard, F., & Jamtveit, B. (2018). Effects of confinement on reaction‐induced fracturing during hydration of periclase. Geochemistry, Geophysics, Geosystems., 19, 2661–2672.

 

How to cite: Ruiz-Agudo, E., Ruiz-Agudo, C., Lázaro-Calisalvo, C., Álvarez-Lloret, P., and Rodríguez-Navarro, C.: Nanoscale observations of periclase (MgO) hydration, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12060, https://doi.org/10.5194/egusphere-egu22-12060, 2022.

First 40Ar/39Ar isotopic age data for gold hydrothermal veinlet-vein mineralization of the late Mesozoic Ketkap-Yuna igneous province (KYuIP) of the Aldan shield (AS) confirm the geological relation of this type of mineralization with the early Cretaceous sub-alkali magmatism. The combination of geological characteristics and U-Pb dating of magmatites indirectly enabled us to determine the age and highly productive bi-metasomatic «massif-skarn» type of mineralization associated with sub-alkali magmatogenic formations of the province.

Isotopic datings of magmatites and gold mineralization of the KYuIP and other late Mesozoic igneous provinces of the Aldan shield show age conformity of ore-bearing magmatites and ores accompanying them (fig. 1, 2). A relative, in comparison to provinces of the tectonic-magmatic activation (TMA) of the Western and Central Aldan, delay in time of occurrences of the KYuIP late Mesozoic magmatism and gold mineralization related to it, and the difference in volume ratios of formational types of magmatic formations in different provinces can be explained by the characteristics of tectonic structure of the region.

We have distinguished two large areas of the late Mesozoic TMA of the AS differing in the timing of polyformational magmatism and concomitant mineralization of different types, and in dominating formational type of magmatites: Western–Central-Aldan on the one hand, and Eastern-Aldan on the other (fig. 1-3). The first is characterized by a long-term development of magmatic activity from the Berriasian to the early Albian (≈ 30 Ma), and prevalence of leucitite–alkali(foid)-syenite formation; the second is characterized by occurrences of magmatism in a period twice as smaller (≈ 15 Ma), and domination of subalkaline diorite-granodiorite-granite formation.

The termination of the late Mesozoic magmatism in both areas was sub synchronous. The “set” of magmatogenic formations within them is also similar: leucitite–alkali(foid)-syenite with alkali granites, monzonite(subalkaline shonkinite)-syenite and subalkaline diorite-granodiorite-granite. A typical feature of the Eastern-Aldan area of the TMA consists in Coniacian-Santonian burst of alkali volcanoplutonism, which manifested in the KYuIP after a long (about 30 Ma) period of amagmatism.

 

How to cite: Polin, V., Zvereva, N., Travin, A., and Ponomarchuk, A.: Ketkap-Yuna igneous province gold mineralization age, ore-bearing complexes formational types, and different occurrence time of the late Mesozoic magmatism in different parts of the Aldan shield, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-163, https://doi.org/10.5194/egusphere-egu22-163, 2022.

The results of studying the granulite belts of the Earth show the presence of two types of granulite metamorphism in them: high-pressure and high-temperature ones.

     High-pressure granulites are characterized by P-T trends in the form of clockwise curves. According to widespread opinion,  the granulite metamorphism with such trends characterizes the areas that were formed as a result of the tectonic thickening of the crust due to continent-continent collisions that correspond to the model of the Himalayan type.

     High-temperature granulites are characterized by counterclockwise trends. For the formation of such granulites, researchers involve the mechanism of mantle underplating or the introduction of large volumes of intrusions under stretching. This model requires a mantle plume, which transports hot mantle material to the base of the crust.

  Thus, granulites with contrasting P-T trends, "orogenic" and "anorogenic" may be present inside the same belt. High-temperature granulites are superimposed on the dominant high-pressure ones. The time interval between these discrete events is not clearly defined and can be estimated in several tens of millions of years.

      Let's consider these two types of metamorphism against the background of the events of the supercontinental cycle (SC). Its structure consists of two stages: proper-continental (one continent-one ocean) and intercontinental (several continents-several oceans). In turn, the stages divide into phases. The first agglomeration phase of the proper-continental stage is characterized by compaction of already collected continental fragments. After the supercontinental culmination, the next, destruction phase begins, which precedes and prepares the break-up of the supercontinent. Its main content is continental rifting and the formation of the basic intrusions. The content of the first phase of the second stage consists of the break-up of the supercontinent, the formation of spreading zones and passive margins of young oceans. The next convergent phase of this stage is the assembly of the new supercontinent, the formation of subduction zones and the closure of young oceans as a result of numerous collisions.

     Based on the collision model of high-pressure granulite metamorphism, it is obvious that its formation will occur in this convergent phase of the SC, when, as a result of continent-continent collisions, a new supercontinent is assembled.

     Conditions for high-temperature granulite metamorphism in a tension environment arise in the phases of destruction and break-up of this supercontinent when plume processes are actively manifested as a result of the heat blanket effect.

      The analysis of the modern world factual material on supercontinental cyclicity for 3 billion years of the Earth history, conducted by the author, generally confirms the above correlation of the evolution of metamorphism during the development of granulite belts with events of SC.

Thus, these two types of granulite metamorphism, which fit into the structure of the super continental cycle, are indicators of geodynamic conditions of the corresponding stages and phases of the SC and show a complex interaction in the course of their manifestation of two geodynamic styles - the tectonics of lithospheric plates and mantle plumes.

 

How to cite: Bozhko, N.: On the manifestation of two types of granulite metamorphism during supercontinental cyclicity, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-362, https://doi.org/10.5194/egusphere-egu22-362, 2022.

EGU22-379 | Presentations | GD2.4 | Highlight

Sulfide inclusions in alkali basalt-associated garnet megacrysts shed light on the mysterious megacryst nature 

Anna Aseeva, Aleksandr Ignatyev, Aleksandr Karabtsov, Aleksey Ruslan, Anton Sinev, Tatyana Velivetskaya, Sergey Vysotskiy, and Maria Ushkova

We have carefully studied an unusual sulfide-bearing garnet megacryst from the ever-surprising Cenozoic Shavaryn-Tsaram basaltic cone (Tariat Platou, Mongolia). Similar sulfide inclusions in minerals constituting mantle xenoliths and clinopyroxene megacrysts related to alkali basalts were already known (Peterson and Francis, 1977, Chaussidon et al, 1989, Ionov et al, 1992) but they have never been found in garnet megacrysts. Since these garnets are believed to be mantle-derived material, their sulfide inclusions provide information on the deep sulfur cycle.

The sulfide-rich garnet megacryst from Shavaryn Tsaram pyroclastic strata is a chip of a large (up to 3 cm) cracked and partly quenched glassy crystal (fig. 1A, fig.1B) with melt pockets (Aseeva et al, 2021) inside (fig. 1C).

 

Sulfide inclusions are primary, isometric, elongated, and orientated towards crystal growth with a distinctive arrangement (3D X-ray images, Skyscane, fig. 2A). Swarms of inclusions contour the growth planes typical for the deltoidal icositetrahedron (fig. 2B).

Sulfide inclusions mainly consist of Ni-bearing pyrrhotite (1.66-2), scarce chalcopyrite (fig.3A and B), and rarely of pentlandite. Incompletely crystallized droplets of MSS (monosulfide solid solution) occur periodically as thin crystal pyrrhotite and pentlandite intergrowths (fig. 3C). These MSS inclusions are thought to be a product of the sulfide melt exsolution caused by undercooling (Chaudison et all, 1989).

The multi-isotope sulfur composition of these sulfide inclusions has been studied to define whether the sulfur source is crustal or mantle-derived. Thus, their δ34S values account for 0.2-0.4‰, δ33S for 0.1-0.2‰, and Δ33S for 0.00-0.03‰, which is characteristic of mantle, meteoric, MORB, and volcanic settings. As for the host garnet, its oxygen isotope composition (Δ18О 5.4 to 5.8‰) also suggests the volcanic origin of these sulfides.

Submicron surface analysis (Bruker Dimension Icon and Solver NT-MDT) reveals the linear-globular structure of garnet (fig. 4A). Being probable nuclei, nearly 1 μm globules compose layers of garnet. We assume that garnet crystal formed via epitaxial growth from the gas phase. Garnet megacryst linear structures consisting of globules differ significantly from the metamorphic garnet crystal lattice (fig. 4B). Sulfur redundancy causes sulfide droplets, immiscible with silicate material (fig. 4C), to gather and form bulbs on top of a growing crystal due to surface tension (fig. 4C). 

The following conclusions may be drawn: 1. Sulfide inclusions in alkali basalt-associated garnet megacrysts are primary. 2. Sulfides hosted in garnet are mantle-derived according to isotopic data. 3. Garnet megacryst formation was caused by epitaxial growth.

How to cite: Aseeva, A., Ignatyev, A., Karabtsov, A., Ruslan, A., Sinev, A., Velivetskaya, T., Vysotskiy, S., and Ushkova, M.: Sulfide inclusions in alkali basalt-associated garnet megacrysts shed light on the mysterious megacryst nature, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-379, https://doi.org/10.5194/egusphere-egu22-379, 2022.

EGU22-516 | Presentations | GD2.4 | Highlight

A relatively pristine C-like component in the eastern Anatolian asthenosphere 

Alican Aktağ, Kaan Sayit, Bradley J. Peters, Tanya Furman, and Jörg Rickli

Eastern Anatolia (Eastern Turkey) resides in the Alpine-Himalayan orogenic belt and hosts the Eastern Anatolian Volcanic Province (EAVP), one of the volumetrically most important volcanic provinces within the circum-Mediterranean region. Previous studies have revealed that the predominant portion of EAVP is composed of the products of the sub-continental lithospheric mantle (SCLM) metasomatized during subduction of the Neo-Tethyan slab. The wide distribution of the lithospheric signatures in EAVP lavas has led to the availability of a large number of geochemical information regarding the regional SCLM in eastern Anatolia. In contrast, the nature of the asthenospheric mantle of eastern Anatolia remains poorly constrained due to scarcity of the asthenosphere-derived melts and lack of detailed information on the source components it comprises. Hence, this study aims primarily to put constraints on the chemical nature of asthenosphere beneath eastern Anatolia by a detailed characterization of its end-members.  

In this study, we provide new trace element and Sr-Nd-Hf-Pb isotope data from Quaternary Elazığ volcanism. This volcanism, entirely represented by mafic alkaline basaltic rocks, is one of the most recent members of EAVP, and its chemistry provides compelling evidence for a predominate asthenosphere origin. Modellings suggest that these mafic volcanics are largely free of crustal assimilation; their geochemical signatures, hence, closely reflect their source regions. Their trace element and Sr-Nd-Hf-Pb isotope systematics are consistent with derivation from an asthenospheric mantle source domain containing approximately 70% recycled oceanic lithologies with the characteristics of the C-like mantle component. However, minor contributions from depleted component (DM; ca. 20%) and an enriched component representing metasomatically modified SCLM (ca. 10%) are also needed to explain their total range of isotope data. With these findings, we propose that the C-like material is dispersed within the asthenosphere, and has mixed with the depleted mantle matrix beneath eastern Anatolia. The SCLM domains, on the other hand, occur as detached pods, following the lithospheric delamination in the region. Having triggered by the extensional dynamics during Quaternary, upwelling of the hot asthenosphere resulted in the melting of the C-DM and SCLM domains. Subsequently, the C-DM melts interacted with the SCLM-type melts, eventually generating the Elazığ volcanism.

How to cite: Aktağ, A., Sayit, K., Peters, B. J., Furman, T., and Rickli, J.: A relatively pristine C-like component in the eastern Anatolian asthenosphere, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-516, https://doi.org/10.5194/egusphere-egu22-516, 2022.

Most researchers believe that large igneous provinces (LIPs) are formed by adiabatic melting of heads of ascending mantle plumes. Because the LIPs have existed throughout the geological history of the Earth (Ernst, 2014), their rocks can be used to probe the plume composition and to decipher the evolution of deep-seated processes in the Earth’s interior.

The early stages of the LIPs evolution are discussed by the example of the eastern Fennoscandian Shield, where three major LIP types successively changed each other during the early Precambrian: (1) Archean LIP composed mainly of komatiite-basaltic series, (2) Early Paleoproterozoic LIP made up mainly of siliceous high-Mg series, and (3) Mid-Paleoproterozoic LIP composed of picrites and basalts similar to the Phanerozoic LIPs (Sharkov, Bogina, 2009). The two former types of LIPs derived from high-Mg depleted ultramafic material practically were extinct after the Mid-Paleoproterozoic, whereas the third type is survived till now without essential change. The magmas of this LIP sharply differed in composition. Like in Phanerozoic LIPs, they were close to E-MORB and OIB and characterized by the elevated and high contents of Fe, Ti, P, alkalis, LREE, and other incompatible elements (Zr, Ba, Nb, Ta, etc.), which are typical of geochemically enriched plume sources.

According to modern paradigm (Maruyama, 1994; Dobretsov, 2010; French, Romanowiсz, 2015, etc.), formation of such LIPs is related to the ascending thermochemical mantle plumes, generated at the mantle-liquid core boundary due to the percolation of the core’s fluids into overlying mantle. Thus, these plumes contain two types of material, which provide two-stage melting of the plume’s heads: adiabatic and fluid-assisted incongruent melting of peridotites of upper cooled margins (Sharkov et al., 2017).

These data indicate that the modern setting in the Earth’s interior has existed since the Mid Paleoproterozoic (~2.3 Ga) and was sharply different at the early stages of the Earth’s evolution. What was happened in the Mid Paleoproterozoic? Why thermochemical plumes appeared only at the middle stages of the Earth’s evolution? It is not clear yet. We suggest that this could be caused by the involvement of primordial core material in the terrestrial tectonomagmatic processes.  This core survived from the Earth’s heterogeneous accretion owing to its gradual centripetal warming accompanied by cooling of outer shells (Sharkov, Bogatikov, 2010).

References

Dobretsov, N.L. (2008). Geological implications of the thermochemical plume model. Russian Geology and Geophysics, 49 (7), 441-454.

Ernst, R.E. (2014). Large Igneous Provinces. Cambridge Univ. Press, Cambridge, 653 p.

French, S.W., Romanowicz, B. (2015). Broad plumes rooted at the base of the Earth’s mantle beneath major hotspots. Nature, 525, 95-99.

Maruyama, S. (1994). Plume tectonics. Journal of Geological Society of Japan, 100, 24-49.

Sharkov, E.V., Bogina, M.M. (2009). Mafic-ultramafic magmatism of the Early Precambrian (from the Archean to Paleoproterozoic). Stratigraphy and Geological Correlation, 17, 117-136.

Sharkov, E.V., Bogatikov, O.A. (2010). Tectonomagmatic evolution of the Earth and Moon // Geotectonics 44(2), 83-101.

Sharkov, E., Bogina, M., Chistyakov, A. (2017). Magmatic systems of large continental igneous provinces. Geoscience Frontiers 8(4), 621-640

How to cite: Sharkov, E.: The Late Cenozoic global activation of tectonomagmatic processes as a result of physico-chemical processes in the solidifying Earth’s core?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-968, https://doi.org/10.5194/egusphere-egu22-968, 2022.

EGU22-1176 | Presentations | GD2.4

The multistage metasomatized mantle beneath Alakit: evidence from mantle xenoliths from Komsomolskaya kimberlite pipe, Yakutia, stages of mantle evolution 

Igor Ashchepkov, Theodoros Ntaflos, Nikolai Medvedev, Denis Yudin, Igor Makovchuk, and Ravil Salikhov

More than 200 metasomatised peridotite xenoliths containing phlogopite, amphibole and ilmenite from the Komsomolskaya pipe are garnet and spinel harzburgites or dunites, and clinopyroxene-enriched lherzolites with garnets (up to 12.5 wt.% Cr2O3) and clinopyroxenes (up to 5 wt.% Na2O). Low-Cr varieties are Fe-enriched pyroxenites, phlogopite metasomatic veins and type A, B eclogites. Minerals were studied by electron microprobe and LA-ICP-MS which revealed their geochemical groupings and their distribution in the mantle section.

     Results indicate that the lithospheric mantle beneath the Komsomolskaya pipe is layered and relatively heated. Heated peridotites at the lithosphere base (7-6 GPa) are enriched in Fe and are porphyroclastic, deformed types and rare polymict breccias. The cold group at 6.0-5.5 GPa (34 mW/m2) are depleted peridotites with sub-Ca garnets. Cpx-fertilized varieties belong to the middle part of the mantle section. Amphiboles range from Cr-hornblendes to edenites (2-6 GPa), showing K-Ti enrichment. Picroilmenites yield two pressure intervals from 6.5 to 5.0 GPa and from 5.0 to 4.0 GPa, forming two differentiation branches. Eclogites are mainly related to the lower part of the section with a peak at pressures of 4-6 GPa.

Trace elements of melts that formed harburgitic garnets-pyroxenes rever to oceanic MORB like melt interaction with peridotites. The subcalcic S-type garnets are similar to subduction-related melts (S-type REE) with troughs in HFSE. Adakite-like hybrid metasomatism formed Na, Al-rich pyroxenes with peaks in Sr and HFSE. K-bearing pyroxenes and amphiboles refer to shoshonitic metasomatism.

Trace elements for Cpx of re-fertilized mantle peridotites have high LREE, Nb-Ta troughs and peaks in Zr, Th, Sr, U and are related to carbonatite –alkaline melts. Protokimberlite (essentially carbonatitic) interaction produced HFSE-enrichment. Type B eclogites show more subduction-related features with HFSE troughs while type A eclogites are closer to hybrid and peridotitic signatures. We suggest six types of major metasomatic agents.  The 40Ar/39Ar ages of phlogopites are in the 440-690 Ma range, with some at 1.6 Ga, suggesting multistage metasomatism.  Supported by  RFBR grant 19-05-00788

 

 

 

How to cite: Ashchepkov, I., Ntaflos, T., Medvedev, N., Yudin, D., Makovchuk, I., and Salikhov, R.: The multistage metasomatized mantle beneath Alakit: evidence from mantle xenoliths from Komsomolskaya kimberlite pipe, Yakutia, stages of mantle evolution, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1176, https://doi.org/10.5194/egusphere-egu22-1176, 2022.

EGU22-1260 | Presentations | GD2.4 | Highlight

Manifestation of various stages PGE mineralization in the different locations Ospa-Kitoy ophiolite massif (East Sayan, Russia). 

Olga Kiseleva, Evgeniya Ayriants, Dmitriy Belyanin, and Sergey Zhmodik

A study of chrome-spinels and PGE mineralization (PGM) from the podiform chromitites has been carried out on the area of four locations of the Ospa-Kitoy ophiolite massif (northern and southern branches East Sayan ophiolite). It has been established that different PGM assemblages formed at different stages of formation of the Ospa-Kitoy ophiolite massif, at various temperature and fluid regimes, are present at four sites. The chromite pods show both disseminated and massive structures. There are veins of massive chromitites, 0.01-0.5 m thick and 1-10 m long, rarely disseminated, schlieren, and rhythmically banded ores, which are discordant to the host ultramafic rocks. (Os-Ir-Ru) alloys occur as inclusions in the Cr-spinel or intergrowth with them (fig 3a). In addition, FePt3 alloys are found in the PGM assemblage. In such grains, decomposition structures of solid solutions represented by osmium lamellas can be observed. Polyphase PGM assemblage: (Os, Ir, Ru), (Ni, Fe, Ir),  (Ir, Ru, Pt)AsS, CuIr2S4, (Os, Ru)As2, Rh-Sb,  PtCu, and Pd5Sb2 are localized in serpentine, in close association with sulfides, sulfoarsenides, arsenides of nickel.

Figure 1. Chromitite bodies and PGE mineralization in Ospa-Kitoy ophiolite massif: 1 – Harh mountain (north branch of the ophiolites); 2 –  lake Sekretnoye (apically Zun-Ospa river); 3 – stream Zmeevikovyi (south branch of the ophiolites); 4 – Harh-Ilchir site (south flank Harh mountain).

Figure 2. Composition of  Os-Ir-Ru alloys: 1 – Harh mountain, 2 – lake Sekretnoye site, 3 – stream Zmeevikovyi.

Based on chemical and microtextural features of the PGM´s and assemblage with magmatic and hydrothermal minerals in the chromitites, it is established that each studied location of chromitites at different stages of PGM formation are exhibited. High-temperature magmatic Os-Ir-Ru alloys are widely exhibited in the Harh and Zmeevikovyichromitites. In the Harh-Ilchir site, there is no magmatic PGM and are established sulfoarsenides and arsenides Ru, Ir, which are formed from the residual fluid phase in the late magmatic stage. Chromitites in the lake Sekretnoye MPG are contained high-temperature magmatic (Os-Ir-Ru) alloys, and there are signs of PGE remobilization with Os0 , Ru0 , (Ir-Ru) alloys. Remobilization processes during serpentinization and fluid interaction of peridotites and chromitites.

In addition, it should note that the PGM assemblage of the Zmeevikovyi and Harh-Ilchir locations has been undergone by influence metamorphogenic fluids with increased activity of O2, As, Sb. and these minerals can be formed directly in hypergenic environments. PGM҆'s such as (Ru, Rh, Pt)Sb, Rh-Sb were created at this stage.

Figure 3. BSE images of primary and secondary PGM: Harh location: а) individual grain of magmatic (Os-Ir-Ru) with microinclusion native Os; b) remobilized polyphase aggregate native Os, (Ir-Ru) (CuIr2S4); location Sekretnoye lake: с) inclusion magmatic (Os-Ir-Ru) in the chromite grain; d) remobilized polyphased aggregate (Ir-Ru), (Rh-Sb); location stream Zmeevikovyi: e) idiomorphic magmatic grain (Os-Ir) replaced by (Ir,Ru)AsS, with separation remobilized (Os,Ir);  Harh-Ilchir site: f) inclusion of Pd5Sb2 in the heazlewoodite (Hzl).

Analytics  made in Analytical Centre SB RAS. Supported by RFBR  19-05-00764а and  Russian Ministry of Education and Science.

 

 

How to cite: Kiseleva, O., Ayriants, E., Belyanin, D., and Zhmodik, S.: Manifestation of various stages PGE mineralization in the different locations Ospa-Kitoy ophiolite massif (East Sayan, Russia)., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1260, https://doi.org/10.5194/egusphere-egu22-1260, 2022.

EGU22-1306 | Presentations | GD2.4

Mantle transects in South and Central Africa according to data of mantle xenocrysts and diamond inclusions.   

Igor Ashchepkov, Vladimir Zinchenko, Alexander Ivanov, and Alla Logvinova

We designed the mantle transects using the PTXFO2 diagrams  (Ashchepkov et al., 2010; 2013; 2017) constructed (Fig. 1) for mantle columns beneath kimberlites of  Kaapvaal and the Congo-Kasai cratons.

The PTXFO2 diagrams (Ashchepkov et al., 2013) in South Africa were constructed using mainly analyses of garnets, eclogitic minerals and inclusions in diamonds in open publications. The sub-calcic type garnets mainly refer to the ancient low-temperature geotherms (35 mv/m2) and higher-temperature inclusions of eclogite-pyroxenite type, giving convective geotherms crossing conductive ones, which reflects the migration process of apparently hybrid melts. 

Roberts Victor is a Mesozoic pipe 95Ma  famous due to the abundance of various eclogite xenoliths. Many eclogites in the SCLM show P-Fe# trends that are typical of ascending and differentiating magmas. Such “basaltic eclogites” may show typical features of their magmatic origin (Fig.1A). They may create channels within the peridotitic lithosphere starting from the deep subduction stages.  These irregularities formed during subduction stages and due to later plumes could explain the irregular distribution of eclogites in kimberlite pipes and abundance in  Roberts Victor (Jacob et al., 2005; Huang et al., 2014) and practical absence in others.

 In the mantle of Luaxe and Cuilo pipes (Fig.1 B, C) the minerals give highly variable conditions representing the multistage metasomatic processes. The oxygen conditions are good for diamonds  The mantle column reveals a long ilmenite trend and the presence of abundant eclogites (Zinchenko et al., 2021; Nikitina et al., 2014; Ashchepkov et al., 2012).

In the sub-meridional mantle transect through the South Kaapvaal and Zimbabwe cratons, mainly dunitic at the basement ancient cores of cratons like in Lesotho and Central part of  Zimbabwe mantle is relatively depleted and low temperature.   In the marginal parts like near Premier pipe, Venetia in Limpopo and Orapa in Magondi belt the amount of the pyroxenitic and eclogitic materials drastically rises and the temperature regimes and oxidation state rise because these zones are more transparent for the melts. These zones are often highly diamondiferous and the largest diamonds are occurring in these regions and pipes (Fig. 2).

In the mantle section through the pipes of the so-called diamond-bearing corridor of the Lucapa within the northeastern part of the Congo craton (Fig. 3), the immersion of the least oxidized and more productive horizon represented mainly by depleted peridotite material and much less oxidized is gradually thinking and in the to the southwest is recorded in the lower part. The temperatures in the lower part are also decreasing. This determines the sharp increase in the diamond grades of kimberlite pipes in this direction. But commonly this transect represents a relatively smooth homogeneous structure, the lithosphere of the craton's mantle distinguishes outflow clusters corresponding to thickenings of pips and kimberlite clusters that have arisen within the limits of separately permeable zones that occur at the intersection of deep faults.

RFBR grant 19-05-00788.  Supported by Ministry of Science and Higher Education.

How to cite: Ashchepkov, I., Zinchenko, V., Ivanov, A., and Logvinova, A.: Mantle transects in South and Central Africa according to data of mantle xenocrysts and diamond inclusions.  , EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1306, https://doi.org/10.5194/egusphere-egu22-1306, 2022.

The system CaCO3-MgCO3 has been used since the '60s for reconstructing the petrogenesis of carbonated lithologies, notably of carbonatite magmas possibly generated in the Earth's mantle. Yet, experimental results at high temperatures and pressures remain contradictory, and a thermodynamic model for the carbonate liquid in this binary is still lacking.

We experimentally investigated the melting of aragonite and magnesite to pressures of 12 GPa, and of calcite-magnesite mixtures at 3 and 4.5 GPa, and at variable Mg/(Mg+Ca) (XMg). Results show that the melting of aragonite, and of magnesite have similar slopes, magnesite melting ≈ 30 °C higher than aragonite. The minimum on the liquidus surface is at XMg ≈ 0.35-0.40, 1200 °C at 3 GPa, and 1275 °C at 4.5 GPa, which, when combined with data from Byrnes and Wyllie (1981) and Müller et al. (2017), imply that minimum liquid composition remains approximately constant with pressure increase. We present the first thermodynamic model for CaCO3-MgCO3 liquids, retrieved from the experimental data available. Although carbonate liquids should be relatively simple molten salts, they display large non-ideality and a three-component (including a dolomite component), pressure dependent, asymmetric solution model is required to model the liquidus surface. Attempts to use an end-member two-component model fail, invariably generating a very wide magnesite-liquid loop, contrary to the experimental evidence.

The liquid model is used to evaluate results of experimentally determined phase relationships for carbonated peridotites modelled in CaO-MgO-SiO2-CO2 (CMS-CO2), and CaO-MgO-Al2O3-SiO2-CO2 (CMAS- CO2). Computations highlight that the liquid composition in the CMS-CO2 and CMAS-CO2 and in more complex systems do not represent "minimum melts" but are significantly more magnesian at high pressure, and that the pressure-temperature position of the solidus, as well as its dP/dT slope, depend on the bulk composition selected, unless truly invariant assemblages occur. Calculated phase relationships are somewhat dependent on the model selected for clinopyroxene, and to a lesser extent of garnet.

Byrnes A.P. and Wyllie P.J. (1981) Subsolidus and melting relations for the join CaCO3-MgCO3 at 10 kbar. Geochim. Cosmochim. Acta 45, 321-328

Müller I.A., Müller M. K., Rhede D., Wilke F.D.H. and Wirth R. (2017) Melting relations in the system CaCO3-MgCO3 at 6 GPa. Am. Mineral. 102, 2440-2449.

How to cite: Poli, S., Zhao, S., and Schmidt, M. W.: An experimental determination of the liquidus in the system CaCO3-MgCO3 and a thermodynamic analysis of the melting of carbonated mantle melting, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1531, https://doi.org/10.5194/egusphere-egu22-1531, 2022.

EGU22-1932 | Presentations | GD2.4

In situ low-degree melts in peridotite xenolith from Majuagaa kimberlite, West Greenland 

Ekaterina S. Kiseeva, Vadim S. Kamenetsky, and Troels F. D. Nielsen

Mantle xenoliths provide a clear evidence of interaction with low-degree mantle melts, however, this evidence is mostly geochemical, manifested by incompatible element enrichment, or mineralogical, manifested by already crystallised phases (e.g. amphibole, phlogopite) as a result of this interaction.

Despite decades of research, the composition of low-degree melts generated in lithospheric mantle are still not very well-known. In situ characterisation of such melts is hampered due to their modification during the ascent as well as rapid alteration and weathering at the surface, while experiments are hampered by difficulties to produce and analyse very low-degrees (<2-3%) melts.

In this study we report a rare sample of well-preserved low-degree melts within a peridotite xenolith GGU473178 from Majuagaa kimberlite in West Greenland. We report alkali-carbonatitic-chloride melt pools and veins that may represent primary low-degree partial melts and products of their in situ crystallisation.

Melt pools are largely composed of carbonate (predominantly dolomite) and contain spinel, apatite, phlogopite as well as minor amounts of Fe-Ni sulphides, barite and halite.

Euhedral crystals of spinel present in these melt pools contain large usually round aggregates of mineral inclusions, which we explain as former melt pools captures by spinel. Mineral assemblage found in these spinel inclusions is consistently composed of ferropericlase, dolomite, alkali-rich carbonate and apatite, which is indicative of a strongly silicate-undersaturated alkali-carbonatitic melt that contains chlorine and phosphorous. Due to the almost complete absence of SiO2, ferropericlase (instead of olivine) crystallises in equilibrium with dolomite and alkali-rich carbonate, implying incredibly low degrees of melting, when essentially only carbonated component is melted, or carbonate-silicate liquid immiscibility, previously reported for spinel lherzolite and garnet wehrlite xenoliths (Frezzotti et al., 2002; Soltys et al., 2016).

References

Frezzotti, M. L., Touret, J. L. R., and Neumann, E. R., 2002, Ephemeral carbonate melts in the upper mantle: carbonate-silicate immiscibility in microveins and inclusions within spinel peridotite xenoliths, La Gomera, Canary Islands: European Journal of Mineralogy, v. 14, no. 5, p. 891-904.

Soltys, A., Giuliani, A., Phillips, D., Kamenetsky, V. S., Maas, R., Woodhead, J., and Rodemann, T., 2016, In-situ assimilation of mantle minerals by kimberlitic magmas — Direct evidence from a garnet wehrlite xenolith entrained in the Bultfontein kimberlite (Kimberley, South Africa): Lithos, v. 256-257, p. 182-196.

How to cite: Kiseeva, E. S., Kamenetsky, V. S., and Nielsen, T. F. D.: In situ low-degree melts in peridotite xenolith from Majuagaa kimberlite, West Greenland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1932, https://doi.org/10.5194/egusphere-egu22-1932, 2022.

EGU22-2177 | Presentations | GD2.4

Ages of micas from xenoliths and xenocrysts of kimberlites of the Siberian Craton determined by 39Ar/40Ar method 

Denis Iudin, Igor Ashchepkov, and Alexei Travin

Plateaus and isochronous and integral ages of 39Ar/40Ar xenocrysts and phlogopite grains from kimberlite xenoliths can be used to determine the ages of mantle processes (Hopp et al., 2008) and decipher the genesis of diamond-forming processes. Dating of deep xenoliths of kimberlites of the Siberian craton reveals a significant spread (Pokhilenko et al., 2012; Ashchepkov et al., 2015) from the Archean to the time close to the age of the host kimberlites, mainly Devonian. The most ancient ages for Udachnaya Daldyn fields for phlogopites from xenoliths of spinel harzburgites of the highest level belong to the late Archean (2.6-2.0) - early Proterozoic 1.7 -1.5 Ga. In the Alakite field, all ages are younger from 1,87 – 1,05- 0,928 - 0,87 Ga and belong to the metasomatic history of the Rodinia continent mantle. Close dates are set for xenoliths from the Obnazhennaya pipe (Kalashnikova et al. 2017).

Fig.1 PT  Udachnaya pipe. Symbols: Op: ToC(Brey, Kohler, 1990)-P(GPa)(McGregor, 1974). Cpx: 2.ToC-P(GPa)(Nimis, Taylor, 2000); 3.ToC (Nimis, Taylor, 2000 with ed. author)–P(GPa)(Ashchepkov et al., 2011); 4. eclogites ; 5. inclusions in diamond; Gar: 6.ToC (O'Neill, Wood, 1979) -P(GPa) (Ashchepkov et al., 2010Gar), 7. For eclogite garnets Chromite: 8,  inclusions in diamond; 9. chromite ToC (O'Neill, Well, 1987)-P(GPa) (Ashchepkov et al., 2010Gar), 7. For eclogite garnets Chromite: 8, inclusions in diamond; 9. chromite ToC (O'Neill, Well, 1987)-P(GPa) (Ashchepkov et al ., 2010Chr); 10 the same for inclusions in diamond; 11. Film Tom (Taylor et al., 1998)- P(GPa) (Ashchepkov et al., 2010 ilm)

Our data on micas by the 39Ar/40Ar method often reveal complex configurations of spectra. The micas of the xenocrysts of the Alakite field give several peaks, ranging from the most high-temperature and ancient, which corresponded to the upper Proterozoic - Vendian and Paleozoic, and only the lowest temperature peaks with a high Ca/K ratio corresponded to the ages of kimberlite introduction. Some peaks may be associated with the thermal effects of the Vilyusky plume (Kuzmin et al., 2012). The lowest temperature peaks, which are close in age to the time of kimberlite formation, which is confirmed by the high 38Ar/39Ar ratios of the gas released at the low-temperature stage, can be used very approximately for dating kimberlites, however, the release of other gases at low-temperature stages significantly increases the measurement error. All of them correspond to the interval 440 -320 Ma. The pipes Mir, Internationalnaya, Ukrainianskaya - 420, Yubileynaya -342, Botuobinskaya -352 Ma). Some definitions practically coincide with Rb/Sr ages (Griffin et al., 1999, Agashev et al., 2005, Kostrovitsky et al., 2008; Zaitsev, Smelov, 2010) and probably represent mixing lines. For many xenocrysts (Feinsteinovskaya, Ukrainskaya, Yubileynaya, Krasnopresnenskaya tr.), the interval from 600 to 500 Ma is manifested, which corresponds to the stage of the Laurasia supercontinent breakdown. The presence of relatively low-temperature plateaus with ancient ages, and high-temperature young ones implies that some stages can be correlated with the mantle history of the mineral.  RFBR grant 19-05-00788.  Supported by Ministry of Science and Higher Education.

Fig.2 PT  Sytykanskaya pipe

How to cite: Iudin, D., Ashchepkov, I., and Travin, A.: Ages of micas from xenoliths and xenocrysts of kimberlites of the Siberian Craton determined by 39Ar/40Ar method, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2177, https://doi.org/10.5194/egusphere-egu22-2177, 2022.

EGU22-3014 | Presentations | GD2.4

Precise calculations of Nickel content in pyropes 

Alexandr Ivanov

The nickel content in pyropes interested researchers due to the possibility to create an algorithm for calculating the temperature boundaries of its joint crystallization with diamonds. Griffin proposed such a calculation algorithm, which was named the diamond-bearing corridor with his name [1]. Determination of nickel content in pyropes on microanalysts is difficult for several reasons. The first reason is the limit of detection of nickel in pyropes, which is very high for the determination of this element on electron microscopes (at least 15 ppm). And then, such an analysis is possible at a quantitative level with a probe beam current of 300nA and an analysis time of 3 minutes. The study of the correlation ratios of nickel with other elements in pyropes allowed us to determine two elements that have a significant correlation with the nickel content in pyropes - these are titanium and manganese and their content in pyropes is acceptable for quantitative determination. On the ion microanalyzer, more than two hundred analyses were performed for pyropes from the kimberlite pipes Botuobinskaya and Nyurbinskaya, the remaining determinations were made from kimberlites tr. Jubilee and tr. Victory with the use of a new technique for the determination of nickel in pyropes in the microanalyzer JXA-8230. In total, 443 definitions of nickel in pyropes were performed at the quantitative level. Such definitions made it possible to calculate the functional dependence of nickel contents on titanium and manganese contents. The STATISTICS program is used for such calculations (Fig. 1).

Fig. 1. Map of level lines (nickel manganese titanium for 443 definitions) with the calculation of functional dependence

The calculation of nickel contents in pyropes makes it possible to fully use the Griffin geothermometer to determine the number of pyrope grains from the diamond-bearing corridor area.

  • Griffin W.L., Ryan C.G. Trace elements in indicator minerals: Area selection and target evaluation in diamond exploration. J. Geochem. Explor., 1995. Vol. 53., pp, 311-357

How to cite: Ivanov, A.: Precise calculations of Nickel content in pyropes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3014, https://doi.org/10.5194/egusphere-egu22-3014, 2022.

EGU22-3284 | Presentations | GD2.4

Seismogenesis in granite under brittle-plastic transition condition 

Jae Hoon Kim and Jin-Han Ree

Most of earthquakes occur below 10-km depth in the Korean Peninsula. For example, the focal depth of the Mw 5.5 Gyeongju Earthquake in 2016, the largest instrumental earthquake in South Korea since scientific earthquake monitoring started in 1978, is about 14 km with hypocentral basement rocks of granitoid and temperature of 370°C (thus, brittle-plastic transition condition). A study on ancient granitoid shear zones with the similar temperature condition will aid in understanding the seismogenesis in the brittle- plastic transition regime. The Yecheon shear zone is an NE- to NNE-striking right-lateral shear zone cross-cutting Mesozoic granitoid belt in South Korea. The deformation temperature of the main shear zone was estimated to be about 350 ℃. In the southeastern margin of the shear zone, protomylonites change gradually into mylonites and then abruptly into ultramylonites toward southeast. Quartz and feldspar grains both of protomylonite and mylonite deform by dislocation creep and brittle fracturing, respectively. Greenish ultramylonite consists of quartz-, feldspar-, muscovite- and epidote-rich layers within matrix of quartz, muscovite and epidote. The protomylonite commonly displays a composite S-C foliation. The deflecting S-foliation of mylonite toward ultramylonite is sharply truncated by the boundary between mylonite and ultramylonite. Thin (several mm to several cm) greenish layers occur in protomylonite subparallel to mylonitic foliation or cross-cutting the foliation at a low angle. They also show injection structure with flow banding and cataclastic deformation along the protomylonite boundary. The greenish layer consists of fragments of protomylonite and matrix of very fine-grained quartz, feldspar, muscovite and epidote. Epidote grains of ultramylonite and greenish layers replace phengitic mica, biotite and plagioclase and show graphic texture. Together with epidote formation, chloritization of biotite and albitization of K-feldspar are prominent in the greenish layers. The growth of hydrothermal minerals including epidote and chlorite within the greenish layers and shear band along the C-foliation indicates fluid circulation in the layers. We interpret the greenish layers were generated during seismic events in fluid-rich conditions and thus seismic event may be caused by pore pressure build up. Once the greenish layers develop, deformation was localized along the layers due to much reduced grain size in interseismic periods, and the greenish layers became ultramylonite with further grain-size reduction.

How to cite: Kim, J. H. and Ree, J.-H.: Seismogenesis in granite under brittle-plastic transition condition, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3284, https://doi.org/10.5194/egusphere-egu22-3284, 2022.

EGU22-3326 | Presentations | GD2.4

Deep seismic reflection profile with big-size dynamite shots reveals Moho and mantle reflection: tracking continental evolution 

Mingrui Li, Rui Gao, Jianbo Zhou, Simon A Wilde, Hesheng Hou, Xiaomiao Tan, and Yanlin Zhu

The deep structure of orogenic belts and cratons has become an important part to track evolution and innovation of tectonics. The extremely thick crust and overlying deposition bring obstacles to the deep structure of the orogenic belt and ancient block. Deep seismic reflection profile is globally regarded as an advanced technology to perspective the fine structure of the crust and the top of the upper mantle, especially using large-size dynamite shots. In the 1990s, international scholars used deep seismic reflection profiles to find inclined reflections penetrating from the lower crust to the upper mantle (Calvert et al., 1995; Cook et al., 1999). They believe that these reflections are related to ancient subduction events(or fossil subduction). At the beginning of this century, Chinese scholars began to carry out similar experiments in the Tibet Plateau, Sichuan Basin and Songliao basin. Using big-size dynamite shots, they also found the Moho under the extremely thick crust of the Tibet Plateau and the mantle reflection under the ancient block (Gao et al., 2013, 2016; Zhang et al., 2015). In 2016, with the support of China Geological Survey Project,we arranged a seismic reflection profile around the Scientific Deep Drilling SK-2 Well in the middle of Songliao basin. According to the data processing results of all five big-size dynamite shots and four medium-size dynamite shots of the profile, we obtained a 127.3km long single-fold reflection profile, revealing the reflection characteristics of the lower crust, Moho and its upper mantle in the study area. The Moho structure distributed nearly horizontally at a depth of 33km (estimated by the average crustal velocity of 6km/s) is clearly obtained, and the mantle reflection extending obliquely from Moho to 80km-depth is found. We believe that this dipping mantle reflection represents an ancient subduction relic under the Songnen block.

 

Calvert, A. J., Sawyer, E. W., Davis, W. J., & Ludden, J. N.  Archaean subduction inferred from seismic images of a mantle suture in the Superior Province. Nature,1995, 375(6533), 670–674.

Cook,F. A., van der Velden, A. J., Hall, K. W., Roberts, B. J.Frozen subduction in Canada’s Northwest Territories: lithoprobe deep lithospheric reflection profiling of the western Canadian Shield. Tectonics 1999,18, 1–24.

Gao R, Chen C, Lu Z W, et al.New constraints on crustal structure an d Moho topography in Central Tibet revealed by SinoProbe deep seismic reflection profiling. Tectonophysics, 2013, 606:160 - 170.

Gao, R., Chen, C., Wang, H. Y., Lu, Z. W., et al.Sinoprobe deep reflection profile reveals a neo-Proterozoic subduction zone be neath Sichuan basin. Earth & Planetary Science Letters, 2016,454(18):86-91

Zhang, X. Z.,Zheng, Z.,Gao, R., et al. Deep reflection seismic section evidence of subduction collision between Jiamusi block and Songnen block. Journal of Geophysics, 2015,58 (12): 4415-4424

How to cite: Li, M., Gao, R., Zhou, J., Wilde, S. A., Hou, H., Tan, X., and Zhu, Y.: Deep seismic reflection profile with big-size dynamite shots reveals Moho and mantle reflection: tracking continental evolution, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3326, https://doi.org/10.5194/egusphere-egu22-3326, 2022.

EGU22-3368 | Presentations | GD2.4

Possible sources of the alluvial diamonds Udzha basin, northern Anabar region near kimberlite Tomtor field, Yakutia. 

Mikhail Vavilov, Valentine Afanasiev, Igor Ashchepkov, Leonid Baranov, and Egorova Vera

The NE of the Siberian platform in Udzha and Anabar river locate the richest alluvial placers of diamonds Since the discovery of placers > 700 were found, but no industrial bodies. A study of kimberlite magmatism has established that there are kimberlites of three ages on the territory of the North-East of the Siberian platform – middle Paleozoic (single), lower Triassic (few) and Jurassic-Cretaceous (prevailing). The latter are almost non-diamond-bearing.

The nearest kimberlite fields of Kuranakh and Tomtor are poor in diamonds. Some placers in the basin of the Udzha river, the right tributary of the Anabar, contain Cr-rich (≤14 wt.% Cr2O3) sub-calcic pyrope garnet associated with diamond. Comparison of kimberlite indicator minerals (KIMs) from the basins of Udzha and Chemara (its right tributary) shows similarity and a large diversity of pyropes, mostly of lherzolitic type. Cr- diopsides found in the Devonian collector suggest a close kimberlite source.

Mainly eclogitic placer diamonds are abundant in the upper reaches of the Chimara river in the northeastern part of the region. They occur in Permian, Jurassic, and Neogene rocks and in Quaternary alluvium where they coexist with pyrope and ilmenite. The diamonds in this region have mostly eclogitic features (Shatsky et al., 2015).

Reconstructions using monomineral thermobarometry (Ashchepkov et al., 2010) for the sources of pyrope and diamond show that the areas of the Anabar and Udzha placers share the similarity in the structure of mantle roots since 7.5 GPa, with a convective branch at the base.

The P-Fe trend for the Jurassic is slightly inclined, which is typical of the Kuranakh field. For the Devonian kimberlites, non-inclined trends are typical. The subcontinental lithospheric mantle (SCLM) beneath the Udzha basin is rich in pyroxenitic garnets as typical for the Anabar region.

There are 3 intermediate collectors of pyropes and associated diamonds: Permian, Jurassic and Neogenic and alluvium.  A study of the chemistry and thermobarometry of the kimberlite indicator minerals show some variations which possibly indicate different kimberlite sources ( Fig.1).

The detailed trace element geochemistry of the KIM from Udzha and Chemyra rivers show high variations and systematic differences.

Fig.1. PTX diagrams for kimberlite indicator minerals (KIM) from three correctors in the Udzha basin.

Fig.2 TRE distributions for KIM from Udzha alluvium

Fig.3 TRE distributions for KIM from Udzha alluvium

Supported by  RBRF grant 19-05-00788.

 

 

How to cite: Vavilov, M., Afanasiev, V., Ashchepkov, I., Baranov, L., and Vera, E.: Possible sources of the alluvial diamonds Udzha basin, northern Anabar region near kimberlite Tomtor field, Yakutia., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3368, https://doi.org/10.5194/egusphere-egu22-3368, 2022.

EGU22-3753 | Presentations | GD2.4

Inhomogeneity of the composition of lithospheric mantle beneath the Yakutian kimberlite province 

Sergey Kostrovitsky, Dmitry Yakovlev, Igor Ashchepkov, and Sebastian Tappe

For the first time, such an indicator as the Ti content in garnets was used as a criterion for the study of heterogeneity of the lithospheric mantle (LM) beneath the Yakutian kimberlite province (YaKP). Comparison of the compositions of garnet from pipes of most fields (18 out of 21) of YaKP was carried out. The study was based on representative collections of garnets from kimberlite concentrates, as well as literature and own data on the composition of garnets from mantle xenoliths from the Upper Muna pipes and northern fields adjacent to the Anabar shield, as well as from the Udachnaya, Dal’nyaya and Obnajennaya pipes. Three groups of YaKP fields with different Ti content (Fig. 1) and Mg# values ​​in garnets have been identified - 1) southern diamondiferous fields - high TiO2 content (0.26-0.50 wt%) and high Mg# value (80.6-82.6%); an exception is the Mirninsky field (0.13 wt.% TiO2); 2) the dominant number of northern fields (10 in total) is a low TiO2 content (0.06-0.26 wt%) (Fig. 2) and a relatively high value of Mg# (78.8-81.7%, middle - 80.2%); 3) three northern fields (Chomurdakh, Ogoner-Yuryakh and Toluopka) - high TiO2 content (0.53-0.78 wt.%) (Fig. 3) and low Mg# (76.9-78.3%). The trace element composition of garnets from the third group testifies to their mainly equilibrium magmatic crystallization (Fig. 4). It is assumed that the garnet-bearing rocks, due to the relatively low lithospheric mantle (LM) thickness in the marginal part of the Siberian Craton, were subjected to almost complete metasomatic processing by melt-fluids of the asthenospheric mantle. The obtained data on the composition of garnets allowed the authors to clarify the reason for the different compositions of kimberlites in the southern and northern fields of YaKP. The authors believe that the predominantly high-Ti composition of the kimberlites of the northern fields, despite the low-Ti composition of the LM rocks, reflects the primary composition of the kimberlite melt-fluid of asthenospheric origin. The relatively small thickness of the LM beneath the northern fields limited the degree of assimilation by kimberlite melt of high-Mg rocks of LM and initiated an increase in asthenosphere activity, which led to the formation of high-Ti kimberlites, high-Ti alkaline basalts, and alkaline-carbonatite massifs here. Supported by RBRF grant 19-05-00788

 

 

How to cite: Kostrovitsky, S., Yakovlev, D., Ashchepkov, I., and Tappe, S.: Inhomogeneity of the composition of lithospheric mantle beneath the Yakutian kimberlite province, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3753, https://doi.org/10.5194/egusphere-egu22-3753, 2022.

EGU22-3997 | Presentations | GD2.4

Zonation in garnets from the Udachnaya pipe: heating and melt infiltration in the lithospheric mantle of the Siberian craton 

Konstantin Solovev, Igor Sharygin, and Alexander Golovin

Xenoliths in kimberlites and other volcanic rocks are our best window into the subcranotic lithospheric mantle. Chemical overprinting associated with melt-rock interactions is almost ubiquitous in these mantle xenoliths [1]. Such local changes in chemistry may be recorded by the formation of compositional zoning in minerals. Studies of major and trace element zoning provide important information about the nature and time scales of metasomatic processes and thermal events in the upper mantle.

Usually, garnets from peridotite xenoliths have pronounced zoning, whereas olivine and pyroxenes are homogeneous. Currently, only zoning in garnets of sheared and coarse peridotite xenoliths from kimberlites of the Kaapvaal craton (southern Africa) and the minette neck The Thumb (North American craton) has been studied in detail (e.g., [2,3]). There is no detailed study on major-, minor- and trace-element zoning in garnets of peridotite xenoliths from kimberlites of the Siberian craton.

In our study, we provide a detailed description of complex major- and trace-element zoning patterns in garnets of two unique fresh sheared peridotites from the Udachnaya kimberlite pipe (Siberian craton). The mantle residence pressure and temperature of the peridotites UV-3/05 (lherzolite) and UV-33/04 (harzburgite) are 6.4 GPa and 1350°C [4] and 6.0 GPa and 1320°C [5], respectively.

The profiles of minor and major elements are complex and symmetric. The profiles change their slope signs (positive/negative) several times. It should be noted that the Ni content increases from the cores to the rims. The chondrite-normalized REE patterns show a continuous change from the cores to the rims. The cores display sinusoidal patterns (LREE enrichment peaking at Sm), whereas patterns of the rims are ‘normal’ (with HREE enriched by 15–19× chondrite abundances for Gd through Lu).

The profiles are consistent with the formation of garnet overgrowths and increasing temperature, followed by diffusive equilibration between the rims and cores over hundreds or thousands of years. Using melt-garnet distribution coefficients of trace elements, we showed that the metasomatic melt, which caused the formation of the garnet overgrowths, had a genetic link to the kimberlite magmatism that formed the Udachnaya pipe. The profile lengths of Zr, Ce, Sm, Eu, Gd, and Hf are longer than the profile lengths of Tb, Dy, Ho, Er, Tm, Yb, and Lu. This indicates that the composition of the melt changed (from composition in equilibrium with upper mantle peridotite to kimberlitic composition) during its percolation through the mantle, as predicted by the theory proposed by Navon and Stolper (1987).

This study was supported by the Russian Science Foundation (grant No 18-77-10062).

References: [1] Pearson, D.G. and Wittig, N., 2014, Treatise on Geochemistry, 255-292. [2] Griffin et al., 1989, Geochim. Cosmochim. Acta, 53(2), 561-567. [3] Smith et al., 1991, Contrib. Mineral. Petrol., 107(1), 60-79. [4] Golovin et al., 2018, Chem. Geol., 261-274. [5] Agashev et al., 2013, Lithos, 160, 201-215. [6] Navon, O. and Stolper, E., 1987, J. Geol., 95(3), 285-307.

How to cite: Solovev, K., Sharygin, I., and Golovin, A.: Zonation in garnets from the Udachnaya pipe: heating and melt infiltration in the lithospheric mantle of the Siberian craton, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3997, https://doi.org/10.5194/egusphere-egu22-3997, 2022.

EGU22-4994 | Presentations | GD2.4

Low He content of the high 3He/4He Afar mantle plume: Origin and implications of the He-poor mantle 

Ugur Balci, Finlay M. Stuart, Jean-Alix Barrat, and Froukje M. van der Zwan

Basalts from high flux intra-plate volcanism (Iceland, Hawaii, Samoa) are characterised by 3He/4He that are significantly higher than those from the upper mantle sampled at mid-ocean ridges.  The prevailing paradigm requires that a largely undegassed deep Earth is enriched in primordial noble gases (3He, 20Ne) relative to degassed convecting upper mantle.  However, the He concentration and 3He/20Ne ratio of high 3He/4He oceanic basalts are generally lower than mid-ocean ridge basalts (MORB). This so called ‘He paradox’ has gained infamy and is used to argue against the conventional model of Earth structure and the existence of mantle plumes.  While the paradox can be resolved by disequilibrium degassing of magmas it highlights the difficulty in reconstructing the primordial volatile inventory of the deep Earth from partially degassed oceanic basalts.

Basalts from 26 to 11°N on the Red Sea spreading axis reveals a systematic southward increase in 3He/4He that tops out at 15 Ra in the Gulf of Tadjoura (GoT). The GoT 3He/4He overlaps the highest values of sub-aerial basalts from Afar and Main Ethiopian Rift and is arguably located over modern Afar plume.  The along-rift 3He/4He variation is mirrored by a systematic change in incompatible trace element (ITE) ratios that appear to define two-component mixing between E-MORB and HIMU.  Despite some complexity, hyperbolic mixing relationships are apparent in 3He/4He-K/Th-Rb/La space.  Using established trace element concentrations in these mantle components we can calculate the concentration of He in the Afar plume mantle.  Surprisingly it appears that the upwelling plume mantle has 5-20 times less He than the convecting asthenospheric mantle despite the high 3He/4He (and primordial Ne isotope composition). This contradicts the prevailing orthodoxy but can simply be explained if the Afar mantle plume is itself a mixture of primordial He-rich, high 3He/4He (55 Ra) deep mantle with a proportionally dominant mass of He-poor low 3He/4He HIMU mantle. This is consistent with the narrow range of Sr-Nd-Os isotopes and ITE ratios of the highest 3He/4He Afar plume basalts, and is in marked contrast to high 3He/4He plumes (e.g. Iceland) that do not have unique geochemical composition. The HIMU signature of the Afar plume basalts implies origin in recycled altered oceanic crust (RAOC). Assuming that no He is recycled and using established RAOC U and Th concentrations, the low He concentration (< 5 x 1013 atoms/g He) of the He-poor mantle implies that the slab was subducted no earlier than 70 Ma and reached no more than 700 km before being incorporated into the upwelling Afar plume. We suggest that the Afar plume acquired its chemical and isotopic fingerprint during large scale mixing at the 670 km transition zone with the Tethyan slab, not at the core-mantle boundary.

This study implies that large domains of essentially He-poor mantle exist within the deep Earth, likely associated with the HIMU mantle compositions. Further, it implies that moderately high-3He/4He (< 30 Ra) mantle plumes (e.g. Reunion) need not contain a significant contribution of deep mantle, thus cannot be used a priori to define primitive Earth composition.

How to cite: Balci, U., Stuart, F. M., Barrat, J.-A., and van der Zwan, F. M.: Low He content of the high 3He/4He Afar mantle plume: Origin and implications of the He-poor mantle, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4994, https://doi.org/10.5194/egusphere-egu22-4994, 2022.

EGU22-5450 | Presentations | GD2.4

Exotic magmatism from the western branch of the East African Rift: insights on the lithospheric mantle source. 

Francesca Innocenzi, Sara Ronca, Stephen F. Foley, Samuele Agostini, and Michele Lustrino

The northernmost sector of the western branch of the East African Rift (EAR) includes the young (~40-50 ka [1]) volcanic province of Toro Ankole, characterized by the presence of exotic volcanic products such as carbonatites, melilitites, kamafugites and foidites [2]. Among these, the occurrence of kamafugites (kalsilite-bearing volcanic rocks [3]) is noteworthy, as Toro Ankole represents the type locality for these compositions, found in only two other localities worldwide. The Toro Ankole volcanic province developed along the margin of the Archean Tanzanian craton, and its magmatic products show the influence of metasomatic processes and phases developed in the thick continental lithosphere. Indeed, MARID-like metasomatism is proposed in literature, with the formation of a veined mantle [4].

A multidisciplinary approach, based on a detailed petrographic, mineral chemical, geochemical and isotopic (Sr, Nd, Pb and B) study, has been carried out on 53 samples, which include not only lavas and tuffs, but also holocrystalline and wall rock xenoliths. Two types of lava may be identified: the first is represented by carbonatites and silico-carbonatites, characterized by low SiO2 (4.89-21.78 wt%) and low alkali (0.44-2.03 wt%) and high CaO (25.17-47.57 wt%), while the second most peculiar lithotypes is represented by kamafugites; katungites (melilite-rich kalsilite-olivine-bearing volcanic rocks), mafurites (kalsilite-rich melilite-olivine-bearing) and ugandites (olivine-rich kalsilite-melilite-bearing). The kamafugites are strongly SiO2-undersaturated and moderately ultrabasic, potassic to ultrapotassic volcanic rocks, with high MgO (6.08-22.20 wt%) and CaO (up to 15.46 wt%). They consist of phenocrysts of clinopyroxene and olivine set in a hypo-holocrystalline fine-grained groundmass made up of microliths of clinopyroxene, olivine, perovskite, kalsilite, nepheline, leucite, melilite, phlogopite, carbonates and opaques.

The xenolith cargo shows wide range of compositions, varying from clinopyroxenite to glimmerite, with low modal abundance of opaques and perovskite in agreement with the literature data that generally report a lack of olivine and orthopyroxene in the mineral assemblage [5]. The common presence of phlogopite, abundant clinopyroxene and carbonate-rich veins indicate the presence of veined lithosphere [6]. This is consistent with the isotopic data for lavas and xenoliths (87Sr/86Sr = 0.70480-0.70563 and 143Nd/144Nd = 0.512515-0.512575), which outlines an enriched and complex mantle source. 206Pb/204Pb is extremely variable, with values from the holocrystalline xenolith (19.99-19.27) being slightly higher than lava samples (19.28-19.63). The d11B values for lavas and xenoliths, show a wide range, varying from DMM-like values (-6 and -8‰) to more variable OIB-like values (down to -12 and up to -3‰; [7]), through to positive values (up to +6.6‰ in the lavas). These latter also exhibit the highest Sr isotopic ratios of the dataset, pointing to the possible occurrence of old and altered oceanic crust and/or serpentinite in the mantle source.

Bibliography

[1] Boven et al., 1998, J. Afr. Earth Sci., 26, 463-476.

[2] Holmes and Harwood, 1932, Quarterly J. Geol. Soc., 88, 370-442.

[3] Le Maitre, 2002, Cambridge University Press.

[4] Rosenthal et al., 2009, Earth Planet. Sci. Lett., 284, 236-248.

[5] Link et al., 2008, 9th Int. Kimb. Conf., 1-3.

[6] Foley, 1992, Lithos, 28, 435-453.

[7] Agostini et al., 2021, Sci. Rep., https://doi.org/10.1038/s41598-021-90275-7.

How to cite: Innocenzi, F., Ronca, S., Foley, S. F., Agostini, S., and Lustrino, M.: Exotic magmatism from the western branch of the East African Rift: insights on the lithospheric mantle source., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5450, https://doi.org/10.5194/egusphere-egu22-5450, 2022.

Spinel peridotite xenoliths have been found in Cenozoic basalts from the Nuomin and Keluo areas in the northern Daxinganling. The Mg content of olivine in the mantleperidotite indicates that the upper mantle in the study area is partially refractory. According to the olivine content and Fo diagram, a part of peridotite xenoliths fell in the Archean and Proterozoic mantle regions, which reveals that there are remnants of ancient lithospheric mantle in the lithospheric mantle of the study area. In the study area, harzburgite and lherzolite show high oxygen fugacity values (FMQ + 1.95-3.15), which is in sharp contrast to the low oxygen fugacity values of the relatively reduced ancient lithospheric mantle. It is possible that the Paleozoic paleo Asian Ocean and Mesozoic paleo Pacific subducted successively under the Xingmeng orogenic belt, resulting in the oxidation of the lithospheric mantle at that time. K 2O (1% ~ 6%) is found in the reaction edge of mantle xenoliths. It is considered that the mantle in the study area has experienced multiple periods of K-rich meltactivity, and the source of K-rich melt may be related to the crust source material recycled by subduction.

How to cite: Liu, J. and Li, H.: Oxygen fugacity characteristics of lithospheric mantle peridotite in northern Xingmeng orogenic belt, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5941, https://doi.org/10.5194/egusphere-egu22-5941, 2022.

The Tuva-Mongolian microcontinent and Khamardaban terrane are known as major tectonic units accreted to the Siberian paleocontinent. We report 207Pb/206Pb ages of 2.44–2.22 Ga for sources of Late Cenozoic volcanic rocks from the Tunka volcanic zone and of 1.63–1.31 Ga for those from the Khamardaban zone. The new ages are consistent with Precambrian geological events that are characteristic of the area and contradict the existing opinion about the Early Paleozoic collisional connection between these tectonic units inferred from dating of syn-collisional granites.

On the one hand, we constrain ore-forming processes in the Gargan block of the Tuva-Mongolian microcontinent and in the south of the Siberian paleocontinent between 2.45 and 1.4 Ga and between 1.3 and 0.25 Ga, respectively [Rasskazov et al., 2010]. The latest Pb-separating event in the Gargan block was followed by the generation of restite ultrabasic Ilchir belt that bounds the block from the south [Kiseleva et al., 2020]. So, we trace the boundary between the Gargan block and Ilchir belt to magma sources of the Tunka and Khamardaban zones that reasonably denote the root part of the Khamardaban terrane, accreted to the Tuva-Mongolian microcontinent and Siberian paleocontinent 1.63–1.31 Ga ago (Figure). On the other hand, we emphasize the importance of ore-forming events in the Gargan block, launched about 2.45 Ga, simultaneously with source generation in the Tunka zone. Basalts of this zone include xenoliths of fassaitic clinopyroxenites that show wide variations in the oxidation–reduction state. We suggest that fassaite (diopside) mineralization was due to interaction between orthopyroxene and calcite: (Mg, Fe)2Si2O6 + CaCO3 → (Mg, Ca)2Si2O6 + CO2 + FeO. Orthopyroxene of high-Mg spinel harzburgite xenoliths from Khobok River lavas (Tunka basin) shows SiO2 content as high as 58.7 wt. %, while fassaite from pyroxenite xenoliths has SiO2 content as low as 49 wt. %. Fassaitization of orthopyroxenites and harzburgites, obviously, releases both iron and silica. These components are found as amorphous Fe–Si phases in metasomatite xenoliths with low Mg/Si and Al/Si ratios [Ailow et al., 2021]. From data obtained, we speculate that fassaitization was an effective crust-mantle process of 2.4–2.2 Ga that could provide both the deep-seated Fe–Si mineralization and the generation of ferruginous quartzites displayed in the Great Oxidation Event.

Ailow Y. et al. // Lithosphere. 2021. V. 21, No. 4. P. 517–545.

Kiseleva O.N. et al. // Minerals. 2020. V. 10. P. 1077.

Rasskazov S.V. Brandt S.B., Brandt I.S. Radiogenic isotopes in geologic processes. Springer, 2010. 306 p.

How to cite: Rasskazov, S., Chuvashova, I., Saranina, E., Yasnygina, T., and Ailow, Y.: Crustal versus mantle events of 2.44–2.22 and 1.63–1.31 Ga at the junction between Khamardaban terrane, Tuva-Mongolian microcontinent, and Siberian paleocontinent: Petrogenetic consequences, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6686, https://doi.org/10.5194/egusphere-egu22-6686, 2022.

EGU22-6723 | Presentations | GD2.4

Deep ultra-hot melting in cratonic mantle roots 

Carl Walsh, Balz Kamber, and Emma Tomlinson

The persistence of Archaean cratons for >2.5Ga was aided by thick, mechanically strong, and cool lithospheric mantle keels up to 250km deep. It is widely accepted that the cratonic mantle, dominated by depleted harzburgite, lherzolite and dunite, was formed by extensive melt extraction from originally fertile mantle peridotite. Models seeking to explain the formation of deep cratonic mantle in the garnet and diamond stability fields, initially sought to answer how such rocks could form in-situ at high temperatures and pressures and envisaged large-scale thermochemical plume upwellings. More recently, mineralogical and geochemical observations, namely the high Cr content of garnet and low whole rock HREE concentrations in cratonic harzburgites, have led to the conclusion that the deep cratonic mantle couldn’t have originally melted in the garnet stability field.  Mechanical stacking of shallowly depleted oceanic lithosphere was therefore proposed to have thickened the depleted lithosphere cratonic roots. In this process, the spinel facies minerals are envisaged to transform into the garnet stability field.

Here we present the first results of combined thermodynamic and geochemical modelling at temperatures high enough to reconcile the very refractory residues. We found that the requirement for initially shallow melting is no longer supported. Deep (150-250km), ultra-hot (>1800°C), incremental melting can produce the mineralogical and geochemical signatures of depleted cratonic harzburgites. The modelling also implies a link between areas of extreme depletion in the deep lithospheric mantle and the genesis of Earth’s hottest lavas (Al-enriched komatiite) by re-melting depleted harzburgite. Diamond inclusion minerals have a well-documented skew to the most refractory compositions found in cratonic peridotite. We propose that these ultra-depleted, highly reducing regions of the lithospheric root possess the highest diamond formation and preservation potential.

How to cite: Walsh, C., Kamber, B., and Tomlinson, E.: Deep ultra-hot melting in cratonic mantle roots, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6723, https://doi.org/10.5194/egusphere-egu22-6723, 2022.

EGU22-6724 | Presentations | GD2.4 | Highlight

Lateral change of  ELMU–LOMU sources for Cenozoic volcanic rocks from Southeast Mongolia and North China: Tracing zonation of solidified Hadean magma ocean 

Irina Chuvashova, Sergei Rasskazov, Yi-min Sun, Tatiana Yasnygina, and Elena Saranina

In terms of Pb isotope ratios, melting anomalies of Central and East Asia show no high μ (HIMU, high 238U/204Pb) signature that was generated on the Earth about 2 Ga ago and was caused by sulfide sequestration of Pb from the mantle to the core [Hart and Gaetany, 2006]. In such particular environment, we use Pb isotope data on Late Phanerozoic volcanic rocks to develop general systematics of their sources through definition of initial viscous protomantle reservoirs with low μ and elevated μ signatures (LOMUVIPMAR and ELMUVIPMAR, respectively) that imply a solidification time of the mantle in the Hadean magma ocean between 4.54 and 4.44 Ga ago. We suggest that the protomantle reservoirs retained specific Pb isotope signatures in the early, middle, and late epochs of the Earth's evolution (4.54–3.6, 2.9–1.8, and  <0.7 Ga ago, respectively) [Rasskazov et al., 2020]. In this presentation, we report the first representative Pb isotope data on the ELMU signature of Late Cenozoic rocks from the Dariganga volcanic field, Southeast Mongolia. Pb isotope secondary-isochron patterns of volcanic rocks show protomantle material that was not differentiated between 4.474 and 4.444 Ga (i.e. directly ascended from a deep mantle reservoir in the Cenozoic). In addition, the material was also differentiated in the deep mantle at about 3.69, 2.16, and 1.74 Ga. Pb isotope data on volcanic fields of North China are indicative for lateral change from the ELMU to LOMU signature (Figure). We infer that sources of volcanic rocks from Southeast Mongolia and North China display the primary inhomogeneity of the deep mantle that was generated in the Hadean magma ocean from its initial solidification as early as 4.54 Ga to its final respond of 4.44 Ga.   

Hart, S.R. &  Gaetani, G.A. (2006). Mantle paradoxes: the sulfide solution. Contrib. Mineral. Petrol., 152, 295–308.

Rasskazov, S., Chuvashova, I., Yasnygina, T., & Saranina, E. (2020). Mantle evolution of Asia inferred from Pb isotopic signatures of sources for Late Phanerozoic volcanic rocks. Minerals, 10 (9), 739. 

How to cite: Chuvashova, I., Rasskazov, S., Sun, Y., Yasnygina, T., and Saranina, E.: Lateral change of  ELMU–LOMU sources for Cenozoic volcanic rocks from Southeast Mongolia and North China: Tracing zonation of solidified Hadean magma ocean, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6724, https://doi.org/10.5194/egusphere-egu22-6724, 2022.

The method of cluster (R and G methods) analysis of the allocation of the cluster (CG) and chemical-generic (CGG) groups of average values of the compositions of diamond indicator minerals (DIM) (Ivanov, 2017) was used, supplemented with data on the frequency of occurrence (FO) of habitus forms, twins and clusters of diamond crystals of three kimberlite pipes of Angola – Catoca, Luele and Txiuzo (Ganga et al., 2021). Clustering of MSDS by their chemical composition was carried out on the basis of chemical-genetic classifications of Dowson J. and Soboleva N.V. for garnets (Dowson et al., 1975; Sobolev, 1973) and Garanin V. K. for Cr-diopsides, of ilmenite and chromite (Garanin et al., 1991).

It is found that FO CG/СGG of МSD are indirect and inverse significant correlation with FO habitus forms, twins and adhesion of diamond crystals of these kimberlite pipes. This is demonstrated by histograms of the joint distribution of CG DIM and habitus forms, twins and splices of diamond crystals from geological samples of kimberlites at their deposits (Fig. 1).

The fractions of octahedra (O) and transition habit crystals (OD) decrease in parallel with a decrease in the proportions of CG G9, G10 pyropes and an increase in G1 and G2a, an increase in the proportions of CGG 2b and 4b picroilmenites. The shares of rhombododecahedron, including dodecahedrons (RD), grow with the growth of the shares of CG pyropes G1a, G2a, as well as CGG picroilmenites 2b and CGG Cr-diopsides S2 and S5. The shares of twins (Tw), splices (Agr) and polycrystalline bead (PC) decrease in the studied tubes with a decrease in the shares of CG pyropes G10, G10a and an increase in the shares of CGG picroilmenites 2b and 4b and CGG Cr-diopsides S2 and S5 (Fig. 1). The presence of Ti and Fe compounds, which are part of DIM in elevated concentrations, in the process/medium of diamond crystal formation contributes to the formation of habitus forms OD and RD (D - dodecahedrons) during dissolution associated with low-chromium pyropes CG G1 and G2. Medium-high chromium pyropes CG G10 and G10a are associated with octahedral habitus (O) diamond crystals and their spinel counterparts (TwSp), whose shares they control.

Petrogenetic affiliation of CG/CGG MSD to various associations of deep mantle rocks allows us to identify the most favourable conditions and environments for the origin and growth of diamonds (high FO of O+TwSp+Tw) and environments (conditions) of their dissolution (high FO of OD+RD+Th+C). Interesting that the diamond grade calculated diamond deposits (Ct /T) is positively correlated with FO (Ar g+Tw), SGG S6 picroilmenites and SG G10 garnets, but the FO (RD+OD) has a negative effect on diamond grade, which allows determining the degree of the fertility of the mantle sources by DIM diamond.

How to cite: Zinchenko, V. and Ivanov, A.: Correlation of habitus forms, twins and aggregates of diamond crystals with the composition of its indicator minerals from kimberlite pipes of Angola, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6809, https://doi.org/10.5194/egusphere-egu22-6809, 2022.

EGU22-6844 | Presentations | GD2.4

Reconstruction of the composition of the kimberlite melt of the Bultfontein pipe, Kaapvaal craton 

Alexey Tarasov, Alexander Golovin, and Igor Sharygin

Information about the compositions of primitive kimberlite melts is important for understanding the petrogenesis of kimberlites. Reconstruction of the composition of these melts is very difficult because the melts greatly changed their compositions via assimilation of mantle and crust xenogenic materials and degassing during ascent.

To reconstruct the composition of the kimberlite melt of the Bultfontein pipe (Kaapvaal craton, South Africa), the mineral assemblage of secondary melt inclusions in olivines of mantle peridotite xenoliths from the pipe has been studied. The depths of equilibrium of the studied peridotites range from 120 to 150 km.

The inclusions occur along the healed cracks in the olivine grains. Twenty-five daughter minerals were found in the inclusions by Raman spectroscopy and scanning electron microscopy. Liquids and gases were not detected. The inclusions are mainly made up of carbonates (calcite CaCO3, magnesite MgCO3, dolomite CaMg(CO3)2, eitelite Na2Mg(CO3)2, nyerereite Na2Ca(CO3)2, gregoryite (Na,K,Ca)2CO3, K-Na-Ca-carbonate (K,Na)2Ca(CO3)2, shortite Na2Ca2(CO3)3) or carbonates with additional anions (nahcolite NaHCO3, bradleyite Na3Mg(PO4)(CO3), northupite Na3Mg(CO3)2Cl, burkeite Na6CO3(SO4)2, tychite Na6Mg2(CO3)4(SO4)). Halides (halite NaCl, sylvite KCl), sulfates (glauberite Na2Ca(SO4)2, thenardite Na2SO4, aphthitalite K3Na(SO4)2), phosphate (apatite Ca5(PO4)3(F,Cl,OH)), oxides (rutile TiO2, magnetite FeFe2O4), sulfide (heazlewoodite Ni3S2) and silicates (phlogopite KMg3AlSi3O10(F,Cl,OH), tetraferriphlogopite KMg3FeSi3O10(F,Cl,OH), richterite Na2Ca(Mg,Fe,Mn,Al)5[Si4O11](OH,F)2) are also present in the inclusions.

These inclusions are considered to be relics of a near‐primary or primitive kimberlitic melt that later formed the Bultfontein pipe. The observed mineral assemblage indicates that the captured melt had an alkali-carbonatitic composition and was rich in Cl and S.

This work was supported by the Russian Foundation for Basic Research (grant No. 20-35-70058).

How to cite: Tarasov, A., Golovin, A., and Sharygin, I.: Reconstruction of the composition of the kimberlite melt of the Bultfontein pipe, Kaapvaal craton, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6844, https://doi.org/10.5194/egusphere-egu22-6844, 2022.

EGU22-7771 | Presentations | GD2.4

Zhidoy Alkali-Ultramafic Rock and Carbonatite Massif: GeochemicalFeatures, Its Sources And Ore-Bearing 

Irina Sotnikova, Nikolai Vladykin, and Natalia Alymova

The article considers the geological position of the Zhidoy massif and its age. The scheme of magmatism of the massif has been developed. The graphs of paired correlations of petrogenic elements in massif rocks which had a consistent trend in composition are given for validation purposes. The present article provides graphs of REE spectra and the spider diagram of rare elements concentration in the massif rocks. Pyroxenites are the early rocks of the massif, which are the ores for titanium. Titanium is concentrated in three minerals: titanium magnetite, ilmenite and perovskite. The main type of titanium ores, perovskite, is known only in the Zhidoy massif. A conclusion about the mantle sources of the primary magma of the massif
is drawn based on the geochemistry of the isotopes Sr and Nd.

Fig. 1 Spectra of rare-earth elements in rocks of the Zhidoy massif (chondrite-normalized).
Symbols: 1−pyroxenite, 2−ijolite, 3−syenite, 4−phenite

 

Fig. 2 Spider-diagram of the Zhidoy massif rocks

Conclusions
1. Three varieties of ore pyroxenites have been defined−titanium-magnetite, ilmenite and perovskite ore.
2. The petrochemical diagrams show a common trend in the composition of rock- forming elements, indicating the homomorphism of the rocks and their crystallization from a single primary magma.
3. Geochemical data also confirm the genetic relation of the Zhidoy massif.
4. Mantle source, the depurated mantle for the primary magma of the Zhidoy massif, has been determined on the basis of isotope data.

How to cite: Sotnikova, I., Vladykin, N., and Alymova, N.: Zhidoy Alkali-Ultramafic Rock and Carbonatite Massif: GeochemicalFeatures, Its Sources And Ore-Bearing, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7771, https://doi.org/10.5194/egusphere-egu22-7771, 2022.

International Ocean Discovery Program (IODP) Expedition 357 drilled 17 shallow sites spanning ~10 km in the spreading direction (from west to east) across the Atlantis Massif oceanic core complex (OCC, Mid-Atlantic Ridge, 30°N). Exposed mantle in the footwall of the Atlantis Massif OCC is predominantly nearly wholly serpentinized harzburgite and subordinate dunite. Altered peridotites are subdivided into: (I) serpentinites, (II) melt-impregnated serpentinites, and (III) metasomatized serpentinites. Type I serpentinites show no evidence of melt-impregnation or metasomatism apart from serpentinization and local oxidation. Type II serpentinites have been intruded by gabbroic melts and are distinguishable in some cases based on macroscopic and microscopic observations, e.g., mm-cm scale mafic-melt veinlets, rare plagioclase (˂0.5 modal % in one sample) or by the local presence of secondary (replacive) olivine after orthopyroxene; in other cases, ‘cryptic’ melt-impregnation is inferred on the basis of incompatible element enrichment. Type III serpentinites are characterized by silica metasomatism manifest by alteration of orthopyroxene to talc and amphibole, anomalously high anhydrous SiO2, and low MgO/SiO2. Two fundamental features of the mantle serpentinites are identified: (1) A pattern of increasing melt-impregnation from west to east; and (2) a link between melt-impregnation and metamorphism. In regard to (1), whereas a dominant fluid- rock alteration (mostly serpentinization) is distinguished in the western serpentinites, a dominant mechanism of melt-impregnation is recognized in the central and eastern serpentinites. Melt-impregnation in the central and eastern sites is characterized by enrichment of incompatilble elements, Cr-spinel with anomalously high TiO2 (up to 0.7 wt.%) and olivine forsterite (Fo) compositions that range to a minimum of Fo86.5.  With respect to (2), in contrast to unmetamorphosed Cr-spinel of western site Type I serpentinized peridotites, spinel of the melt-dominated central and eastern peridotites record metamorphism, which ranges from sub-greenschist (<500°C) to lower amphibolite (>600°C) facies. Low grade, sub-greenschist facies metamorphism resulted in Mg and Fe2+ exchange between Cr-spinel and olivine resulting in Cr-spinel with anomalously low Mg# (cationic Mg/(Mg+Fe2+)). Higher grade amphibolite facies metamorphism resulted in Al-Cr exchange and the production of Fe-chromite and Cr-magnetite. Heat associated with magma injection and subsequent melt-impregnation resulted in localized contact metamorphism. High degrees of melt extraction are evident in low whole-rock Al2O3/SiO2 and low concentrations of Al2O3, CaO, and incompatible elements. Estimates of the degree of melt extraction based on Cr# (cationic Cr/Cr+Al, up to ~0.4) of unaltered Cr-spinel and modeled whole rock REE patterns, suggest a maximum of ~18-20% non-modal fractional melting. As some serpentinite samples are ex-situ rubble, the magmatic histories at each site are consistent with derivation from a local source (the fault zone) rather than rafted rubble that would be expected to show more heterogeneity and no spatial pattern. In this case, the studied sites may provide a record of enhanced melt-rock interactions with time, consistent with proposed geological models for OCC formation.  

How to cite: Whattam, S. A.: Spatial patterns of fluid- and melt-rock processes and link between melt-impregnation and metamorphism of Atlantis Massif peridotites (IODP Expedition 357), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9186, https://doi.org/10.5194/egusphere-egu22-9186, 2022.

EGU22-9214 | Presentations | GD2.4 | Highlight

Mantle-derived cargo vs. magmatic growth: ascent path, dynamics of the Udachnaya kimberlite and interactions with the Siberian sub-cratonic lithosphere 

Federico Casetta, Rainer Abart, Theodoros Ntaflos, Igor Ashchepkov, and Massimo Coltorti

Unravelling the processes taking place during the genesis of kimberlites, their ascent through the sub-cratonic mantle and their emplacement in the crust is challenging, as kimberlites are mixtures of mantle-derived and magmatic components, rarely preserving pristine evidence of their original nature. Furthermore, their intense state of alteration makes it difficult to access the textural-compositional record of information engraved in the phase constituents. In this study, fresh samples of kimberlites and related mantle-derived xenocrysts-xenoliths from the Udachnaya pipe (Siberia) were investigated to reconstruct the pressure-temperature-time-composition (P-T-t-X) framework of the sub-cratonic lithosphere at the time of kimberlite emplacement. Routine and high-precision electron microprobe analyses of olivine, phlogopite and spinel from different facies of the Udachnaya pipe (intrusive coherent, hypabyssal and pyroclastic, sensu Scott Smith et al., 2013) showed that specific phase assemblages are associated with each evolutionary stage of the kimberlite. Olivine composition, in particular, is extremely variable, ranging from high-Fo and high-Ni (Fo93; NiO = 0.45 wt%) to low-Fo and low-Ni (Fo85; NiO = 0.10 wt%), but also to high-Fo and low-Ni (Fo>93; NiO <0.05 wt%) terms, often encompassing the whole compositional spectrum in a single sample and/or showing marked zoning within the individual crystals. 
A comparison between the main constituents of the Udachnaya kimberlite and those of the mantle xenoliths sampled during ascent, complemented by detailed major-trace element profiles on olivine crystals, was put forward to: (i) discriminate between the mantle-derived xenocryst cargo and the magmatic assemblage; (ii) model the P-T-fO2 path of kimberlites; (iii) speculate about their ascent rate; (iv) model the interactions between kimberlite-related fluid/melts and the Siberian sub-cratonic lithosphere.

REFERENCES
Scott Smith, B.H., Nowicki, T.E., Russell, J.K., Webb, K.J., Mitchell, R.H., Hetman, C.M., ... & Robey, J.A. (2013). Kimberlite terminology and classification. In Proceedings of 10th international kimberlite conference (pp. 1-17). Springer, New Delhi.

How to cite: Casetta, F., Abart, R., Ntaflos, T., Ashchepkov, I., and Coltorti, M.: Mantle-derived cargo vs. magmatic growth: ascent path, dynamics of the Udachnaya kimberlite and interactions with the Siberian sub-cratonic lithosphere, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9214, https://doi.org/10.5194/egusphere-egu22-9214, 2022.

EGU22-9813 | Presentations | GD2.4

The architecture of the lithospheric mantle controlled the emplacement of the Central Atlantic Magmatic Province 

Andrea Boscaini, Andrea Marzoli, Hervé Bertrand, Massimo Chiaradia, Fred Jourdan, Manuele Faccenda, Christine Meyzen, Sara Callegaro, and Lina Serrano Durán

Large Igneous Provinces (LIPs) represent exceptionally brief (<1 Ma) voluminous magmatic events that punctuate Earth history, frequently leading to continental break-up, global climate changes and, eventually, mass extinctions. Most LIPs emplaced in continental settings are located near cratons, begging the question of a potential control of thick lithosphere on mantle melting dynamics. In this study we discuss the case of the Central Atlantic Magmatic Province (CAMP), emplaced in the vicinity of the thick lithospheric keels of the Precambrian cratons forming the central portion of Pangea prior to the opening of the Central Atlantic Ocean. In particular, we focus on CAMP magmas of the Prevalent group, ubiquitous all over the province, and of the Tiourjdal and High-Ti groups, emplaced (respectively) at the edges of the Reguibat and Leo-Man shields in north-western Africa, and the Amazonian and São Luis cratons in South America. As imaged by recent tomographic studies, there is a strong spatial correlation between most CAMP outcrops at surface and the edges of the thick cratonic keels. Geochemical modelling of trace element and isotopic compositions of CAMP basalts suggests a derivation by partial melting of a Depleted MORB Mantle (DMM) source enriched by recycled continental crust (1-4%) beneath a lithosphere of ca. 80 km. Melting under a significantly thicker lithosphere (>110 km) cannot produce magmas with chemical compositions similar to those of CAMP basalts. Therefore, our results suggest that CAMP magmatism was produced by asthenospheric upwelling along the deep cratonic keels and subsequent decompression-induced partial melting in correspondence with thinner lithosphere. Afterwards, lateral transport of magma along dykes or sills led to the formation of shallow intrusions and lava flows at considerable distances from the source region, possibly straddling the edges of the cratonic lithosphere at depth. Overall, the variations of the lithospheric thickness (i.e., the presence of stable thick cratonic keels juxtaposed to relatively thinner lithosphere) appear to play a primary role for localizing mantle upwelling and partial melting during large-scale magmatic events like the CAMP.

How to cite: Boscaini, A., Marzoli, A., Bertrand, H., Chiaradia, M., Jourdan, F., Faccenda, M., Meyzen, C., Callegaro, S., and Serrano Durán, L.: The architecture of the lithospheric mantle controlled the emplacement of the Central Atlantic Magmatic Province, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9813, https://doi.org/10.5194/egusphere-egu22-9813, 2022.

EGU22-10951 | Presentations | GD2.4

Age and geochemistry of the Kamthai carbonatites, Rajasthan, western India 

Milan Kumar Mahala and Jyotiranjan S. Ray

The Kamthai carbonatites form part of the Sarnu-Dandali alkaline complex (SDAC) of Rajasthan, western India. The SDAC is one of several alkaline intrusive complexes emplaced prior to the Deccan continental flood basalt eruptions. Considered as one of the earliest Deccan-Reunion plume related magmatic activities, the rocks of the complex hold clues to many tectonomagmatic processes such as plume-lithosphere interaction, mantle melting prior to flood basalt volcanism, and carbonatite-plume relationship, apart from the outstanding questions pertaining to the origin of carbonatites themselves, and their association with alkaline silicate rocks. To understand some of these processes vis-à-vis the evolution of the complex, we have carried out a detailed field, petrographic, geochronological (40Ar/39Ar), geochemical, and Sr-Nd-Pb-C-O isotopic investigation. Phlogopites from carbonatites yield an age of 68.6 Ma, identical to the ages determined for the three associated phonolite dykes. Interestingly, an earlier study reports the presence of older (89-86 Ma) subvolcanic and volcanic bodies in the complex, thus suggesting recurrent alkaline magmatism. Carbonatites of Kamthai occur as veins, dykes, and small plugs, along with dykes/plugs of ijolite, nephelinite, syenite and phonolite etc. The SDAC intrudes into the basement made up of Malani Rhyolites. The stable C-O isotopic compositions of unaltered carbonatites (δ13CPDB= -6.6 to -4.6 ‰; δ18OSMOW=5.5 to 9.5 ‰), which are predominantly calcite carbonatites, not only confirm the magmatic nature of the rocks but also show evidence of fractional crystallization. The chondrite-normalized rare-earth element patterns of the carbonatites and alkaline silicate rocks show LREE enriched patterns, with the former possessing abnormally high contents of LREE. The average (87Sr/86Sr)i and εNd(t=68.5 Ma) for carbonatites are 0.7043±0.0001 and 2.4±0.2, respectively, which are indistinguishable from those for the alkaline silicate rocks (87Sr/86Sr)i= 0.7045±0.0003; εNd(t)=2.4±0.4), which suggests common parentage. All these data point towards a petrogenetic link between the 68.6 Ma carbonatites and alkaline silicate rocks of the SDAC, either through liquid immiscibility or fractional crystallization of a common parental magma. Overlapping initial Sr-Nd isotopic ratios of these rocks with those of the least contaminated Deccan lava flows and the Reunion island rocks suggest a possible genetic link between the SDAC and the Deccan-Reunion plume. 

How to cite: Mahala, M. K. and Ray, J. S.: Age and geochemistry of the Kamthai carbonatites, Rajasthan, western India, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10951, https://doi.org/10.5194/egusphere-egu22-10951, 2022.

EGU22-10980 | Presentations | GD2.4

Composition of the kimberlite melt of the Komsomolskaya-Magnitnaya pipe (Upper Muna field, Siberian craton) 

Anastasiya Kalugina, Igor Sharygin, Konstantin Solovev, Alexander Golovin, and Anna Dymshits

Reconstruction of kimberlite melt composition is especially important to understand the processes of mantle-derived magmatism and the Earth’s mantle evolution. This task seems to be very complicated because mantle melts during ascent and emplacement changed their initial characteristics due to degassing and contamination by both mantle and crustal xenogenic materials. Moreover, mantle magmatic rocks are often subjected to secondary alteration. Melt inclusions in minerals of mantle xenoliths can preserve information about the initial characteristics of mantle melts.

Here, we present the results of a study on secondary crystallized melt inclusions in olivines in two partially serpentinized xenoliths of sheared peridotites (AKM-42n and AKM-56) from the Komsomolskaya-Magnitnaya pipe (Upper Muna field, Siberian craton). The mantle residence P–T conditions of AKM-42n and AKM-56 are 6.4 GPa and 1380°C, and 6.7 GPa and 1395°C, respectively.

We identified twenty-one daughter minerals in the melt inclusions using confocal Raman spectroscopy and scanning electron microscopy coupled with energy-dispersive X-ray microanalysis. The minerals within the inclusions are presented by chlorides (sylvite KCl and halite NaCl), silicates (tetraferriphlogopite KMg3Fe3+Si3O10(OH,F)2, phlogopite KMg3AlSi3O10(OH,F)2, olivine (Mg,Fe)2SiO4, clinopyroxene (Ca,Mg,Fe)2Si2O6, and monticellite Ca(Mg,Fe)SiO4), carbonates (nyerereite (Na,K)2Ca(CO3)2, shortite Na2Ca2(CO3)3, eitelite Na2Mg(CO3)2, dolomite CaMg(CO3)2, calcite CaCO3, and magnesite MgCO3), carbonates with additional anions (burkeite Na6CO3(SO4)2 and tychite Na6Mg2(CO3)4(SO4)), sulphates (aphthitalite K3Na(SO4)2 and thenardite Na2SO4), fluorapatite Ca5(PO4)3F, sulfides (pyrrhotite Fe1-xS and djerfisherite K6(Fe,Ni,Cu)25S26Cl) and magnetite FeFe2O4.

The studied melt inclusions are considered to be relics of a near‐primary or primitive kimberlite melt that formed the Komsomolskaya-Magnitnaya pipe. The assemblage of the daughter minerals indicates that the melt had an alkali-carbonatitic composition and was enriched in Cl and S.

This work was supported by the Russian Foundation for Basic Research (grant No. 20-35-70058) and the Russian Science Foundation (grant No 18-77-10062).

How to cite: Kalugina, A., Sharygin, I., Solovev, K., Golovin, A., and Dymshits, A.: Composition of the kimberlite melt of the Komsomolskaya-Magnitnaya pipe (Upper Muna field, Siberian craton), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10980, https://doi.org/10.5194/egusphere-egu22-10980, 2022.

EGU22-11936 | Presentations | GD2.4

Garnets from xenolith in Mir kimberlite pipe: chemical composition and genesis 

Tatiana Kalashnikova, Sergey Kostrovitsky, Lidia Solovieva, Konstantin Sinitsyn, and Elvira Yudintseva

The problem of the lithospheric mantle structure under ancient cratons and their evolution attracts researchers in connection with the question of the diamond genesis. The petrological way is based on the mineral composition studying in xenoliths from the mantle depths. The Mirny kimberlite field belongs to the diamond-bearing kimberlite fields in the center of the Siberian craton. The authors studied a collection of mantle xenoliths from the Mir pipe (57 samples). The samples were classified as peridotites (Grt lherzolites) and pyroxenites (Grt websterites, Grt clinopyroxenites and eclogites).

Lherzolites from the Mir pipe are characterized by a high degree of alteration; olivine and orthopyroxene are replaced by serpentine in many samples (up to 50–70%). Websterite rocks are different by the presence of orthopyroxene and clinopyroxene, while clinopyroxene may contain lamellae of exsollution structures. Garnet websterites are distinguished by orange-reddish color of garnet, dark green color of pyroxene and dominanting medium-large-grained hypidiomorphic-granular textures; porphyroblastic and granoblastic textures (up to mosaic) are also observed. In garnet clinopyroxenites rutile is usually present in the form of thin (5–20 µm) needles in garnet and clinopyroxene. Eclogites are characterized by orangish or pinkish garnet color and granoblastic structure.

Garnets from lherzolites and websterites are also characterized by a relatively high Mg# content (75–83) and low TiO2 contents (up to 0.2 wt %). It belongs to the lherzolite paragenesis by content CaO (3.68 - 5.35 wt.%) and Cr2O3 (0.07-3.7 wt.%). Eclogites are characterized by high-calcium (3.78 - 9.46 wt.%) and high-iron (7.77 - 17.20 wt.%) composition of garnet getting into the ​​wehrlite paragenesis area. None of the garnet studied compositions belongs to the high-chromium dunite - harzburgite paragenesis. Also garnets from the lithospheric mantle under the Mirny kimberlite field are characterized by a low-Ti garnet composition (up to 0.7 wt.%). Thus, the lithospheric mantle under the Mirny kimberlite field differs from the lithospheric mantle under other diamondiferous fields (for example, Udachnaya kimberlite pipe). The Mirny mantle xenoliths are characterized by the pyroxenites widespread development (up to 50%), the low-Ti composition and deformed lherzolites absence. These features indicate the minimal silicate metasomatic alteration in the lithospheric mantle under the Mirny field (in contrast to the center of the Siberian craton). The isotopic oxygen composition in garnet and clinopyroxene was also determined. The δ18O value varies in Cpx from 5.7-5.8‰ in clinopyroxenites and 6.1-6.1‰ in eclogites. On the whole, minerals from pyroxenites demonstrate δ18O values exceeding mantle values, which suggests a wide development of melting processes in the lithospheric mantle in the south of the Siberian craton Craton and the formation of megacrystalline pyroxene cumulates. In some cases, metamorphic recrystallization leads to oxygen isotope equilibrium between garnet and clinopyroxene. For minerals from eclogites higher values ​​of δ18O are noted, which may indicate the origin of eclogites from subducted oceanic crust, the presence of a subduction component in the process of formation of the lithospheric mantle.

The research was supported by Russian Science Foundation grant №20-77-00074.

How to cite: Kalashnikova, T., Kostrovitsky, S., Solovieva, L., Sinitsyn, K., and Yudintseva, E.: Garnets from xenolith in Mir kimberlite pipe: chemical composition and genesis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11936, https://doi.org/10.5194/egusphere-egu22-11936, 2022.

EGU22-13248 | Presentations | GD2.4

Source and evolution of metasomatizing liquids in orogenic peridotites: evidence from multiphase solid inclusions 

Jana Kotkova, Renata Čopjaková, and Radek Škoda

Orogenic garnet peridotites exhumed in ultrahigh-pressure-ultrahigh-temperature terranes represent windows into material transfer in deep subduction zones. Multiphase solid inclusions (MSI) trapped in garnet proved to be important tracers of metasomatism by crustal-derived fluids. Our study of the MSI from the Saxothuringian basement in the Bohemian Massif, European Variscan Belt, allowed identifying the source and evolution of the liquids metasomatized the mantle rocks. As the MSI could not be re-homogenized due to a high content of volatiles, their bulk composition was estimated considering the proportions, phase densities and chemical composition of the constituent minerals.

The MSI occur in an annulus at garnet rim of garnet lherzolite and harzburgite, and throughout garnet in garnet pyroxenite. The major phases of the MSI include amphibole, barian mica and carbonate (dolomite, magnesite). Minor phases are clinopyroxene, orthopyroxene, garnet II, spinel, apatite, monazite, thorianite, graphite, pentlandite, scheelite and sulphides. The proportion of hornblende systematically decreases from pyroxenite and close harzburgite and lherzolite to more distal mantle rocks, where clinopyroxene and garnet II occur instead. By contrast, the amount of barium-bearing phases (barian mica, Ba-Mg carbonate norsethite, barian feldspar) and carbonates increases in the same direction.

Major element composition of garnet pyroxenite, including enrichment in alkalies and barium, approaches carbonate-silicate melts similar to kimberlites.  Trace element signatures indicate that it is a rare example of low-degree supercritical liquid derived from a mixed crust-mantle source frozen in the mantle. The MSI hosted by garnet in pyroxenite represent a residual solute-rich liquid after high-pressure fractional crystallization of the parental melt, enriched in alkalies (Na, K), highly incompatible elements (LILE – Ba, Sr; Th, U), LREE, Ti, W and volatiles (CO2, Cl, F, P). The MSI in peridotites allow tracing the changes of this metasomatizing liquid during its reactive infiltration into peridotite through silicate crystallization as well as interaction with mantle minerals distinct in lherzolite and harzburgite (garnet±clinopyroxene). The liquid evolved from more silicic, solute-rich to more diluted carbonate-rich, with gradual enrichment in LILE (K, Ba) and volatiles (CO2, Cl) and LREE fractionation, similar to evolution of kimberlitic to carbonatitic melts through differentiation by fractional crystallization.  

Here we demonstrate that the MSI trapped in garnet can be used as a unique tool for tracing chemical evolution of the liquids metasomatizing the mantle wedge. Importantly, these results are valid even in the case of the interaction of the trapped material (MSI) with the host garnet, as this potential contamination mainly concerns Al, Si and Cr while majority of the other elements used for petrogenetic implications remained unaffected

How to cite: Kotkova, J., Čopjaková, R., and Škoda, R.: Source and evolution of metasomatizing liquids in orogenic peridotites: evidence from multiphase solid inclusions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13248, https://doi.org/10.5194/egusphere-egu22-13248, 2022.

TS11 – Deformation unrelated to regional displacements: salt tectonics, impact geology, magma emplacement

EGU22-674 | Presentations | TS11.1

Neogene Shale Tectonics in Offshore Tarakan Basin, North East Borneo (Kalimantan): Insights from 3D Seismic Interpretation 

Aurio Erdi, Christopher A. L. Jackson, and Juan I. Soto

The geometry and evolution of continental margins can be influenced by gravity-driven, thin-skinned deformation above mobile shale. The response of the mobile shale and its overburden to gravitational collapse is complex due to: (i) spatial and temporal variations in the timing and magnitude of extension within prograding deltaic systems driving deformation; and (ii) the behavior of the weak, basal shale layer. This complexity, together with the difficulties in seismically imaging mobile shales and their strongly deformed overburden, mean we have a relatively poor understanding of the distribution and evolution of syn-sedimentary extension in large, supra-shale deltaic systems.

In this study we use a 3D pre-stack time migration (PSTM) seismic dataset located on the shelf-edge to upper slope of the Offshore Tarakan, North East Borneo. We combine our seismic-stratigraphic analysis and a detailed seismic interpretation with published well data, producing six age-constrained structural and thickness maps that document the Neogene tectonic evolutions of this shale-rich delta system. Our study reveals that the Tarakan delta system, including its underlying basal mobile shales, is deformed by a range of NE-trending shale structures, and NE-SW-striking, basinward- (i.e., eastwards) and counter-regional (i.e., westwards) dipping shale-detached (i.e., basement-decoupled) extensional faults. The extensional faults typically have a listric geometry, merging towards the top of an interval inferred to be within the mobile shales. Lateral throw distributions of each extensional listric faults appear to decrease southwestward. Hangingwall rollover-related deformation is accommodated by planar crestal faults. In relatively distal locations we document broad, shale-cored anticlines. We also observe mud volcanos and diapirs that are located above and along the shale-detached normal faults and shale-cored anticlines, respectively. Isochrone maps document complex thickness patterns through time, reflecting the complex interplay between mobile shale flow, supra-shale extension, and sea-level variations. Taken together, we identify three main tectonic stages: (i) Middle Miocene - fault nucleation, growth, and local linkage in the proximal domain, and formation of a shale-cored anticline more distally; (ii) Upper Miocene-Pliocene – lateral propagation and eventual retreat of the extensional faults, and mud diapirism; and (iii) Pleistocene-Holocene – extensional faults reactivation, decay and death, accompanied by mud volcanism.

We suggest that the extensional faults in the Tarakan delta system formed in response to Neogene tilting and gliding of supra-shale sequence in response to the uplift of Borneo. Updip extension was accommodated by and kinematically linked to, downdip contraction, and the formation of shale-cored anticlines. We speculate that mud volcanoes and shale diapirs formed above these extensional and contractional structures in response to mobile shale ascending fault- and fold-related fracture. Our careful analysis of the supra-shale faults and underlying shale structures can provide insights into the three-dimensional kinematic evolution of other mobile-shale provinces in deltaic systems, such as those characterizing North West Borneo, the Niger Delta, and the Ceduna shelf margin in Southern Australia.

How to cite: Erdi, A., Jackson, C. A. L., and Soto, J. I.: Neogene Shale Tectonics in Offshore Tarakan Basin, North East Borneo (Kalimantan): Insights from 3D Seismic Interpretation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-674, https://doi.org/10.5194/egusphere-egu22-674, 2022.

EGU22-1093 | Presentations | TS11.1

Coupling crustal-scale rift architecture with passive margin salt tectonics: a geodynamic modelling approach 

Leonardo Pichel, Ritske Huismans, Rob Gawthorpe, Jan Inge Faleide, and Thomas Theunissen

Many rifted passive margins are associated with widespread and thick evaporite (i.e., salt) deposits, and pronounced syn-and post-rift salt tectonics. The majority and largest salt basins known-to-date formed during the latest stages of rifting, immediately prior to continental breakup. We use 2D thermo-mechanically coupled finite-element modelling of lithospheric extension to investigate the interplay between variable styles of rifted margin, syn-rift architecture, and consequences for the distribution of late syn-rift salt, and post-rift salt tectonics. We simulate the formation of salt basins in different types of continental margins: narrow, intermediate, wide, and ultra-wide margins. For each of these, we evaluate: 1) the interplay between rifting, post-rift sediment progradation, base-salt topography and margin scale salt tectonics, 2) the spatial and temporal distribution of salt-related structural domains, and 3) the contrasting styles of salt tectonics for different margin types. We show that narrow and intermediate margins form partially isolated salt basins in their proximal domain with limited translation and significant vertical diapirism. Their distal portions are associated with significant translation, development of updip listric normal faults and rollovers passing downdip to squeezed diapirs. Wide and ultra-wide margins form wide salt basins with a more subtle base-salt topography which result in significant basinward salt expulsion and overburden translation towards their distal domains. These margins are characterized by updip extensional and/or expulsion rollovers and downdip salt inflation, diapirism and shortening in the form of diapir squeezing, buckle-folding and development of allochthonous salt sheets. All margins present a distal salt nappe that varies in width for each margin type and forms as a consequence of syn-rift distal salt stretching and post-rift thrusting. These models are the first to integrate lithospheric extension with long-lived post-rift salt tectonics using a geodynamically self-consistent modelling approach where the geometries of the lithosphere and salt basins are not prescribed, allowing a natural evolution of syn and post-rift deformation. They also incorporate a more realistic style of post-rift progradation using a dynamically evolving profile and present unprecedented detail for salt, syn- and post-rift stratigraphy. The results can be directly compared to examples from various salt-bearing continental margins and provide an improved understanding on the kinematics and relative timing of rift and salt deformation, and on the controls and variability of salt tectonics for different margin types.

How to cite: Pichel, L., Huismans, R., Gawthorpe, R., Faleide, J. I., and Theunissen, T.: Coupling crustal-scale rift architecture with passive margin salt tectonics: a geodynamic modelling approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1093, https://doi.org/10.5194/egusphere-egu22-1093, 2022.

Subsurface salt movement is primarily driven by differential loading, which is typically caused by tectonics or sedimentation. During glacial periods, the weight of an ice sheet may represent another source of differential loading. In salt-bearing basins affected by Pleistocene glaciations, however, it often remains unresolved if young deformations at salt structures were triggered by ice loading or represent a continuation of late Cenozoic activity. Numerical modelling can help distinguishing ice-load-induced deformation from halotectonic movement unrelated to salt-ice interaction. A prerequisite for obtaining conclusive model results is the appropriate choice of the rheological behaviours and parameters of the modelled materials.

Finite-element simulations (ABAQUS) were conducted to test and improve existing models of the interaction between salt structures and ice sheets. The models comprise two-dimensional plane-strain sections based on a simplified geological cross-section of a viscoelastic salt structure with elastic overburden and basement rocks. Different parameter sets for the rheology of salt and overburden rocks, including linear versus non-linear viscosity of the salt, were tested to gain insight into the main controlling factors.

All tested configurations show ice load-driven salt flow and deformation of the salt structure and the overburden rocks. The advance of an ice sheet towards the salt structure causes lateral salt flow away from the load into the salt structure and thus uplift at the surface above the salt structure. Complete ice coverage leads to downward displacement of the salt structure and subsidence at the surface. The downward displacement is accompanied by lateral expansion of the salt structure, which is controlled by the elasticity of the overburden rocks. After unloading, the displacements are largely restored by the elasticity of the materials. In all models, the observed deformation was limited to a few metres and no permanent reactivation of salt structures occurred. The deformation is generally larger in models with linear viscous salt than in those applying non-linear viscosity. Considering the low stress caused by a several hundreds of metres thick ice sheet and the time scales of several thousands of years, the application of a linear viscosity appears to be appropriate. The elastic parameters strongly impact the results, with lower Young's moduli leading to larger deformation. Our model results highlight the importance of a careful parameter choice, regarding both the viscous and elastic behaviour of the modelled materials.

How to cite: Lang, J. and Hampel, A.: Ice-load induced salt movement – insights into the controlling parameters from numerical modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1117, https://doi.org/10.5194/egusphere-egu22-1117, 2022.

Salt Tectonics Outcrops and 3D Drone Images from the Sivas Basin (Turkey) compared to High-Resolution Seismic Lines

Jean-Claude Ringenbach1*, Charlie Kergaravat1, Charlotte Ribes1, Alexandre Pichat2, Etienne Legeay2 & Jean-Paul Callot2

 

1 TotalEnergies s.e., Av. Larribau, 64018 Pau cedex, France.

2 LFC-R, Université de Pau et des Pays de l’Adour, Avenue de l’Université, BP 576, 64012 Pau cedex, France.

* Corresponding author: jean-claude.ringenbach@total.com

 

The outstanding outcrops of salt tectonic structures of the Sivas basin in Anatolia are now well known. A drone acquisition in November 2018 provides 3D images to visualize and interpret the structures in order to better analyze subsurface data from salt domains and since, many puctures have been acquired by the first author with a Mavic drone. Drone images, now widely used in structural geology, allow building 3D qualitative models of the outcrops. Seven structures among the most demonstrative of salt tectonics have thus been imaged in the secondary minibasins.

The Sivas basin, an elongated Oligo-Miocene north-verging multi-phased foreland basin, developed above the Neotethys suture zone. Evaporites deposited at the end of the early compression phase (Bartonian), filled the foreland basin and covered eroded thrust sheets and folds to the south. Primary minibasins formed during a period of quiescence from Late Eocene to Early Oligocene, associated to the building of an evaporite canopy. The system further evolved during convergence of the Arabian and Eurasian plates in the Late Oligocene-Early Miocene with a renewed compression on the north verging fold-and-thrust belt (FTB). This resulted in the formation of secondary minibasins, ultimately tilted and welded.

In the last decades, huge improvements in seismic imaging under thick allochthonous salt have been made in the Gulf of Mexico and Angola. Wide-azimuth towed-streamer (WATS) 2D as well as 3D seismic acquisitions allow far better imaging along steep subsalt diapiric flanks and welds. However, major drilling disappointments still do occur, due to unseen megaflaps and small-scale structures such as halokinetic sequences at various scales or small faults cannot be seen. Field analogs then become the only guide for a better assessment of the traps. Striking geometric analogies between the Sivas outcrops and seismic images from the classic petroleum provinces controlled by salt tectonics will illustrate the extraordinary quality of the Sivas basin as a geometrical field analog for the Angola and the Gulf of Mexico salt basins. Analog modelling imaged with X-ray tomography under a medical scanner will also be used for comparison.

How to cite: Ringenbach, J.-C. R.: Salt Tectonics Outcrops and 3D Drone Images from the Sivas Basin (Turkey) compared to High-Resolution Seismic Lines, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1174, https://doi.org/10.5194/egusphere-egu22-1174, 2022.

The reserves of hydrocarbon reservoirs with gypsum-salt rock as cap rock account for 55% of the total hydrocarbon reserves in the world. The influence of cap rock sealing ability is an important problem to be solved in hydrocarbon accumulation analysis. Gypsum-salt rock belongs to evaporite, which is often associated with mudstone, limestone and dolomite, resulting in extremely complex lithologic composition of gypsum-salt rock caprock. At present, the analysis of sealing capacity of gypsum-salt rock caprock lacks the distinction between gypsum rock and salt rock, and the previous comprehensive evaluation of sealing capacity of caprock mainly focuses on the macro and micro characteristics of caprock. As one of the influencing factors of sealing capacity - mechanical properties, they are ignored in the evaluation system of sealing capacity of caprock.

Based on this, the classification standard of gypsum-salt rock caprock type is established, and the gypsum-salt rock caprock is divided into "three categories and five sub categories". Comprehensively considering the macro and micro characteristics and mechanical properties of the caprock, the lithology and rock combination type, lithology zoning, cumulative thickness of dominant lithology, caprock thickness, maximum thickness of thick single layer, ground coverage ratio, internal friction coefficient, tensile strength and peak strength are selected as the evaluation factors. The analytic hierarchy process (AHP) is introduced to determine the weight of each factor, formulate the evaluation standard, and establish the evaluation system of gypsum-salt rock caprock based on AHP to realize the quantitative evaluation of the sealing capacity of gypsum-salt rock caprock.

The evaluation method is applied to the Cambrian gypsum salt caprock in Tarim Basin, China. The results show that the C value in Bachu area of Tarim Basin is between 2.6-3.9, with an average value of 3.3, and the caprock quality is good; The C value in Tazhong area is 1.8-22, with an average value of 2.0, and the sealing capacity of caprock is generally general; The C value of Tabei uplift is less than 2, and it is in the range of poor caprock as a whole. On the whole, the evaluation value of sealing capacity of gypsum-salt rock caprock in Tabei—Tazhong—Bachu area gradually increases and the sealing capacity gradually becomes better. Combining the evaluation results with the vertical distribution of hydrocarbon, the corresponding vertical display type of hydrocarbon is mainly the distribution type under salt rock, and the corresponding hydrocarbon distribution position of poor caprock is above salt. The evaluation results are highly correlated with the vertical distribution of hydrocarbon, It shows that the evaluation system is of great significance for accurately evaluating the sealing hydrocarbon ability of gypsum-salt rock caprock and guiding hydrocarbon exploration.

Keywords: gypsum-salt caprock; lithological combination; sealing ability; quantitative evaluation; Tarim Basin

How to cite: Zhao, S.: Quantitative evaluation of the sealing ability of gypsum-salt rock caprocks, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1396, https://doi.org/10.5194/egusphere-egu22-1396, 2022.

EGU22-2235 | Presentations | TS11.1

Megaflap formation and Damage recording: the case of the Cotiella Megaflap, South-Central Pyrenees. 

Marine Lartigau, Jean-Paul Callot, Charles Aubourg, and Charlie Kergaravat

Salt tectonics is responsible for typical structures associated with salt structures margins development: (i) minibasin subsidence, (ii) basin edge backfolding of basin margins, forming plurikilometric steep or overturned structures along the salt structures or their equivalent welds, called megahooks and megaflaps and (iii) smaller-scale halokinetic drape folding and composite halokinetic sequences (CHS). Mega-halokinetic structures like the megaflaps are of particular interest to us as they have been recently defined and their kinematics are poorly understood compared to those of CHS. They develop either during halokinetic drape folding, or during contractional squeezing of the diapirs or during some combination of both processes. It seems megaflaps form early in the salt reliefs development as opposed to more mature structures allowing the CHS development. Because of their geometry, megaflaps have also implications for reservoirs geometries and fluid pressures distribution, critical for successful exploration or potential storage. Megaflaps seem to have the same behaviour as detachment folds and could present same kinematics and deformations. Characterizing the multi-scale damage records, using fracturation network and matrix damage analyses, may allow us to reconstruct the megaflaps formation dynamics and to establish relationships between reservoir properties and structural evolution.

In the Cotiella Basin, recent studies have shown the role of salt tectonics associated with gravity in the creation of various minibasins during the post-rift system between the Cenomanian and the Santonian. The Cotiella minibasin s.s. presents a megaflap with vertical to completely overturned layers. The calcarenites composing this megaflap present numerous joints, veins and stylolites. The first observations and analyses show several stages of deformation, from Layer Parallel Shortening (LPS) to Late Stage Fold Tightening (LSFT) as observed in the folds. Moreover, preliminary results of matrix damage, using AMS, also indicate a record of LPS and even late deformation, LSFT, in the rocks. A detailed scenario of the damage acquisition chronology, from the multi-scale damage, is under contruction to understand the formation of this megaflap. We will then be able to compare the damage, the type of megaflap and the causal relationships such as geodynamic context and lithology with others such as the Sivas megaflap (Turkey).

How to cite: Lartigau, M., Callot, J.-P., Aubourg, C., and Kergaravat, C.: Megaflap formation and Damage recording: the case of the Cotiella Megaflap, South-Central Pyrenees., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2235, https://doi.org/10.5194/egusphere-egu22-2235, 2022.

EGU22-2767 | Presentations | TS11.1

The role of salt in mountain building, from minibasin formation to orogen dynamic 

Jean-Paul Callot, Naim Célini, Anthony Jourdon, Etienne Legeay, Frederic Mouthereau, Laetitia Le Pourhiet, and Jean-Claude Ringenbach

Evaporites levels have long been considered to have a major impact on the evolution of tectonically-driven as well as gravity-driven fold-and-thrust belts. If initially thin and planar, the role of pre-tectonic salt can be limited to an efficient décollement level during the convergence. Nevertheless, as a décollement level, pre-kinematic salt rock already deeply modifies the shape of the orogenic wedge, favouring large and low taper prisms. In addition, a thick pre-kinematic evaporite level, triggering salt tectonics from the time of the deposition on, modifies the architecture of the sedimentary packages and subordinate basins later incorporated within the orogenic wedge, creating structurally deceiving inherited geometries. Syn-orogenic salt levels also controls the fold-and-thrust belt development, favouring large scale decoupling and strain partitioning. At a much larger scale, it appears that salt levels influences also the development of the orogenic prism itself, modifying the topographical evolution of the taper. Examples from the Western Alps, the Pyrenees and the Sivas basin illustrate the various roles of salt, generating strong inheritance at almost all scales of observation. In addition, two dimensional numerical experiments of collision built by the inversion of rifted margins reveal that mechanically, a weak décollement layer formed by salt rocks delays the formation of the collisional orogen. The thicker the salt layer, the wider is the orogen and the lower the altitude of the mountain belt, leading to a quasi-absence of topography and widespread salt tectonics, which obliterates classical thrusts propagation.

How to cite: Callot, J.-P., Célini, N., Jourdon, A., Legeay, E., Mouthereau, F., Le Pourhiet, L., and Ringenbach, J.-C.: The role of salt in mountain building, from minibasin formation to orogen dynamic, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2767, https://doi.org/10.5194/egusphere-egu22-2767, 2022.

EGU22-4498 | Presentations | TS11.1

Do diapirs ever lose their heads? Insights from the Romanian Eastern Carpathians 

Dan Mircea Tamas, Alexandra Tamas, Jessica Barabasch, Mark Rowan, Zsolt Schleder, Csaba Krezsek, and Janos Urai

Numerous orogenic fold-and-thrust belts contain salt. It serves as an excellent décollement for folds and thrusts, and in some, diapirs had a profound influence on the structural styles. In salt-detached fold-and-thrust belts, decapitated diapirs can form due to thrusting but are poorly documented in the subsurface and not reported in outcrop. Here we present a surface exposure of a sub-horizontal intra-salt shear zone, which is interpreted to have formed as a result of partial decapitation of a deep-rooted salt-cored anticline. The Mânzălești diapir in the Romanian Eastern Carpathians forms the largest rock salt outcrop in Europe, with unique salt-karst geomorphology between the Tarcău and Subcarpathian nappes. Numerous wells show that the outcrop lies over a deep-seated salt diapir, the base of which is at >3500 m. Multi-scale observations using UAV-based digital outcrop models, fieldwork, and microstructure analysis show that the outcrop is characterised by sub-horizontal foliation with isoclinal folds. The halite is rich in clastic inclusions, with a power-law size distribution caused by tectonic reworking of originally dirty salt. Microstructures show that the halite matrix is strongly deformed by dislocation creep, forming subgrains with a dynamically recrystallised grain size of about 1.5 mm. This is indicative of relatively high differential stress, of around 4 MPa. After combining observations on all scales (cross-sectional, outcrop, and microstructural analyses), our preferred explanation is that the Mânzălești diapir has evolved from a salt-cored anticline to a thrusted diapir in front of the Tarcău nappe. Intense shear originating from a thrust partially decapitated the diapir, shifting its upper portion away from its base.

How to cite: Tamas, D. M., Tamas, A., Barabasch, J., Rowan, M., Schleder, Z., Krezsek, C., and Urai, J.: Do diapirs ever lose their heads? Insights from the Romanian Eastern Carpathians, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4498, https://doi.org/10.5194/egusphere-egu22-4498, 2022.

                Allochthonous salt sheets in the external SW Alps

Rod Graham₁, Sam Brooke-Barnett₁, Naïm Célini₂, Jean Paul Callot₂, Adam Csicsek₁, Lidia Lonergan₁, Jean Claude Ringenbach₃.

₁ Imperial College London ₂Université de Pau et des Pays del’Adour ₃Total Energies SE

Understanding of the importance of salt tectonics in the Alpine fold and thrust belts of Europe has evolved considerably in the last few years. Our particular area of focus has been in the sub-Alpine chains of Haute Provence, an area where initial ground-breaking work on diapirism was published many years ago by Graciansky, Dardeau, Mascle and others.

 Our own work demonstrates that salt related phenomena like minibasins, megaflaps, welds and anomalous changes in stratigraphic thickness and facies are widespread over the region, but perhaps the most startling discovery is that, at several times in the past, salt was squeezed out over topographic surfaces to form allochthonous sheets of considerable extent. The salt breakouts were mostly submarine, comparable with the allochthonous salt in the Gulf of Mexico and coincided with times of shale deposition during Oxfordian, Albo- Cenomanian and , although breakout  onto land surfaces occurred in the Tertiary.

Graham et al (2012) described an allochthonous salt sheet overlying the inverted strata of the Barre de Chine north of Digne which covered some 25sq Km of the Oxfordian seabed,. North of this structure Célini et al. (2021) describe a major allochthonous sheet rooting in the Astoin diapir. 10 sq km of this remains as gypsum and cargneule, but the original extent of the salt glacier on the Oxfordian sea floor must have been much greater since stratigraphically out of place remnants of Liassic resting on Oxfordian black shales are found 10km north of the remnant allochthonous gypsum.

Further east on the flanks of the Dome de Barrot inlier near Daluis, there is evidence of Oxfordian breakout, renewed more extensively in the Apto-Albian with an extent of at least 10 sq km. More extensive Apto-Albian breakout is associated with the Gevaudan diapir near Barreme on which secondary minibasins developed from the Late Cretaceous to the Miocene. These include the hugely rotated minibasin containing the Poudingues d’Argens conglomerate, and, we suggest, much of the Barreme basin itself. The minimum extent of this sheet was about 80sq km, though it may have been larger.  

20km to the east, Eocene breakout is indicated by an enormously expanded growth in Nummulitic  shales - a possible Roho system, with salt expelled into the active strike slip system of the Rouaine-Daluis transcurrent fault zone. The most spectacular example of Tertiary allochthonous salt, however,  is  that into which the secondary minibasin of the famous  Esclangon Velodrome sank, providing a major depocentre for  Burdigalian to Pliocene sediments. Célini et al. (in press) have documented the evolution of the Velodrome and convincingly compared it with the Tuzlagözü minibasin of the Sivas basin in Turkey. The salt glacier into which the Velodrome sank must have flowed out onto an Oligocene land surface and may be analogous with the Salt Range of Pakistan.

How to cite: Graham, R.:               Allochthonous salt sheets in the external SW Alps, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4580, https://doi.org/10.5194/egusphere-egu22-4580, 2022.

EGU22-5173 | Presentations | TS11.1

Triassic-Jurassic tectonic evolution of the Baltic sector of the North German Basin: regional extension, salt movement and large-scale uplift 

Niklas Ahlrichs, Vera Noack, Elisabeth Seidel, and Christian Hübscher

As a part of the intracontinental Central European Basin System, the Baltic sector of the North German Basin has a long and complex history of basin evolution strongly influenced by salt tectonics. In the scope of the DFG project StrucFlow, we investigate the Triassic – Jurassic phase of basin evolution of the Baltic sector of the North German Basin to deepen the understanding of regional tectonics and their relation to the initial development of Zechstein salt structures. We use a dense network of modern marine high-resolution 2D seismic profiles together with older seismic data and both onshore and offshore wells. Thereby, we strive for a detailed regional tectono-stratigraphic interpretation of Triassic and Jurassic deposits with improved stratigraphic subdivision. We interpret local thickness variations across salt structures, imaged by the seismic data, to identify phases of salt withdrawal in rim-synclines and accumulation within the salt structure. Our analysis covers the northernmost part of both the eastern Glückstadt Graben and the Eastholstein Mecklenburg Block as well as the northeastern basin margin close to Rügen Island. Relatively quiet tectonic conditions characterized by thermal subsidence during the Early and Middle Triassic persisted in the study area. In the Late Triassic, during deposition of the Keuper, Paleozoic faults were reactivated at the northeastern basin margin, which created a local depocenter with increased thickness of Keuper and Lower Jurassic deposits. We interpret this zone with increased Triassic – Jurassic sedimentary thickness as a transtensional graben system connected to deeper Paleozoic structures. Local thickness variations of Triassic units across salt structures and crestal faulting indicate initial salt movement in the eastern Glückstadt Graben and at the Kegnaes Diapir contemporaneous with the onset of Late Triassic regional extension and faulting at the northeastern basin margin. Salt movement continued at least until the early Jurassic. During the Triassic, the Eastholstein Mecklenburg Block formed a more stable area at the transition between the Glückstadt Graben and the fault systems of the northeastern basin margin. Within the Eastholstein Mecklenburg Block, salt movement started only in the latest Triassic and was of decreased intensity. From Middle Jurassic times until the Albian, the North Sea doming event subjected the study area to uplift and erosion, which removed much of the Jurassic and partly Upper Triassic deposits resulting in a study area-wide erosional unconformity.

How to cite: Ahlrichs, N., Noack, V., Seidel, E., and Hübscher, C.: Triassic-Jurassic tectonic evolution of the Baltic sector of the North German Basin: regional extension, salt movement and large-scale uplift, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5173, https://doi.org/10.5194/egusphere-egu22-5173, 2022.

EGU22-6252 | Presentations | TS11.1

The forgotten salt basin: Sivas Basin, Turkey 

Jean-Paul Callot, Jean-Claude Ringenbach, Charlotte Ribes, Charlie Kergaravat, Etienne legeay, and Alexandre pichat

Located in the center of the Anatolian Plateau in Turkey, the Tertiary Sivas Basin was built after the closure of the northern Neotethys oceanic domain from Upper Cretaceous to Pliocene times. It developed over an ophiolitic basement obducted from the north during the Late Cretaceous, initially separating the Kirshehir continental block from the Taurus microplate. During the Paleogene, the onset of the Tauride compression resulted in the development of a foreland basin within the Sivas domain, affected by north-verging thrusts reworking the foreland sequence and ophiolitic sheets. The flexural deepening of the basin resulted in the accumulation of a thick marine turbiditic succession in the foredeep area, followed by a rapid shallowing and the deposition of a thick evaporitic sequence during the late Eocene. This very special episode allowed for a second youth of the basin. Although studied for a quite long time, the Sivas Basin was indeed recently revisited as being likely the world’s finest open-air museum of salt tectonic structures. Despite huge difference with respect to known salt provinces, the Sivas basin provides outstanding outcrops of the classic geometries associated to the development of diapirs, i.e. halokinetic sequences along diapir walls, and associated stratal deformations, and more exotic structures such as bubble shaped minibasins, megaflaps and evaporites allochtonous glaciers and canopy. We will here review some of the results obtained thanks to a 5 year long project, during which the basin was dissected at the metric scale by a team including four PhD students to handle (1) the detailed mapping of a 60x30 km2 domain, (2) the coupled tectono-sedimentary analysis of the central, salt-controlled area, (3) decipher the complex and recurrent story of evaporite reworking and redeposition, (4) incorporate some matrix scale observations, and eventually (5) integrate the Sivas story within the Tethyan domain evolution. More generally, this fairy tale was also an opportunity to critically review the processes of geologic knowledge acquisition, basically here the trial and error game of building a coherent story, even based on fantastic outcrops.

How to cite: Callot, J.-P., Ringenbach, J.-C., Ribes, C., Kergaravat, C., legeay, E., and pichat, A.: The forgotten salt basin: Sivas Basin, Turkey, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6252, https://doi.org/10.5194/egusphere-egu22-6252, 2022.

In emergent salt diapirs, the volume of the salt at the surface represents an equilibrium state between the salt supplied from the underlying orifice and that lost by dissolution and erosion at the surface. Therefore, the salt volume at the surface represents the surplus of the salt supply over the dissolution and erosion neglecting any volume changes from the decompaction. Both dissolution and erosion processes occur at or near surface and can be estimated, while estimating salt supply remains challenging because it occurs at depth. At the surface, the salt moves away from the central dome above the diapir’s orifice toward the flanks by gravity spreading in the direction of the slope.

In this work, the salt volume change at the surface was estimated using Persistent Scatterer Interferometry (PSI) data to estimate the salt supply into the surface. While the salt tends to move in the direction of slopes, maximum deformation signal can be detected from the PSI data where the slope direction aligns with the line-of-sight (LOS) of satellite in the east- and west-facing slopes of salt diapirs. The salt deformation was estimated from both the east-west and up-down components of the decomposed PSI data along an east-west trending swath profile across the symmetrical Finu salt diapir to obtain salt gain (surplus) along this profile. During the PSI processing, areas with surface erosion and dissolution (sinkholes) were mostly filtered out, and the relevant salt loss was already accounted when analyzing the salt deformation.  However, the down (subsidence) signal of the analyzed PSI data in nearly horizontal areas in the flanks of the Finu diapir, where salt movement is expected to be horizontal, is assumed to be associated with the subsurface salt dissolution. The used PSI data cover a period of four years from October 2014 to December 2018.

Our results show that salt area surplus is c. 14 m2 a-1 along the profile crossing the Finu diapir. With the profile length of 4.6 km, the surplus rates along it are c. 3.1 mm a-1. The average subsidence rate on the diapirs flat flanks, which is supposed to be associated with the subsurface dissolution, was estimated at c. 1.0 mm a-1. Thus, the total supply rate along the profile is c. 4.1 mm a-1. Along the profile length, these rates mean that a total section area of c. 19 m2 a-1 of salt is added to the profile. Considering the semi-circular and symmetrical shape of the diapir and assuming uniform salt supply rates, the total volume of the salt delivered to the surface is in the order of c. 70,000 m3 a-1 from the underlying orifice. The orifice is approximately circular with a diameter of c. 1.7 km and an aperture covering c. 2.3 km2 area. This means the salt is extruded at a rate of c. 30 mm a-1 averaged over the period of four years.

How to cite: Zebari, M., Friedrich, A., Plattner, C., Rieger, S., and Parizzi, A.: Quantifying salt extrusion rates in active emergent salt diapirs from Persistent Scatterer Interferometry data and salt budget estimates: Finu Diapir in Zagros (Iran) as a case study, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6470, https://doi.org/10.5194/egusphere-egu22-6470, 2022.

EGU22-6980 | Presentations | TS11.1

The deformation of caprock on extruding salt diapirs – insights from analog and numerical modelling 

Michael Warsitzka, Michał Słotwinski, Ondřej Krýza, and Prokop Závada

Growing salt diapirs emerging at the sedimentary surface can produce outflowing salt extrusions, as observed, for instance, in many locations in the Zagros fold-and-thrust belt (Southern Iran). Flow patterns of such salt extrusions are controlled by gravity spreading and gliding. Furthermore, internal structures and shapes of salt extrusions are affected by factors like the local topography, the width of the diapir and the tectonic stress field. Many field examples of outcropping diapirs reveal, however, that the highly soluble evaporites (mainly halite) are already dissolved at the surface and that extrusions are covered by a ‘caprock’ layer, which is built of a multi-compositional residuum of less soluble minerals and rocks. Thickness, composition and mechanical properties of the caprock (density, shear strength, etc.) strongly vary between individual diapirs depending on the original composition of the salt layer, overlying host rock sediments, erosion rate, etc. Hence, the influence of such a caprock on the dynamics of the salt extrusion might also be highly variable and has not yet been investigated. It is unclear, if the caprock deforms by ductile shearing similar as viscous rock salt or if it acts as competent, brittle cover layer deforming by fracturing and brecciation during flow of the underlying salt.

We present a series of 3D analogue experiments and 2D numerical models in which we systematically investigated deformation patterns of the caprock layer during diapiric extrusion of a viscous material. In the analog experiments, we tested different types of granular materials as caprock equivalent to simulate different rheologies. Specifically, a fine-grained powder was used to mimic a competent, high-cohesive rock and a coarse-grained, low-density granulate for a less competent rock. In the numerical models, we tested a wide range of caprock parameters, such as thickness, viscosity, and shear strength. Our study is specifically focused on salt extrusions of the Iranian Zagros fold and thrust belt. Thus, the extrusion patterns in both, analog and numerical models, were tested on 1. passively growing diapirs and 2. diapirs reactivated by lateral shortening.

The results of this modelling study provide insights into the conditions (e.g. minimum thickness or strength) under which a caprock layer has a significant influence on the style of the salt extrusion or only acts as a passive veneer floating on top of the flowing salt. The model results show that a competent or thick caprock forms a polygonal fracture pattern at the beginning of the extrusion, while the separated blocks slide downslope during later stages of the extrusion. An incompetent or thin caprock rather deforms by flow, shear thinning and folding coupled to the flow of the underlying salt. These characteristics can help us to interpret deformation structures observed on natural salt extrusions, in terms of thickness and deformation behavior of the caprock.

How to cite: Warsitzka, M., Słotwinski, M., Krýza, O., and Závada, P.: The deformation of caprock on extruding salt diapirs – insights from analog and numerical modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6980, https://doi.org/10.5194/egusphere-egu22-6980, 2022.

EGU22-7092 | Presentations | TS11.1

Salt welds from up close: Examples from the Eastern Alps 

Oscar Fernández, Bernhard Grasemann, Hugo Ortner, Jacek Szczygiel, and Thomas Leitner

Salt welds are frequent features in basins with halokinesis. They are profusely observed on reflection seismic and are common features on maps of salt-rich geological provinces (even though they may not always have been identified as such). Despite this abundance, detailed studies of salt weld outcrops are remarkably scarce, in part due to outcrop conditions being hampered by vegetation and weathering. This results in a significant paucity in the description of the structure of salt welds at the meter- to centimeter-scale.

In this contribution we present our observations on three non-primary salt welds from the Northern Calcareous Alps (NCA) in the Eastern Alps, an area that evolved from a Permian-Jurassic passive margin setting to the Cretaceous-Recent Alpine orogenesis. The NCA are dominated by Triassic to Jurassic shallow to deep water carbonates, underlain by an Upper Permian evaporitic unit (mainly salt, anhydrite and shales). The evaporite unit is preserved at present mostly in broad, poorly outcropping salt bodies (salt walls?) located between blocks of Triassic platforms, and in diapirs and allochthonous bodies that are mined or quarried for halite and anhydrite. These bodies have been affected by Alpine orogenesis to different degrees, but in general present a strong contractional and/or strike-slip overprint.

In this presentation we discuss welds that are associated to two diapirs and potentially to a strongly overprinted salt wall. Outcrop conditions for the welds are outstanding, with two of these welds being observed in the galleries of two salt mines. All welds occur in Middle to Upper Triassic platform carbonates and contain no major traces of evaporites but do contain either highly sheared syn-evaporite shales or fragments of Lower to Middle Triassic post-salt sediments. Hand samples and outcrop observations have been used to describe the millimiter- to hectometer-scale structure of the welds and provide a unique insight into the detailed architecture of salt welds. Furthermore, it reveals a different tectonic evolution for each weld, with different relative contributions of halokinesis and faulting during the passive margin stage, and of re-activation during Alpine orogenesis.

How to cite: Fernández, O., Grasemann, B., Ortner, H., Szczygiel, J., and Leitner, T.: Salt welds from up close: Examples from the Eastern Alps, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7092, https://doi.org/10.5194/egusphere-egu22-7092, 2022.

EGU22-7644 | Presentations | TS11.1

Along-strike variations of salt-related structural style in the Western Alps 

Adam Csicsek, Naïm Célini, Jean-Paul Callot, Jean-Claude Ringenbach, Rodney Graham, Sam Brooke-Barnett, and Lidia Lonergan

The Upper Triassic evaporites of Western Europe, also known as the ‘Keuper’, are well-known and have been mostly considered as an efficient décollement level for the thrusts of the external fold-and-thrust belts. Numerous recent studies aimed to reappraise their role, and especially the role of salt tectonics, in the formation of several mountain belts such as the Pyrenees, the Betics, Provence, and the Alps.

The Western Alps represent a good laboratory to study the role of salt in shaping a mountain belt because it contains areas with (1) no evaporites, (2) evaporites involved as an efficient décollement level during orogeny and (3) evaporites mobilised in salt tectonics since the Lias rifting. We propose here, based on literature and our recent works regarding salt tectonics in the SW Alps, to present and discuss the different salt-related structural styles observed along-strike the Western Alps. A focus will be done on the SW Alps where evaporites influence their structure during the whole Alpine history from rifting until collision. They were mobilised by the Lias rifting through reactive diapirism. Salt tectonics carried on during the post-rift period by passive diapirism, controlled by sediment loading. A few structures were reactivated during the Oligocene and in places evaporites influenced the structure of the subalpine chains until the Mio-Pliocene.

Our study shows that evaporites strongly influence the structure of a mountain belt at different scales and that along-strike variations of structural style are observed along the strike of the Western Alps depending on the presence, the amount or the absence of evaporites.

How to cite: Csicsek, A., Célini, N., Callot, J.-P., Ringenbach, J.-C., Graham, R., Brooke-Barnett, S., and Lonergan, L.: Along-strike variations of salt-related structural style in the Western Alps, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7644, https://doi.org/10.5194/egusphere-egu22-7644, 2022.

EGU22-8216 | Presentations | TS11.1

Facies distribution along the salt diapirs of the Cotiella mini-basins (Southern Pyrenees, Spain) 

Amir Kalifi, Charlotte Ribes, Jean-Claude Ringenbach, Emmanuel Dujoncquoy, Josep Anton Muñoz, and Jean-Paul Callot

Most of the studies focusing on salt-tectonics are limited concerning high-resolution facies variations (seismic resolution/outcrop conditions) and reservoir distribution in salt diapir-flanking strata (few wells). As a consequence, many questions remain unsolved, such as the relation between the type of halokinetic sequences and the facies distribution, the interplay between sedimentary environments and the local halokinetic context. The aim of this study is to better understand spatial and temporal facies distribution and resulting sedimentary stacking pattern along the Cotiella mini-basins salt structures (Spanish Pyrenees).

Our approach is dedicated to detailed field mapping, sedimentological description of the stratigraphic succession as well as the investigation of the facies partitioning and depositional systems along within these exceptionally well exposed group of MBs. There, syn-halokinetic strata deposited during the Middle Coniacian to Early Santonian post-rift succession. Preliminary results show that:

  • The Cotiella mini-basin is characterized by a megaflap involving a 130° salt-controlled growth-strata. The Armeña mini-basin corresponds to a salt-expulsion roll-over characterized by a 80° salt-controlled growth-strata. Armeña formed mostly before Cotiella.
  • Depositional environments correspond to type-ramp mixed siliciclastic-carbonate platform. The sedimentological succession is composed by a parasequence stack characterized by proximal quartz-rich facies located mainly along the salt-weld and evolving laterally to more distal marine environments. Quartz are partly derived from the erosion of the salt-diapir, which correspond to the Keuper evaporitic facies containing authigenic quartz.
  • The stratigraphic successions of the Armena and Cotiella mini-basins is subdivided into 4 depositional sequences (S1a, S1b, S2, S3) but present specific thicknesses and facies partitioning, that suggest a strong control from the salt. These 4 sequences reveal the evolution from early to late stages of the rising salt-diapir.

Ultimately, and by integrating other mini-basins (i.e. mini-basins from the Sivas basin un Turkey), this study will help to better predict reservoir-facies and pinch-out locations along salt diapir-flanking strata.

How to cite: Kalifi, A., Ribes, C., Ringenbach, J.-C., Dujoncquoy, E., Muñoz, J. A., and Callot, J.-P.: Facies distribution along the salt diapirs of the Cotiella mini-basins (Southern Pyrenees, Spain), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8216, https://doi.org/10.5194/egusphere-egu22-8216, 2022.

EGU22-9559 | Presentations | TS11.1

Salt welding during canopy advance and shortening in the Green Canyon area, northern Gulf of Mexico 

Sian Evans, Turki Alshammasi, and Christopher Jackson

Welds form due to the tectonically-induced thinning and/or dissolution of salt, with their composition and completeness thought to at least partly reflect their structural position within the salt-tectonic system. Despite their importance as seals or migration pathways for accumulations of hydrocarbons and CO2, we have relatively few examples of drilled subsurface welds; such examples would allow us to improve our understanding of the processes and products of welding, and to test analytical models of the underlying mechanics. In this study we integrate 3D seismic reflection and borehole data from the Green Canyon Area of the northern Gulf of Mexico, USA to characterize the geophysical and geological expression of a tertiary weld, as well as its broader salt-tectonic context. These data show although it appears complete on seismic reflection data, the weld contains c. 38 m of pure halite. This thickness is consistent with the predictions of analytical models, and with observations from other natural examples of subsurface welds. Our observations also support a model whereby compositional fractionation of salt occurs as the salt-tectonic system evolves; in this model, less mobile and/or denser units are typically stranded within the deeper, autochthonous level, trapped in primary welds, or stranded near the basal root of diapirs, whereas less viscous and/or less dense units form the cores of these diapirs and, potentially, genetically related allochthonous sheets and canopies. We also show that shearing of the weld during downslope translation of the overlying minibasin did not lead to complete welding.

How to cite: Evans, S., Alshammasi, T., and Jackson, C.: Salt welding during canopy advance and shortening in the Green Canyon area, northern Gulf of Mexico, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9559, https://doi.org/10.5194/egusphere-egu22-9559, 2022.

EGU22-11211 | Presentations | TS11.1

Salt tectonic in the western subalpine foreland basin of Haute Provence? New insights on the Miocene Vélodrome syncline by a 3D geometrical modelling approach 

Agathe Faure, Laurent Jolivet, Cécile Allanic, Charles Gumiaux, Nicolas Loget, Gautier Laurent, Jean-Paul Callot, and Myette Guiomar

Recently, the understanding of the role of salt dynamics in the evolution of fold-and-thrust belts and foreland basins has significantly improved with the development of high-resolution seismics. Understanding a salt-related structure in the field as a mini-basin requires a thorough understanding of the 3-D geometries of folds.

In the western subalpine chain of Haute Provence, the Digne thrust area has undergone a complex tectonic history involving syn-sedimentary deformation, the migration of alpine front, late exhumation related to surface processes, and salt tectonics. In the front of the Digne thrust, the Vélodrome is an emblematic example of a complex fold displaying a 3D structure hardly explained by regional tectonics. The Vélodrome is an overturned syncline displaying a curved axis which direction changes from E-W in the north to N-S in the east and to E-W again in the south-eastern part. The Vélodrome is often interpreted as a growth fold with internal unconformities, but microstructural analyses (Fournier et al., 2008) have alternatively suggested a post-deposition folding. Moreover, recent studies (Graham et al., 2012; Celini, 2020) propose that the fold formed due to salt tectonics and interpret the Vélodrome as a mini-basin.

Thus, the Vélodrome complex tectonic structure requires a thorough understanding of the 3-D geometries to understand its tectonostratigraphic evolution.

This study aims at understanding the emplacement and the tectonic history of the Miocene Vélodrome series using in-situ field observations and drone field data to realize a 3-D geometrical model (GeoModeller - ©BRGM). More than 3000 structural data have been measured - both directly in the field and on 3D models obtained from drone image processing - and used in the GeoModeller to test the different hypotheses. The implicit approach offered by the GeoModeller and the field structural data-based approach bring an objective and new vision of 3-D geometries of the Vélodrome basin and confirm the Vélodrome as a syn-sedimentary fold. This study highlights several discontinuities inter- and intra-formations spatially localized. In the north of the Vélodrome, Aquitanian deposits do not present any unconformity, whereas internal unconformities can be observed in Burdigalian deposits. In the southeast of the fold, we observed internal unconformities both in the Aquitanian and Burdigalian deposits. This leads us to propose an early salt-related episode of deformation in the southeast part of the fold (Aquitanian) compared to the north, where deformation began only during the Burdigalian.

How to cite: Faure, A., Jolivet, L., Allanic, C., Gumiaux, C., Loget, N., Laurent, G., Callot, J.-P., and Guiomar, M.: Salt tectonic in the western subalpine foreland basin of Haute Provence? New insights on the Miocene Vélodrome syncline by a 3D geometrical modelling approach, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11211, https://doi.org/10.5194/egusphere-egu22-11211, 2022.

EGU22-11751 | Presentations | TS11.1

Late Miocene-Quaternary diapiric activity in the SW Iberian Margin: Interaction between salt and shale structures and deep-water sedimentation 

Débora Duarte, F. Javier Hernández-Molina, Vitor Hugo Magalhães, Cristina Roque, and Zhi Lin Ng

The southwestern margin of Iberian (SWIM) underwent a complex tectonic evolution, related to its proximity to the plate boundary between Africa and Europe, and the Betic-Rif Orogeny. The Algarve, Doñana, Sanlucar and Cadiz Basins developed on the Betics’ foreland since the late Miocene, and their sedimentary infill is composed of deep-water turbiditic, hemipelagic and contourite deposits. This work aims to understand the influence of diapiric structures on the development and evolution of deep-water sedimentation associated with these sedimentary basins. It has been accomplished with the analysis of regional 2D and 3D seismic datasets and a chronological framework from well data.

Extensive diapiric activity was recorded throughout the Late Miocene-Quaternary basins. Salt and shale structures were identified characterized by their internal transparent to chaotic reflections with moderate to low amplitude. Three types of diapirs were observed: i) squeezed, vertical diapiric stocks, ii) vertical elongated diapirs related to compressive deformation, and iii) salt-cored normal faults. Eight diapiric pulses occurred during the late Miocene-Quaternary timeframe. Deep-water sedimentation is influenced by these diapiric pulses in two ways: i) diapiric-related reliefs on the seafloor control down- and along-slope current circulation, and consequently the turbidite and contourite sediment distribution and their deposits architecture, and by ii) changeable accommodation space: depocenter size and capacity for sediment accumulation are variable over time, being directly related to the intensity of the diapiric activity. Contourite deposits also respond to changes in depocenter characteristics by altering drifts geometry and size, from sheeted to mounded to confined, with the increasing intensity of diapiric activity.

This work demonstrates the influence of diapirism in shaping the seafloor paleo-morphology, with diapiric-related reliefs and depocentres, controlling the distribution of deep-water depositional systems. Thus, this study emphasizes the importance of an integrated basin analysis, considering sediment supply, regional tectonics, including diapiric activity, as well as climatic and sea-level variations in controlling deep-water sedimentation.

 

Acknowledgements: D.D. thanks the Portuguese Foundation for Science and Technology (FCT) for a PhD scholarship (reference SFRH/BD/115962/2016). This research has been conducted under the framework of ‘The Drifters Research Group’, Department of Earth Sciences, Royal Holloway University of London (UK). We thank DGEG (Direção-Geral de Energia e Geologia) and Dr. José Miguel Martins for the supply of the 3D seismic dataset. The bathymetric data used in this work is from the European Marine Observation and Data Network (EMODnet) Bathymetry Project (http://www.emodnet.eu/bathymetry).

How to cite: Duarte, D., Hernández-Molina, F. J., Magalhães, V. H., Roque, C., and Ng, Z. L.: Late Miocene-Quaternary diapiric activity in the SW Iberian Margin: Interaction between salt and shale structures and deep-water sedimentation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11751, https://doi.org/10.5194/egusphere-egu22-11751, 2022.

EGU22-12073 | Presentations | TS11.1

Messinian salt deformation offshore Algeria: the role of crustal tectonics and sedimentary load on the observed geometries 

Gaia Travan, Virginie Gaullier, Bruno C. Vendeville, and Jacques Déverchère

The Algerian margin (Western Mediterranean) reactivated in compression 8 My ago due to the convergence between Africa and Eurasia, and is nowadays subjected to a strain regime of several mm/y, resulting in destructive earthquakes as the M 6.8 Boumerdès event in 2003.

The MARADJA I seismic reflection data acquired in 2003 allowed to image in detail the Messinian Salinity Crisis Mobile Unit (mostly halite) and its brittle sedimentary overburden offshore Algiers. Particularly interesting in the area are the salt-related geometries and the presence of crustal tectonic structures -consequence of the compressional setting of this margin- that created an uplifted plateau offshore Algiers (Déverchère et al., 2005; Domzig et al., 2006). The comparison with the MARADJA II (2005) data offshore Béjaia allowed to better distinguish between the regional trends and the local peculiarities.

Together with the general analysis of the structures due to the salt tectonics, as well as the influence of crustal tectonics on salt deformation on the Algerian margin, this study is particularly focused on the geometry, position and triggering processes of a localized minibasins field, which started to form very early –possibly before the end of the Messinian Salinity Crisis- and is still active nowadays. This minibasins field position corresponds to both the external limit of a sedimentary body and the western limit of the previously mentioned uplifted plateau, raising the question of the relative influence of these two contributing factors in the formation of the minibasins. The analogue modelling contribution in this analysis is crucial.

How to cite: Travan, G., Gaullier, V., Vendeville, B. C., and Déverchère, J.: Messinian salt deformation offshore Algeria: the role of crustal tectonics and sedimentary load on the observed geometries, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12073, https://doi.org/10.5194/egusphere-egu22-12073, 2022.

EGU22-12981 | Presentations | TS11.1

Fault reactivation and halokinesis: an example from the Penobscot 3D seismic volume, offshore Nova Scotia, Canada 

Alexander Peace, Christian Schiffer, Scott Jess, and Jordan Phethean

Polyphase deformation on passive margins, including fault reactivation, has been documented globally. These processes form complex structures that can be integral to petroleum systems and can provide essential constraints on the kinematic and structural evolution of rifts and passive margins. In some cases, inversion structures can also be used as global markers for far-field stress changes and help us to understand how plate tectonics operates on Earth. Despite the importance of reactivated faults, their identification, extent mapping, controls on kinematic evolution, and knowledge of interaction within fault populations are often poorly constrained. As such, there is need for detailed investigations of such structures, including their relationship with halokinesis, which can lead to complex and sometimes misleading structural observations.

We present a new structural interpretation of the Penobscot 3D seismic reflection survey, and associated relay ramp, imaged offshore Nova Scotia, Canada, down to ~3.5 s TWT, constrained by two exploration wells. The relay ramp comprises two dominant faults that dip approximately SSE and are associated with smaller antithetic and synthetic faults. The wider fault population is dominated by ~ENE-WSW striking normal faults that dip both NNW and SSE. The two major normal faults display evidence for reverse deformation in their lower portions (below ~2.5 s TWT), which manifests as anticlinal folding and reverse offsets. However, in their upper portions the faults display normal offset. Smaller faults tend to only affect the uppermost strata and do not show evidence of reactivation. Analysis of fault throw demonstrates that movement on the two main faults was coupled during both the reverse and normal deformation intervals. Through our structural analysis and previous regional interpretations of widespread salt kinesis, we determine that the observed style of deformation likely occurred due to normal (extensional) reactivation of reverse faults that had initially formed due to halokinesis of underlying salt. The timing of salt movement broadly corresponds to documented times of kinematic reorganisation on many Atlantic margins, and thus salt kinesis may have been in response to this. The kinematic dichotomy with depth along the two dominant faults is important to document as this style of polyphase reactivation may go unrecognised where seismic data does not image the full depth of a structure. Therefore, reactivation may be more widespread than previously thought if only uppermost parts of structures have been imaged. The interpretation of salt as an important contributor to kinematic reactivation of faults is crucial as it likely provides a mechanism to explain inversion at many other locations globally.

How to cite: Peace, A., Schiffer, C., Jess, S., and Phethean, J.: Fault reactivation and halokinesis: an example from the Penobscot 3D seismic volume, offshore Nova Scotia, Canada, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12981, https://doi.org/10.5194/egusphere-egu22-12981, 2022.

EGU22-216 | Presentations | GMPV9.4

Exploring the mechanical influence of mush poroelasticity on volcanic surface deformation 

Rami Alshembari, James Hickey, Ben J. Williamson, and Katharine Cashman

Understanding the mechanical behaviour of melt reservoirs is vital for advancing geophysical models that aim to constrain the evolution of subvolcanic systems and inform hazard monitoring and mitigation. From geophysical and petrological studies, large melt-dominated (magma) reservoirs are difficult to sustain over long periods of time. Melt is more likely to reside within reservoirs which consist of variably packed frameworks of crystals, so-called crystal mush, as well as in pockets of magma, in changing proportions over time. The behaviour of crystal mush, in particular, is emerging as a vital consideration in understanding how magmatic systems evolve. In addition, current models for volcano deformation often consider static magma sources and thus provide little insight into the internal dynamics of melt reservoirs; and these models ignore the presence of crystals and therefore the likely poroelastic mechanical response to melt intrusion or withdrawal. Our study considers the melt reservoir to be partly crystalline (> 50% crystal fraction), with melt residing between crystals. We examine the influence of poroelastic mechanical behaviour on the evolution of reservoir pressure and the resultant surface deformation. From our results, the modelling of a crystal mush rather than a 100% melt magma reservoir can significantly modify the resulting spatial and temporal mechanical evolution of the system. Specifically, the poroelastic behaviour of a mush reservoir will continue to develop following the end of a melt injection period, generating further time-dependent surface displacements. Post-injection and post-eruption inflation can occur, which are linked to a poroelastic response associated with continuous melt diffusion. Following an injection/eruption, a steady-state point is eventually achieved when the fluid pressure reaches a uniform value throughout the reservoir. This process is controlled by the poroelastic diffusivity. Increasing the reservoir crystal fraction from 50% to 90% reduces the mobility of melts, decreases permeability, and leads to a slow rate of melt diffusion. Our study confirms that volcanic surface deformation can occur without continued intrusion or withdrawal of melt.

How to cite: Alshembari, R., Hickey, J., J. Williamson, B., and Cashman, K.: Exploring the mechanical influence of mush poroelasticity on volcanic surface deformation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-216, https://doi.org/10.5194/egusphere-egu22-216, 2022.

EGU22-583 | Presentations | GMPV9.4

Contribution of the use of a plate model to calculate the stresses at large silicic systems 

Alexandra Morand, Stephen Tait, and Geneviève Brandeis

Large silicic systems can produce devastating eruptions with emitted volumes greater than 100 km³ and worldwide impacts. Such eruptions suggest the presence of significant reservoirs of silicic magma at shallow depths. Understanding how these reservoirs form is crucial to understanding how they affect the surrounding rock. But the shape and the organization of magmatic storage are still debated, despite their crucial influence on the results of theoretical predictions. Based on physical considerations of silicic-magma properties and the continental-crust state of active systems; our hypothesis is that the rise of silicic magma is stopped by the Brittle Ductile Transition. As the relaxation time of the ductile part of the crust is very short compared to the lifetime of such systems, magma storage could be considered as a buoyant liquid stored beneath an elastic plate. We thus used a plate model to theoretically predict the stress above those large magma chambers. To test our hypothesis, we computed the general behaviours of large silicic systems and compared them to natural cases. We first calculated the stress field produced in the plate. Results show that stressed values can reach tens of MPa, which is enough to cause plate failure. Then, we compared reservoir dimensions and volumes predicted by our model when failure could occur with documented ones for past eruptions. We showed that the two are consistent with each other. In a broader perspective, we then showed that stresses produced in the plate by the magma chamber can produce circular faults above the storage zone. This result has direct implications for the understanding of caldera formation during large silicic eruptions.

How to cite: Morand, A., Tait, S., and Brandeis, G.: Contribution of the use of a plate model to calculate the stresses at large silicic systems, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-583, https://doi.org/10.5194/egusphere-egu22-583, 2022.

EGU22-607 | Presentations | GMPV9.4

Integrated Multi-scale approach for constraining source parameters responsible of deformation field in volcanic framework. 

Andrea Barone, Maurizio Fedi, Antonio Pepe, Susi Pepe, Giuseppe Solaro, Pietro Tizzani, and Raffaele Castaldo

The monitoring and characterization of volcanic systems are performed through measurements of different nature; among these, the development of the remote sensing technologies has supported the analysis and interpretation of the ground deformation field, for which the Differential SAR Interferometry (DInSAR) technique provides a large amount of densely sampled measurements over space and time (Dzurisin, 2007). The modeling of these datasets leads to understand the changes of physical and geometrical parameters of deep and/or shallow volcanic reservoirs by using different strategies, such as the forward (Lu et al., 1998), the parametric (Battaglia et al., 2013) and tomographic (Camacho et al., 2020) inverse modeling. Unfortunately, these methods could bring to ambiguous interpretation of deformation measurements because of ambiguities of inherent, theoretical, algebraic, instrumental/experimental nature.

Here, we model the deformation field in volcanic framework through a different approach, which is mainly based on harmonic elastic fields satisfying the homogeneity laws; in particular, we use multi-scale procedures, such as the Multiridge (Fedi et al., 2009) and ScalFun (Fedi et al., 2007) methods, and boundary analysis technique, such as the Total Horizontal Derivative (THD) (Blakely, 1996), for unambiguous estimate of the geometrical parameters of the deformation sources, which are the depth, the horizontal position, the shape and the horizontal extent.

Starting from the harmonic solutions of the Navier’s equation, Castaldo et al. (2018) and Barone et al. (2019) have shown that multi-scale methods are valid tools to study simple field sources as the Mogi one, according to the homogeneity law and the Euler’s equation. To generalize this approach, we show the use of multi-scale methods to model sources with any geometry, also irregular. We test our methodology, which is an integration of multi-scale techniques, on Finite Element synthetic deformation field generated through Comsol Multiphysics software package; we consider both regular and irregular geometry cases by analysing different deformation component estimating the source geometry without any reference model.

Finally, we use the proposed approach to investigate the ground deformation pattern of the 2004 – 2010 uplift episode occurred at Yellowstone caldera resurgent domes area and the 2013 unrest event at Fernandina volcano (Galapagos Archipelago, Ecuador); in the first case, we use the vertical component and the integrated multi-scale approach to highlight the geometrical irregularities of the retrieved sill-like intrusion; in the second case, we analyse the E-W component retrieving a ≈ 1.5 km b.s.l. deep pipe-like source.

We conclude that our approach is crucial for retrieving an unconstrained geometrical model of the deformation source.

How to cite: Barone, A., Fedi, M., Pepe, A., Pepe, S., Solaro, G., Tizzani, P., and Castaldo, R.: Integrated Multi-scale approach for constraining source parameters responsible of deformation field in volcanic framework., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-607, https://doi.org/10.5194/egusphere-egu22-607, 2022.

Lava dome collapse hazards are intimately linked with their morphology and internal structure. We present new lava dome emplacement models that use calibrated rock strengths and allow material behaviour to be simulated for three distinct units: (1) a ductile, fluid core; (2) a solid upper carapace; and (3) disaggregated talus slopes. We first show that relative proportions of solid and disaggregated rock depend on rock strength, and that disaggregated talus piles can act as an unstable substrate and cause collapse, even in domes with a high rock strength. We then simulate sequential dome emplacement, demonstrating that renewed growth can destabilise otherwise stable pre-existing domes. This destabilisation is exacerbated if the pre-existing dome has been weakened following emplacement, e.g., through processes of hydrothermal alteration. Finally, we simulate dome growth within a crater and show how weakening of crater walls can engender sector collapse. A better understanding of dome growth and collapse is an important component of hazard mitigation at dome-forming volcanoes worldwide.

How to cite: Harnett, C. and Heap, M.: Exploring lava dome mechanics & structure: how does stability change as a function of rock strength?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-691, https://doi.org/10.5194/egusphere-egu22-691, 2022.

EGU22-1431 | Presentations | GMPV9.4 | Highlight

An analytical model for the ascent speed of a viscous fluid batch in three dimensions 

Timothy Davis and Eleonora Rivalta

There are few analytical models of 3D dyke ascent due in part to the algebraic complexity of deriving such solutions but also due to a lack of numerical schemes that can be used to test the validity of their simplifying assumptions. Recent developments in hydro-fracture codes allow for numerical simulation of constant inflow/finite batches of fluid rising towards the ground surface (Zia and Lecampion, 2020). Such schemes allow us to formulate and test some analytical approximations of this process.

Recently, analytical formulations have reproduced in three dimensions the self-sustaining ascent of a batch of fluid, where a fracture ascends upwards once a given “critical" volume of fluid is injected (Davis et al., 2020; Salimzadeh et al., 2020; Smittarello et al., 2021). The critical volume is dependent on: the rock stiffness, the density contrast between the fluid and rock and the rock toughness. Such formulations have been verified numerically, showing that relatively small batches of fluid are required before these begin to ascend towards the ground surface. In particular, these estimated critical volumes are below observed eruptive volumes and far below typical industrial fluid injection volumes. We investigate how accounting for fluid flow in the model can lead to better estimates of the critical volumes, ascent timescales and the fracture size.

We first detail an approximation of the ascent speed for a given volume of fluid, deriving an approximate maximum ascent speed of a fracture. We show this speed is linearly proportional to the injected volume and inversely proportional to the material stiffness and fluid viscosity. Secondly, we adapt the 2D similarity solution of Spence and Turcotte (1990), showing how to scale this in 3D. This solution describes how the ascent speed decelerates from its initial velocity. We note that in particular the decay in the front velocity is dependent on volume (V) and time (t) with the following scaling V(1/2)/t(2/3). Our resulting analytical solution matches well to decay speeds from 3D numerical experiments with a finite fluid batch. We discuss the implications this scaling has on the ascent speed of magmatic intrusions and the stability of industrial operations.

Lastly, we briefly discuss formulations describing how density, stress and stiffness interfaces can trap ascending fractures.

Davis, T., Rivalta, E. and Dahm, T., 2020. Critical fluid injection volumes for uncontrolled fracture ascent. Geophysical Research Letters, 47(14), p.e2020GL087774.

Salimzadeh, S., Zimmerman, R.W. and Khalili, N., 2020. Gravity Hydraulic Fracturing: A Method to Create Self‐Driven Fractures. Geophysical Research Letters, 47(20), p.e2020GL087563.

Smittarello, D., Pinel, V., Maccaferri, F., Furst, S., Rivalta, E. and Cayol, V., 2021. Characterizing the physical properties of gelatin, a classic analog for the brittle elastic crust, insight from numerical modeling. Tectonophysics, 812, p.228901.

Spence, D.A. and Turcotte, D.L., 1990. Buoyancy‐driven magma fracture: A mechanism for ascent through the lithosphere and the emplacement of diamonds. Journal of Geophysical Research: Solid Earth, 95(B4), pp.5133-5139.

Zia, H. and Lecampion, B., 2020. PyFrac: A planar 3D hydraulic fracture simulator. Computer Physics Communications, 255, p.107368.

How to cite: Davis, T. and Rivalta, E.: An analytical model for the ascent speed of a viscous fluid batch in three dimensions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1431, https://doi.org/10.5194/egusphere-egu22-1431, 2022.

EGU22-2480 | Presentations | GMPV9.4

The Deformation Style of Somma-Vesuvius 

Bruno Massa, Raffaele Castaldo, Luca D’Auria, Ada De Matteo, Michael R. James, Stephen J. Lane, Susi Pepe, and Pietro Tizzani

The Somma-Vesuvius volcano is one of the most dangerous on the Earth due to its proximity to the city of Napoli (Southern Italy). The volcanic edifice has a typical asymmetric shape: the truncated cone of Mt.  Somma topped by the Vesuvius “Gran Cono”. Somma-Vesuvius last erupted in 1944 and is currently quiescent, experiencing fumarolic activity, low-energy seismicity and slow ground deformation (subsidence of the edifice itself and uplift in the surrounding area). Understanding the deformation style of Somma-Vesuvius and the corresponding long-term structural evolution allows inferences about volcanic activity and associated hazards. A large amount of data has already been collected about Somma-Vesuvius. Nevertheless, the deformation style affecting its volcanic edifice is still matter of debate. We present results of an integrated numerical-analogue modeling approach aimed at refining the current state of deformation of this volcano. Numerical models were built using a Finite Element (FE) method, implemented with a three-dimensional time-dependent fluid-dynamic approach, representative of both 1:100,000 and 1:1 scales. A wide range of laboratory analog models were built at a scale of 1:100,000, using sand mixtures as brittle medium and polydimethylsiloxane as a ductile one. A comparison with the actual Somma-Vesuvius deformation velocity patterns, obtained by differential interferometric synthetic aperture radar (DInSAR) and GPS measurements, allowed the selection of a pair of analog/numerical models that faithfully reproduced the field and remote sensing observations. The modeling procedure adds new constrains supporting a combined gravitational spreading-sagging process governing the deformation of the Somma-Vesuvius volcano. This conclusion has a critical consequence: the recognized deformation processes support the presence of a tensional regime. This has the potential implication of reducing the loading stress on the magmatic reservoir system and, consequently, of decreasing the Volcanic Explosive Index of eruptive events. The refined knowledge of the actual deformation process affecting Somma-Vesuvius should be a key contribution to a reliable volcanic surveillance system.

How to cite: Massa, B., Castaldo, R., D’Auria, L., De Matteo, A., James, M. R., Lane, S. J., Pepe, S., and Tizzani, P.: The Deformation Style of Somma-Vesuvius, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2480, https://doi.org/10.5194/egusphere-egu22-2480, 2022.

EGU22-2639 | Presentations | GMPV9.4

Quantification of Volcano Deformation caused by Volatile Accumulation and Release 

Arne Spang, Mike Burton, Boris Kaus, and Freysteinn Sigmundsson

Magma stored in the crust may exsolve a significant amount of volatiles, primarily CO2, but also H2O and SO2 if cooling promotes crystallisation and volatile exsolution. These volatiles may, over time, segregate and accumulate into a gas-rich foam at the roof of the magma body. This is the underpinning process to explain the frequently observed ‘excess gas’ produced in explosive eruptions, where the amount of erupted SO2 is much larger than can be explained by the mass of erupted products and the initial dissolved S content.

Here, we examine and quantify the buoyancy force exerted on the crust due to the presence of accumulated volatiles in the roof of a magma reservoir of exsolved volatiles. This foam has a significantly lower density than magma or the crust, and will therefore produce a buoyancy force which will manifest as deformation of the volcanic edifice above. A key concept in this work is that the accumulation of the foam layer may occur slowly over long time periods and therefore be challenging to detect. However, upon eruption, the gas phase will be suddenly lost, and the removal of the buoyant volatiles will result in syn-eruptive subsidence, in addition to that expected from the eruption of lavas.

We present three-dimensional, visco-elasto-plastic, thermomechanical modeling results which quantify the ground deformation arising from the growth and sudden release of a volatile reservoir. We find that the deformation is independent from the thermal structure of the crust and the shapes of the volatile and magma reservoirs. Instead, it is a function of the volume, density and depth of the volatile reservoir and crustal rigidity. This allows us to derive a scaling law for the volatiles’ contribution to syn-eruptive subsidence.

Applying our scaling law to the April 2015 eruption of the Chilean stratovolcano Calbuco, together with estimates of the pre-accumulated volatile mass, suggests that up to 25% of the observed syn-eruptive subsidence can be explained by the release of a buoyant reservoir of exsolved volatiles. Our results highlight the key role that volatile-driven buoyancy can have in volcano deformation and show a new link between syn-eruptive degassing and deflation. They also highlight that shallow gas accumulation and release may have a major impact on ground deformation of volcanoes and can serve as an explanation for inflation/deflation of up to a few cm.

How to cite: Spang, A., Burton, M., Kaus, B., and Sigmundsson, F.: Quantification of Volcano Deformation caused by Volatile Accumulation and Release, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2639, https://doi.org/10.5194/egusphere-egu22-2639, 2022.

EGU22-2704 | Presentations | GMPV9.4 | Highlight

Structural failure and shallow dike intrusion at Nyiragongo volcano (D.R Congo) 

Delphine Smittarello, Julien Barrière, Nicolas d'Oreye, Benoit Smets, Adrien Oth, Caroline Michellier, Tara Shreve, Raphael Grandin, Valérie Cayol, Christelle Wauthier, Dominique Derauw, Halldor Geirsson, Nicolas Theys, Hugues Brenot, Jean-Luc Froger, Adalbert Muhindo, and François Kervyn

After January 1977 and January 2002, the third historically known flank eruption of Nyiragongo volcano and the first ever to be recorded by dense measurements both on the ground and from space started on the 22nd of May 2021, although no alarming precursory unrest had been reported. Nyiragongo lava flows threatened about 1 million of inhabitants living in the cities of Goma (Democratic Republic of Congo) and Giseny (Rwanda).

In the following days, seismic and geodetic data as well as fracture mapping revealed the gradual southward propagation of a shallow dike from the Nyiragongo edifice underlying below Goma airport on May 23-24, then Goma and Gisenyi city centers on May 25-26 and finally below the northern part of Lake Kivu on May 27. Southward migration of the associated seismic swarm slowed down between May 27 and June 02. Micro seismicity became more diffuse, progressively activating transverse tectonic structures previously identified in the whole Lake Kivu basin.

Here we exploit ground based and remote sensing data as well as inversion and physics-based models to fully characterize the dike size, the dynamics of dike propagation and its arrest against a structural lineament known as the Nyabihu Fault. This work highlights the shallow origin of the dike, the segmented dike propagation controlled by the interaction with pre-existing fracture networks and the incremental crater collapse associated with drainage which led to the disappearance of the world’s largest long-living lava lake on top of Nyiragongo.

How to cite: Smittarello, D., Barrière, J., d'Oreye, N., Smets, B., Oth, A., Michellier, C., Shreve, T., Grandin, R., Cayol, V., Wauthier, C., Derauw, D., Geirsson, H., Theys, N., Brenot, H., Froger, J.-L., Muhindo, A., and Kervyn, F.: Structural failure and shallow dike intrusion at Nyiragongo volcano (D.R Congo), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2704, https://doi.org/10.5194/egusphere-egu22-2704, 2022.

EGU22-3238 | Presentations | GMPV9.4

Making space for magma fingers and sheet intrusions: the importance of intrusion tip velocities 

Jonas Köpping, Alexander R. Cruden, Craig Magee, Samuel Thiele, Anja Slim, and Andrew Bunger

Magma transport through the Earth’s crust is commonly described to occur through interconnected planar sheet intrusions such as dykes and sills, which form so called magma plumbing systems. Elongate intrusion geometries (i.e., magma fingers and segments), hereafter referred to as elements, may form during magma transport due to viscous and/or elastic instabilities at the propagating intrusion tip, and they are often observed at the outer margin of solidified sheet intrusions. Field observations, geophysical datasets, and analogue models further show that when elements grow in width, they can coalesce, indicating that planar sheet intrusions can form and grow by the amalgamation of individual elements. Previous studies suggest that the emplacement and growth of elements is accommodated by one dominating emplacement end-member process, namely: i) tensile-elastic fracturing, ii) shear failure, or iii) viscous deformation (e.g., host rock fluidisation). However, the interplay between individual end-member processes remains poorly understood. Here we present field observations of elongate magma fingers located at the SE margin of the Paleogene Shonkin Sag laccolith (Montana, USA) to assess how host rocks (Cretaceous Eagle Sandstone) deform to make space for the magma. We combine drone photogrammetry surveys with field mapping and microstructural analyses to describe and quantify host rock deformation in the vicinity of 37 magma fingers, and we conduct thermal modelling to further evaluate the conditions at which viscous deformation due to host rock fluidisation is feasible.

Our field observations show that all three proposed end-member processes accommodated the emplacement of magma fingers at the SE margin of the Shonkin Sag laccolith. Brittle deformation, shear failure, and folding of host rock mainly occurs in the compressional regime between two adjacent magma fingers, whereas host rock fluidisation and mobilisation is predominantly observed at the cross-sectional, lateral finger tips. Our photogrammetric analyses show that up to 40 % of the finger thickness is accommodated by elastic host rock uplift. Critically, this range of host rock deformation mechanisms is observed in one outcrop at metre scale, and in some cases associated with an individual magma finger. Thermal modelling of temperatures ahead of a propagating intrusion tip indicates that intrusion induced host rock fluidisation is only possible at low tip velocities of ≤ 10-5 m/s, which can vary depending on the emplacement depth, magma temperature, and the thermal diffusivity of the host rock.

Overall, we conclude that the emplacement of magma fingers at the outer margin of the Shonkin Sag laccolith was accommodated by a combination of elastic host rock uplift and both brittle and ductile host rock deformation. Based on our field observations and thermal modelling results, we suggest that intrusion tip velocities and the resulting strain rate are key parameters that control the dominating space-making mechanisms during magma emplacement. Due to the elongate geometry of elements and the resulting different strain rates at their lateral and frontal tips, we further propose that deformation mechanisms observed at lateral tips in cross sectional outcrops are likely decoupled from those at frontal tips such that they may not be equivalent.

How to cite: Köpping, J., Cruden, A. R., Magee, C., Thiele, S., Slim, A., and Bunger, A.: Making space for magma fingers and sheet intrusions: the importance of intrusion tip velocities, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3238, https://doi.org/10.5194/egusphere-egu22-3238, 2022.

EGU22-3579 | Presentations | GMPV9.4

The influence of the 2018 Lombok earthquake sequence, Indonesia on the unrest Rinjani volcano inferred from InSAR time-series analysis 

Siyuan Zhao, Simon McClusky, Meghan Miller, Phil Cummins, and Matt Garthwaite

Rinjani volcano is a highly active volcano located on Lombok Island in eastern Indonesia which has experienced ten eruptions in the last 100 years. Between 2014 and 2020, this stratovolcano has erupted twice, on 25th October 2015; and on 1st August 2016. Both eruptions lasted approximately two months, with activity concentrated in the volcanoes central Barujari Crater region. In 2018, four deadly (Mw 6.2 to 6.9) earthquakes struck the north coast of Lombok Island on 28th July, 5th August, and 19th August, causing hundreds of fatalities and extensive damage. These earthquakes also resulted in the remobilization of ash deposits on the flanks of Rinjani volcano located on the north island as landslides. Our InSAR-based finite fault rupture modelling suggests the estimated maximum fault slip of 1.4 m, 2.3 m, and 2.5 m for the three mainshocks located on southward dipping fault planes to the northwest-northeast of the Rinjani volcano occurred at depths of ~15 km, 12 km, and 32 km, respectively. Coulomb stress change modelling based on the these rupture models indicates about 1 MPa of extensional stress change at 10 to 20 km of depth around the crater region was observed, which may promote opening of the magma conduit. The short distance between the peak slip region and the volcano, as well as the stress change, raises the question of whether the earthquake sequence may have influenced the spatio-temporal deformation pattern of the Rinjani volcano.We use an InSAR time-series, consisting of 658 descending and 370 ascending Sentinal-1 interferograms to investigate the time-dependent inflation and deflation signals around the crater region generated by the 2015, 2016 eruptions and the 2018 earthquakes. We analyse the average inflation/deflation rate and the cumulative displacements in different periods between 2014 and 2020 to quantify the volcano deformation before and after the 2018 earthquake sequence. Our preliminary results reveal that the crater region has undergone rapid inflation of up to 20 mm/yr through the 2014 to 2017 period, before significantly slowing to ~10 mm/yr over the 2017 to 2018 period. During the first three months following the 2018 earthquake sequence, a noticeable deflation of the edifice was detected, followed by gentle inflation lasting until late 2020. These results imply that the influence of the 2018 earthquakes acted to reduce the pressure in the reservoir, at least temporarily. We will present results from modelling the volume change and the location of the volcano pressure source for better understanding how changes in the magma body and magma movement may have been influenced by the 2018 Lombok earthquake sequence.

How to cite: Zhao, S., McClusky, S., Miller, M., Cummins, P., and Garthwaite, M.: The influence of the 2018 Lombok earthquake sequence, Indonesia on the unrest Rinjani volcano inferred from InSAR time-series analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3579, https://doi.org/10.5194/egusphere-egu22-3579, 2022.

EGU22-3623 | Presentations | GMPV9.4 | Highlight

Flank instability at Mount Etna: new insights from seafloor deformation monitoring 

Morelia Urlaub, Florian Petersen, Alessandro Bonforte, Felix Gross, and Heidrun Kopp

Coastal and ocean island volcanoes are renowned for having unstable flanks, which expresses as slow seawards flank sliding observable by geodetic techniques and/or catastrophic sector collapses. A large section of these unstable flanks is often below sea level, where information on the volcanotectonic structure and, in particular, ground deformation are limited. Consequently, kinematic models that attempt to explain measured onshore ground deformation associated to flank instability are poorly constrained in the offshore area. This is also the case for Mount Etna’s unstable south-eastern flank that slides seawards at rates of 2-3 cm/yr. Displacements associated to flank movement, observed onshore by geodetic and remote sensing techniques, show maximum values at the coast and kinematic models consistently predict even larger movements seawards of the coast. Our seafloor geodetic measurements between 2016 and 2018 confirmed that offshore flank slip is equal or slightly larger compared to onshore slip. The main displacement was released during one slow slip event. Here, we present new data from a second deployment of the seafloor geodetic network in the same location with the same direct-path acoustic ranging technique and a modified network design. The measurements allow reconstructing relative seafloor displacement within the network at sub-centimetre precision, from September 2020 until November 2021. The preliminary results indicate a possible eastward sliding of the flank, although the overall slip of <1 cm is close to the limit of resolution. Flank slip is continuous over the observation period. With our seafloor geodetic network, we are able to record different styles of fault slip and deformation rates. Ongoing long-term monitoring will show how these styles of deformation interact, and which type of flank movement is dominant in the offshore sector.

How to cite: Urlaub, M., Petersen, F., Bonforte, A., Gross, F., and Kopp, H.: Flank instability at Mount Etna: new insights from seafloor deformation monitoring, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3623, https://doi.org/10.5194/egusphere-egu22-3623, 2022.

EGU22-3732 | Presentations | GMPV9.4

Dike geometry and scaling controlled by kinetics rather than host rock toughness 

Simon Gill, Richard Walker, Ken McCaffrey, and Catherine Greenfield

A common method of characterising dikes is to plot their measured maximum thickness (T) against their horizontal length (L). This method has been applied widely to fault systems to determine critical mechanical controls on intraplate fault evolution, in which the maximum displacement Dmax  is related to L by Dmax=γLn, where typically n=1. This power law Dmax-L relationship (with scatter) is inferred to represent scaling under constant driving stress. For dikes and other opening mode fractures (e.g., joints, veins, and sills) T-L scaling is typically shown as n=0.5 (i.e. T=αL0.5 ) albeit with significant scatter in aspect ratio at all data-rich length scales. In contrast to the frictional control for shear faults, this square root scaling is consistent with growth under conditions of constant rock properties, including material fracture toughness KIC (i.e., the ability of a material containing a crack to resist fracture). Understanding scaling relationships therefore has significant implications for the mechanics of intrusions and other opening mode fractures.

                Thickness versus length (T-L) data for dikes (and veins, sills, etc., but here we focus on dikes) are universally interpreted using a linear elastic 2D pressurised crack model. The model assumes mechanical equilibrium, such that the stress intensity, K , at the tip of the dike is equal to the mode I fracture toughness of the country rock, KIC . Measured thickness to length ratios are generally consistent with reasonable magma excess pressure estimates, in the range of 1–10 MPa, but the large areas over which that pressure operates in a constant pressure model results in extremely large stress intensity at the tip, which then requires excessively large fracture toughness to stabilise the crack: for most dike sets, KIC=300-3000 MPa.m0.5, which is about 100–1000 times that of measured KIC values for rocks at upper crustal depths.

Here we propose that solidified intrusions variably preserve internal pressure gradients (required for magma flow), representing cracks controlled by kinetics; they are non-equilibrated structures and cannot be treated in continuum with toughness-controlled, uniform pressure (equilibrium) structures such as veins, or many types of scaled analogue model. Early stages of dike growth (inflation) result in increasing length and thickness, but magma pressure gradients within the dike may serve to drive late-stage lengthening at the expense of maximum thickness (relaxation). For cracks in 2D, we find that inflation is controlled by the magma injection rate, viscosity, and host rock stiffness. Pressure relaxation in the dike is controlled by magma viscosity and host rock stiffness, with the timescale of operation controlled by host rock thermal diffusivity (i.e., cooling toward eventual solidification). This combination of parameters imposes conditions that are unique to individual dikes and dike systems of variable volume, magma type, host rocks, and depth of emplacement, hence we suggest there is no unique scaling law for solidified intrusions. Host rock fracture toughness has no impact on kinetics-controlled dike growth in the upper crust, with the key controls being the host rock compliance relative to the magma flow, which will change during dike emplacement

How to cite: Gill, S., Walker, R., McCaffrey, K., and Greenfield, C.: Dike geometry and scaling controlled by kinetics rather than host rock toughness, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3732, https://doi.org/10.5194/egusphere-egu22-3732, 2022.

EGU22-3883 | Presentations | GMPV9.4

High-resolution InSAR reveals deformation inside the crater of Agung, Indonesia, prior to the 2017 eruption. 

Mark Bemelmans, Juliet Biggs, James Wookey, Mike Poland, Susanna Ebmeier, and Devy Syahbana

In September 2017, volcanic unrest in the vicinity of Mount Agung, Bali, Indonesia, increased drastically as a dike intruded between Agung and Batur volcanoes. This intrusion was followed by 5 weeks of declining activity before the eventual explosive eruption from Agung’s summit starting on November 21, 2017. We use high-resolution satellite SAR imagery to detect pre-eruptive intra-crater uplift at Agung volcano. We show that deformation of the crater floor occurred together with the dike intrusion to the northwest of the volcano. We attribute the deformation to a hydrothermal system less than 300 m below the surface that was activated by the injection of magmatic gasses. This finding indicates that Agung’s shallow magmatic system was active from the start of the increased unrest. Additionally, we observe a pulse of intra-crater uplift within 3-0.5 days prior to the onset of the eruption. The second pulse of uplift was one of the only precursors to the eruption and was probably caused by interaction between the hydrothermal system and the ascending magma. The detection of localized deformation during a volcanic crisis has important implications for eruption and unrest forecasting at Mount Agung and similar volcanoes and argues for monitoring with high-resolution SAR, which is capable of achieving both outstanding spatial resolution and, if sufficient satellites are used, excellent temporal coverage.

How to cite: Bemelmans, M., Biggs, J., Wookey, J., Poland, M., Ebmeier, S., and Syahbana, D.: High-resolution InSAR reveals deformation inside the crater of Agung, Indonesia, prior to the 2017 eruption., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3883, https://doi.org/10.5194/egusphere-egu22-3883, 2022.

EGU22-4214 | Presentations | GMPV9.4

Modelling the shape of a growing fluid-filled crack and computing its propagation velocity: application to magmatic dykes. 

Francesco Maccaferri, Severine Furst, and Virginie Pinel

The physics describing fluid-filled fracture growth is simple to describe, but extremely challenging to implement in an analytical, and even in a numerical modelling scheme. The fracturing process is governed by the equations for a brittle-elastic medium, while the internal flow is described by fluid dynamics equations. The pressure profile within the fluid-filled crack, the crack shape, and the velocity of crack growth, results from the solution of the coupled elastic and fluid-dynamic problem, that is far from been trivial. Magmatic dykes can be seen as a sub-set of the larger family of fluid-filled fractures. So far, two main schools have been established for modelling magmatic dykes: they have been named “fracture dominated” and “viscous dominated”, according to the fracture propagation regime that they target. Fracture dominated models are used when the fluid viscosity contributes with a negligible forcing to the total budget of the problem. They can describe complex crack shapes, account for heterogeneous stress fields and crustal heterogeneity, and compute the direction of crack growth. However they give no information about the crack propagation velocity. On the other hand, the viscous dominated school, drastically simplifies the crack geometry and the crustal structures, but can account for the interaction between elastic and viscous forces, hence it can compute the crack propagation velocity along a prescribed trajectory.

A few years ago, we teamed up, coming from these two different modelling schools, with the aim of merging our approaches in a single modelling scheme. Here we present a new modelling scheme, which computes the dynamic shape of a moving fluid-filled crack, built with the BE technique, in plane strain approximation (2D). Our model account for heterogeneous crustal stress and complex fracture propagation paths, and compute the crack shape considering the fluid viscosity and the crack propagation velocity. The crack velocity can be given as input to our model, or computed as output in the assumption that the main sources of energy dissipation are the brittle fracturing and the laminar viscous flow. We compare our model results with previous numerical models from the fracture dominated and viscous dominated schools, and present the implications of our findings with regards to some of the most important parameters characterising a magmatic intrusion, such as its volume, buoyancy and viscosity of magma, and rock fracture toughness. Eventually we show an application of the model to the rising of the dyke that fed the 1998 Piton de la Fournaise eruption (La Réunion Island).

How to cite: Maccaferri, F., Furst, S., and Pinel, V.: Modelling the shape of a growing fluid-filled crack and computing its propagation velocity: application to magmatic dykes., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4214, https://doi.org/10.5194/egusphere-egu22-4214, 2022.

EGU22-4677 | Presentations | GMPV9.4

A novel trans-dimensional inversion algorithm to model deformation sources with unconstrained shape in finite element domains 

Erica De Paolo, Nicola Piana Agostinetti, and Elisa Trasatti

Ground deformation signals, detected by geodetic instruments, can provide valuable insights on subsurface processes. The deformation field patterns, in fact, typically reflect characteristics of the buried source such as the position, depth, shape and volume variation. The increasing accuracy and spatio-temporal density of remote-sensing measurements allow us to map these patterns with unprecedented detail, highlighting the need to quantitatively investigate the processes at the origin. In active volcanic sites, in presence of deep pressurized reservoirs, e.g. magma chambers, the correct interpretation of geodetic signals is essential to define the hazard potential. Inverse modeling techniques are commonly employed for this goal, providing quantitative estimates of parameters describing the volcanic source. However, despite the robustness of the available approaches, a realistic imaging of reservoirs is still challenging. The widely used analytical models return quick but simplistic results, assuming an isotropic and elastic crust and forcing the solution to fit in pre-established geometric shapes. The use of inaccurate assumptions about the source shape can lead to the misinterpretation of other fundamental parameters, affecting the reliability of the solution. A more sophisticated analysis, accounting for the effects of topographic loads, crust inelasticity and the presence of structural discontinuities, requires the employment of numerical models, like those based on finite elements methods (FEM), but also a much higher computational effort. Here, we present a novel approach aimed at overcoming the aforementioned limitations. This method allow us to retrieve deformation sources without a-priori shape constraints, benefiting from the advantages of FEM simulations at a cost-efficient computing effort. We image the deformation source as an assembly of elementary units, each one represented by a cubic element of a regular FE mesh, loaded, in turn, with the six components of the stress tensor. The surface response to each stress component is computed and linearly combined to obtain the total displacement associated to the elementary source. This can be extended to a volume of multiple elements, approximating a deformation source of potentially any shape. Our direct tests prove that the sum of the responses associated to an assembly of solid units, loaded with an appropriate stress tensor, is numerically equivalent to the deformation fields produced by corresponding analytical and FEM cavities with uniform pressures applied at their boundaries. Our ability to simulate pressurized cavities in a continuum domain allow us to pre-compute a library of unitary surface responses, i.e., the Green’s function matrix, and to avoid complex re-meshing. We develop a Bayesian trans-dimensional inversion algorithm to select, scale and sum the displacements associated to each unit belonging to the assemblies that best fit the observations. In particular, we employ two sets of 3D Voronoi cells to sample the model domain, selecting the elementary units contributing to the source solution and the part belonging to the set representing the crust, which remains inactive. In this contribution, we present the original methodology and preliminary applications.

How to cite: De Paolo, E., Piana Agostinetti, N., and Trasatti, E.: A novel trans-dimensional inversion algorithm to model deformation sources with unconstrained shape in finite element domains, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4677, https://doi.org/10.5194/egusphere-egu22-4677, 2022.

When magma ascends through the shallow parts of terrestrial planetary crust, it deforms the surrounding host rocks. The deformation patterns observed at the surface offer indirect means to characterize the position, geometry and volume of subsurface magmatic intrusions. To enable real-time eruption forecasting during volcano unrest, most volcano geodetic models assume that magma intrusion induces linearly elastic deformation of homogeneous shallow planetary crust. Other indirect geophysical volcano monitoring data (e.g., seismology, gravimetry) however offer only limited opportunity for validating geodetic model results. Moreover, recent geological observations at exhumed volcano plumbing systems and geophysical observations of recent intrusion events have shown that plastic behaviour can dominate in heavily fractured and heterogeneous volcanic edifices and tectonically active areas. The question remains how large the effect of unaccounted plastic deformation could be on estimated intrusion characteristics.

Scaled laboratory experiments can be an innovative tool to assess by how much modelled magma intrusion characteristics – volume, geometry, position – deviate from reality in circumstances where plastic deformation processes are important. We used a tensile rectangular dislocation in a homogeneous, linearly elastic half-space to invert the three components of near-surface displacements extracted from X-ray Computed Tomography imagery of laboratory experiments of analogue dyke injection in cohesive mixtures of quartz sand and gypsum powder. The model results favored by the inversions are then compared to the three-dimensional characteristics of the analogue magma intrusions observed in the X-ray CT imagery. To further investigate the effect of more complex model geometry, we also used a tensile distributed-opening dislocation geometry. Preliminary results show that inversion results can be improved by fixing values of parameters that control the position of the modelled dislocation, but significant discrepancies remain between the modelled and observed intrusion geometry, orientation and volume. This test study helps gaining insight on the limitations of commonly used volcano geodetic modelling and inversion methods, and provides a novel basis for interpreting geological, geodetic and geophysical data related to volcanic deformation. The experimental results pave the way for developing complex forward models of magma-induced deformation in the heterogeneous shallow crust of terrestrial planets.

How to cite: Poppe, S., Wauthier, C., and Fontijn, K.: Elastic vs. plastic: Inversion of analogue magma-induced surface displacements in granular materials in laboratory experiments, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4902, https://doi.org/10.5194/egusphere-egu22-4902, 2022.

EGU22-5239 | Presentations | GMPV9.4

A conceptual model for the initiation of flank creep at Pacaya Volcano, Guatemala 

Judit Gonzalez Santana, Christelle Wauthier, and Michelle Burns

Magma emplacement is a recognized trigger of volcanic flank instability. There is also growing evidence for links between magmatic intrusions and accelerating creep on detachment faults within volcanic edifices. This driver was recently proposed at Pacaya, an active basaltic stratovolcano in Guatemala with evidence for past flank collapse, and magma-driven flank instability during major eruptions in 2010 and 2014. In order to understand the conditions under which flank creep can be initiated, sustained, or halted at active volcanoes, we investigate the links between flank creep and eruptive behavior at Pacaya and devise a conceptual model for the initiation of flank creep. Flank creep is quantified through time-series of surface displacements from 2007 to 2020 using seven Synthetic Aperture Radar datasets, and eruptive behavior is described through volcanic activity reports, ash advisories, thermal anomaly time-series, and lava flow maps. We identify large transient flank instabilities coincident with vigorous eruptions in 2010 and 2014, but not during times of similarly elevated activity in 2007 to 2009 and 2018 to 2020. Slower creep takes place during the relatively quiescent 2010 to 2014 and 2015 to 2018 intervals, following the 2010 and 2014 transient instability events. Our analysis suggests that during times of elevated volcanic unrest with persistent thermal anomalies and degassing, attributed to open-vent volcanism, as in 2007 to 2009 and 2018 to 2020, magma movements in an open conduit happen with little associated deformation and flank motion. Conversely, whenever new vents open outside the summit area, irrespective of whether this takes place at the start or during a transition in an eruption, transient flank creep can be initiated, as in 2010 and 2014. Therefore, the opening of new vents away from the main summit cone at Pacaya, especially in a north-northwest to south-southeast alignment, could forewarn an increased likelihood of new or accelerating flank creep.

How to cite: Gonzalez Santana, J., Wauthier, C., and Burns, M.: A conceptual model for the initiation of flank creep at Pacaya Volcano, Guatemala, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5239, https://doi.org/10.5194/egusphere-egu22-5239, 2022.

EGU22-5350 | Presentations | GMPV9.4 | Highlight

How studying solidified, exposed magma chambers helps to interpret volcano deformation and pre-eruptive unrest 

Steffi Burchardt, Emma Rhodes, Tobias Mattsson, Taylor Witcher, Tobias Schmiedel, Erika Ronchin, Sonja Greiner, Orlando Quintela, and Abigail C. Barker

The remnants of kilometre-sized solidified magma bodies exposed in volcanic areas are the product of magma accumulation beneath active volcanoes. These magma bodies can have formed over time spans ranging from months to hundreds of thousands of years, and some have triggered unrest and fed eruptions at the volcano surface. Here, we focus on melt-dominated magma bodies in the upper crust, which represents a sub-volcanic magma-storage level overlying a deeper, likely mush-dominated, igneous plumbing system. Based on several examples in eastern Iceland, we present field observations, structural analyses, 3D reconstructions, and petrological and fabric analyses that shed light on (1) the growth of magma chambers during single, fast, or multiple, long-term, magma injection events and (2) the deformation of the surrounding host rock as a result of different styles of magma emplacement. Moreover, we present evidence for syn-emplacement eruptions from one of the field examples.

We then discuss how field studies of solidified upper crustal magma chambers can inform the interpretation of volcanic unrest signals at active volcanoes. For instance, certain styles of magma emplacement create pronounced surface deformation and seismicity, while others may show initial seismicity that resembles dyke and/or sill emplacement but then allows for the emplacement of vast amounts of magma at shallow depth. This emplacement can likely happen without any significant surface deformation and with very little seismicity. Hence, solidified, exposed magma chambers that formed in the upper crust can provide valuable clues to improve eruption risk and volcano hazard assessment.

How to cite: Burchardt, S., Rhodes, E., Mattsson, T., Witcher, T., Schmiedel, T., Ronchin, E., Greiner, S., Quintela, O., and Barker, A. C.: How studying solidified, exposed magma chambers helps to interpret volcano deformation and pre-eruptive unrest, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5350, https://doi.org/10.5194/egusphere-egu22-5350, 2022.

EGU22-5634 | Presentations | GMPV9.4

Energy budget during magma ascent: using viscous fluid-filled crack in laboratory models to investigate magmatic dike intrusions in natural settings 

Ayleen Gaete, Francesco Maccaferri, Eleonora Rivalta, and Nicola Alessandro Pino

Dikes play a significant role in transporting magma from the Earth's depth to the surface. Likewise, dikes constitute a network of intrusions connected to storage bodies that form the volcanic plumbing system promoting magma transport beneath and inside active volcanic centers, channeling its ascent during volcanic eruptions.

Characterizing the dike properties is critical for determining whether a dike will reach the surface and estimating the time it needs to do so. Increasing our understanding of diking could contribute to assessing the volcanic hazard.

We implement laboratory models by means of viscous-oil injections in solidified gelatin to study the dynamic properties of magmatic dikes propagating in the upper crust. We prepare gelatin at 1.5 wt.% gel and 15 wt.% salt to produce a host medium with lower resistance to fracturing and higher density that facilitates the propagation of viscous fluids. Salty gelatin is carefully prepared following a protocol that ensures the elastic properties remain consistent over all our experiments. We inject oils 1000 and 10000 times more viscous than water from the bottom of the gelatin tank. Injection volumes range from 10 to 50 ml. Such experimental setting ensures a correct scaling of magma buoyancy and viscosity to study dike dynamics. A camera facing the models follows the vertical trajectory of the dike. The second camera positioned above the models records the opening and width of the crack just before the eruption.

From camera data recorded for a large set of experiments, we constrain the propagation velocity for different dike volumes. We implemented these experiments to study fluid-filled crack velocity and velocity variations as a function of fluid volume, buoyancy, viscosity, and gelatin fracture toughness. We simulate the laboratory experiments using a numerical model for dike propagation to address fundamental questions about the total energy budget involved in the fluid-filled fracture propagation process. Here we present preliminary results concerning the energy budget, in particular, comparing the energy needed to extend the brittle fracture with respect to the energy dissipated by the viscous fluid motion and better characterizing the propagation regime of the experiments versus magmatic dikes.

We foresee the application of these models to caldera settings, focusing on Campi Flegrei, Italy.

How to cite: Gaete, A., Maccaferri, F., Rivalta, E., and Pino, N. A.: Energy budget during magma ascent: using viscous fluid-filled crack in laboratory models to investigate magmatic dike intrusions in natural settings, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5634, https://doi.org/10.5194/egusphere-egu22-5634, 2022.

EGU22-5637 | Presentations | GMPV9.4

Numerical modelling of unrest signals at Mt. Ruapehu (New Zealand) 

Fee Arens, Joachim Gottsmann, Armando Coco, James Hickey, and Geoff Kilgour

The absence of precursory signals of recent eruptions at Mt. Ruapehu poses a problem for hazard assessment and risk mitigation at the popular Tongariro National Park. Ruapehu hosts an active hydrothermal system with volcanic unrest being driven by either migration of magma, hydrothermal fluids, or a combination of both. In our study, we develop a suite of 2D axisymmetric numerical models to study the detectability limit of precursory subsurface processes at Ruapehu to inform recommendations for monitoring protocols. In our models magmatic unrest (MU) results from pressurisation of a transcrustal elliptical mush zone due to the intrusion of juvenile magma which triggers a poroelastic response in the hydrothermal system. Hydrothermal unrest (HTU) is simulated by the injection of hot multicomponent and multiphase fluids (H2O and CO2) into Ruapehu’s hydrothermal system (HTS), where thermo-poroelastic responses are triggered. We simultaneously solve for ground displacement, self-potential (SP) anomalies and residual gravity changes resulting from the subsurface perturbations, with model parameterization adapted to Ruapehu. All models account for topography and subsurface mechanical and hydro-electric heterogeneities.

For a plausible reference parameter set, we find that geophysical observables are markedly distinct in their magnitude and wavelength in both magmatic and hydrothermal unrest scenarios. Most geophysical anomalies show their largest magnitudes directly above the hydrothermal system, with signals falling off rapidly with distance. At Ruapehu’s summit plateau (500 m from the HTS) vertical displacement amplitudes for MU simulations are 1.5 times smaller than maximum magnitudes of 1.2 cm for HTU simulations, with the latter being above conventical detection limits (1 cm in the vertical). Maximum residual gravity changes on the plateau are -4 μGal for HTU simulations and hence below detection levels of standard field observations, while for MU simulations with a source density change of 10 kg/m3 resulting signal magnitude is twice as high. Modelled SP anomalies are predicted to exceed conventional detection levels of 0.1 mV with typical SP signals for HTU simulations attaining maximal amplitudes of 1.3 mV, which are ~3 times larger than those resulting from MU simulations.

Parameter exploration shows that residual gravity changes for MU simulations are predominantly controlled by reservoir density changes, while SP polarity and magnitude strongly depends on the hydro-electric coupling coefficient for both unrest scenarios. Moreover, we find that the Biot-Willis coefficient (degree of poroelastic response) has the greatest influence on displacement amplitudes for HTU simulations, with negligible effect on displacement, SP and gravity changes resulting from MU simulations. Although gravity changes and displacements for reservoir strengths (volume/overpressure) > 7 km3/MPa are greater as for reference simulations, vertical displacement remains below detection levels. Magnitudes of all signals from HTU simulations correlate with fluid fluxes. Our interpretation of the findings is that magmatic unrest at Ruapehu should be identifiable by joint residual gravity and SP time series, whereas ground displacements >1 cm in the vertical and SP anomalies should be indicative of hydrothermal unrest.

How to cite: Arens, F., Gottsmann, J., Coco, A., Hickey, J., and Kilgour, G.: Numerical modelling of unrest signals at Mt. Ruapehu (New Zealand), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5637, https://doi.org/10.5194/egusphere-egu22-5637, 2022.

EGU22-6071 | Presentations | GMPV9.4

Microseismicity reveals the fault geometry and internal structure of the re-inflating Bárðarbunga caldera 

Tom Winder, Nick Rawlinson, Bryndís Brandsdóttir, Kristín Jónsdóttir, and Robert S. White

Between August 2014 and February 2015 the subglacial Bárðarbunga caldera collapsed, subsiding more than 65 metres as magma flowed out from beneath it to feed a dike intrusion and fissure eruption at Holuhraun. Subsequently, the caldera has been re-inflating, likely indicating recharge of the crustal magma storage reservoir. Sustained seismicity along the caldera ring faults – but with reversed polarity compared to the eruption period – further indicates its ongoing resurgence1. Between June-August 2021 we installed an array of 6 seismometers on the ice cap above Bárðarbunga, to provide improved constraints on earthquake locations and focal mechanisms, and to improve ray coverage in the region beneath the caldera.

Tilt-tolerant Güralp Certimus sensors provided high-quality three-component recordings throughout the deployment, despite significant ice movement. We used QuakeMigrate2 – a powerful migration-based automatic earthquake detection and location algorithm – to produce a catalogue of more than 8,500 earthquakes during the two month deployment, with a magnitude of completeness of ML -0.8. These are dominantly composed of high-frequency volcano-tectonic (VT) earthquakes around the caldera margins. Waveform cross-correlation and relative-relocation reveals a sharply defined ring fault, which is consistent in geometry with geodetic constraints obtained during the deflation period in 2014-15. Tightly constrained focal mechanisms provide further insight into the geometry of the caldera-bounding fault system.

Low frequency earthquakes observed between 15 - 25 km depth b.s.l. in the normally ductile part of the crust below Bárðarbunga signify activity at the roots of the volcano, which may indicate fluid ascent pathways. Further long-period earthquakes in the centre of the caldera, at around 5 km b.s.l., possibly mark the location of the shallow magma storage reservoir. Precise manually picked phase arrival times will be inverted to produce a local body-wave tomography model of the internal structure of the volcano. Together with the seismicity, this will provide the first image of the magma plumbing system that feeds Bárðarbunga. It will furthermore provide constraints on the relative geometry of the caldera ring faults and magma reservoir that drained during the 2014-15 eruption and caldera collapse, and which is now re-inflating to drive the ongoing resurgence. These may be compared to laboratory and numerical models of caldera formation and faulting mechanisms to provide an improved general understanding of this important volcanic phenomenon.

 

1: Southern, E.O., Winder, T., White, R.S. and Brandsdóttir, B., 2021. Ring Fault Slip Reversal at Bárðarbunga Volcano, Iceland: Seismicity during Caldera Collapse and Re-Inflation 2014-2018. https://doi.org/ 10.1002/essoar.10510097.1

2: Winder, T., Bacon, C., Smith, J., Hudson, T., Greenfield, T. and White, R., 2020. QuakeMigrate: a Modular, Open-Source Python Package for Automatic Earthquake Detection and Location. https://doi.org/10.1002/essoar.10505850.1

How to cite: Winder, T., Rawlinson, N., Brandsdóttir, B., Jónsdóttir, K., and White, R. S.: Microseismicity reveals the fault geometry and internal structure of the re-inflating Bárðarbunga caldera, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6071, https://doi.org/10.5194/egusphere-egu22-6071, 2022.

EGU22-6194 | Presentations | GMPV9.4 | Highlight

Low-temperature thermal unrest and deformation at active volcanoes: The intriguing case of Domuyo and Taal calderas 

Társilo Girona, Paul Lundgren, Grace Bato, and Claire Puleio

Understanding the processes that govern the inter-eruptive dynamics of volcanic calderas (e.g., Campi Flegrei, Yellowstone) is crucial to detect unrest and better forecast their activity. This is an important concern to monitoring agencies because calderas may represent major hazards to modern societies, both at local and global scale. One of the most intriguing caldera-related phenomena is the so-called breathing, i.e., continuous inflation-deflation cycles on the order of up to 10s of centimeters per year and with characteristic periodicities ranging from a few years to decades. In this study, we explore the breathing activity of Domuyo volcano (Argentina), a dacitic-rhyolitic caldera in the Southern Andes whose most recent eruption occurred >10,000 years ago (Lundgren et al., 2020); and the recent breathing phase leading to the moderate (volcano explosivity index 3) eruption in January 2020 at Taal volcano (Philippines). In particular, we integrate geodetic data (retrieved from the synthetic aperture radar -SAR- sensors onboard ALOS, ALOS-2, Radarsat-2, and Sentinel-1 satellites) with a recently discovered observable found to emerge on active volcanoes during unrest (Girona et al., 2021): low-temperature (~1 K over ambient temperature), large-scale (up to 10s of km2), long-term ( 6 months/1 year) thermal anomalies (retrieved from the moderate resolution imaging spectroradiometers -MODIS- onboard NASA’s Terra and Aqua satellites). Our analysis shows that geodetic and thermal unrest are significantly correlated, although the time series are phase shifted. To interpret these phase shifts and their implications, we develop a first-order, 1D numerical model based on mass, momentum, and energy conservation that couples the permeable flow of gases through the shallow crust, the viscoelastic deformation of the crust, the condensation of magmatic water vapor in the subsurface, and the diffusive transport of heat to the surface. Our preliminary results show that: (i) phase shifts between thermal and geodetic time series are controlled by detection limits, and by the coupling between magma reservoir processes and the transport of gas and heat through the crust; (ii) the pressure inside magma reservoirs can oscillate spontaneously during quiescent outgassing at the typical breathing timescales, thus suggesting that some geodetic and thermal unrest episodes are not necessarily associated to new magma inputs, but to the intrinsic dynamics of active magma reservoirs. This study has important implications for assessing volcanic hazards through improved eruption forecasting methods.

Girona, T., Realmuto, V. & Lundgren, P. Large-scale thermal unrest of volcanoes for years prior to eruption. Nat. Geosci. 14, 238–241 (2021). https://doi.org/10.1038/s41561-021-00705-4.

Lundgren, P., Girona, T., Bato, M.G. et al. The dynamics of large silicic systems from satellite remote sensing observations: the intriguing case of Domuyo volcano, Argentina. Sci Rep 10, 11642 (2020). https://doi.org/10.1038/s41598-020-67982-8.

 

How to cite: Girona, T., Lundgren, P., Bato, G., and Puleio, C.: Low-temperature thermal unrest and deformation at active volcanoes: The intriguing case of Domuyo and Taal calderas, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6194, https://doi.org/10.5194/egusphere-egu22-6194, 2022.

EGU22-6487 | Presentations | GMPV9.4

Linking surface Observables to sub-Volcanic plumbing-system:a multidisciplinary approach for Eruption forecasting at Campi Flegrei caldera (Italy). 

Lucia Pappalardo, Stefano Caliro, Anna Tramelli, and Elisa Trasatti and the LOVE-CF team

The Campi Flegrei caldera (Italy) is one of the most dangerous volcanoes in Europe and is currently in a new phase (started in 2000 and still ongoing) of the unrest that has persisted intermittently for several decades (main crises occurred in 1950-52, 70-72 and 82-84). The current activity has prompted the Italian Civil Protection to move the Campi Flegrei volcano from the first (“base” or “green”) to the second (“warning” or “yellow”) level of alert since the end of 2012.

The geophysical and geochemical changes accompanying the unrest stimulated a number of scientific investigations that resulted in a remarkable production of articles over the last decade. However, large uncertainties still persist on the architecture of the caldera plumbing system as well as on the nature of the subsurface processes driving the current (and previous) unrest.

LOVE-CF is a 4-years project started in October 2020 and funded by INGV (Istituto Nazionale di Geofisica e Vulcanologia), with the aim of improving our ability to forecast the behaviour of the Campi Flegrei caldera, through a multi-disciplinary approach based on a combination of volcanological, petrological, geochemical, seismological and geodetic observations, as well as experiments and numerical models. 

We present the project objectives and methods, and show obtained preliminary results. Particularly our investigation includes: 

  • a) the integration of structural, volcanological and petrological data from representative past eruptions with results of decompression experiments and numerical models of conduit dynamics and dyke propagation;
  • b) innovative geochemical (new redox gas species and CH4isotopes), minero- petrological (alteration products) and seismic (fumarolic tremor) measurements at the crucial “Solfatara-Pisciarelli” hydrothermal site as well as geochemical characterization of submarine emissions in the area of “Secca delle Fumose” in the Gulf of Pozzuoli which has been poorly-explored so far;
  • c) novel multi-dimensional statistical analysis of seismic, geochemical and geophysical records collected (both on land and offshore) in the last decades and in the recent period of unrest, constrained by geological observations and advanced numerical modelling;
  • d) comprehensive analysis of surface deformations from historical data (since 35 BC) to modern techniques (both in-situ and remote sensing), and related modelling to disclose the active plumbing system and the relationship among the different sources of deformation throughout the decades and centuries.

How to cite: Pappalardo, L., Caliro, S., Tramelli, A., and Trasatti, E. and the LOVE-CF team: Linking surface Observables to sub-Volcanic plumbing-system:a multidisciplinary approach for Eruption forecasting at Campi Flegrei caldera (Italy)., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6487, https://doi.org/10.5194/egusphere-egu22-6487, 2022.

EGU22-7207 | Presentations | GMPV9.4

Transport of mafic magma through the crust and  sedimentary basins: Jameson Land, East Greenland 

Christian Haug Eide, Nick Schofield, John Howell, and Dougal Jerram

Igneous sheet-complexes transport magma through the crust, but most studies have focused on single segments of the magma-transport-system or have low resolution. In the Jameson Land Basin in East Greenland, reflection-seismic data and extensive outcrops give unparalleled constraints on mafic intrusions down to 15 km. This dataset shows how sill-complexes develop and how magma is transported from the mantle through sedimentary basins. The feeder zone of the sill-complex is a narrow zone below basin, where a magmatic underplate body impinges on thinned crust. Magma was transported through the crystalline crust through dykes. Seismic data and published geochemistry indicate magma was supplied from a magmatic underplate, without perceptible storage in crustal magma-chambers and crustal assimilation. As magma entered the sedimentary basin, it formed distributed, bowl-shaped sill-complexes throughout the basin. Large magma volumes in sills (4-20 times larger than the Skaergaard Intrusion), and few dykes highlight the importance of sills in crustal magma-transport. On scales smaller than 0.2 km, host-rock lithology, and particularly mudstone tensile strength-anisotropy, controls sill-architecture in the upper 10km of the basin, whereas sills are bowl-shaped below the brittle-ductile transition zone. On scales of kilometres and towards basin margins, tectonic stresses and lateral lithological changes dominate architecture of sills.

How to cite: Eide, C. H., Schofield, N., Howell, J., and Jerram, D.: Transport of mafic magma through the crust and  sedimentary basins: Jameson Land, East Greenland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7207, https://doi.org/10.5194/egusphere-egu22-7207, 2022.

EGU22-7614 | Presentations | GMPV9.4

Faulting induced by underground magma migration: new insights from detailed field analysis (Campi Flegrei, Italy) 

Renato Diamanti, Giovanni Camanni, Jacopo Natale, and Stefano Vitale

Faulting triggered by magma migration at depth is a not-rare phenomenon in volcanic areas, where they can be found at very different scales. By analogue and numerical models, it has been shown that these types of faults can display a complex structure that often comprises an array of fault segments with both normal and reverse senses of movement. In this work, we analyzed in detail, and for the first time using field data, a fault array associated with the collapse induced by underground magma migration. The fault array crops out in cross-section within a recent volcanic succession in the Campi Flegrei caldera (southern Italy). Analyses focused on defining the spatial and temporal relationships between the normal and reverse fault segments of the fault array to provide insights into the process of collapse development. Based on geometric and displacement data, we propose that normal and reverse faults likely acted simultaneously to accommodate the collapse after a rapid phase of fault propagation.

How to cite: Diamanti, R., Camanni, G., Natale, J., and Vitale, S.: Faulting induced by underground magma migration: new insights from detailed field analysis (Campi Flegrei, Italy), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7614, https://doi.org/10.5194/egusphere-egu22-7614, 2022.

EGU22-7941 | Presentations | GMPV9.4

Nested crater morphology, ring-structures and temperature anomalies detected by close-range photogrammetry and thermal remote sensing at Láscar volcano, Chile 

Lun Ai, Thomas Walter, Francesco Massimetti, Felipe Aguilera, Rene Mania, Martin Zimmer, Christian Kujawa, and Manuel Pizarro

Volcanic craters often develop in clusters and enclose smaller, subsidiary vents and ring structures. Details on the ongoing geomorphology and structural evolution, however, are commonly lacking for active volcanic craters due to difficult and hazardous access. Therefore, remote sensing based investigation at active volcanoes is providing unique data allowing entrance to inaccessible summit craters. Here we describe novel drone and satellite data collected at Láscar, the most active volcano in the central Andes. Láscar hosts five partially nested craters, the deepest crater of the eastern three persist active and was the site of numerous violent explosions in the past decades. Using a Pleiades tri-stereo satellite dataset, we constructed a 1-m resolution digital terrain model (DTM) and orthomap that we used to identify subtle structures and morphologies of the eastern three nested craters. However, due to the shadow effect caused by the deep concave shape of the active crater, its geometry remains unclear. We complement this analysis by unoccupied aerial vehicle (UAV) surveys in 2017 and 2020 by employing both an optical and a thermal imaging camera. We systematically mapped the entire crater field and could also fly into the deep active crater to acquire close range images. We applied the Structure-from-Motion (SfM) method that enables us to create centimeter-scale DTMs, optical and thermal orthomosaics. Using this data-set we create an inventory of fumaroles and thermal anomalies. By calculating the difference of the 2017 and 2020 data, we quantify the spatial and volumetric changes that occurred during the observation period. We find changes mostly concentrated at the crater floor, material accumulation, thermal anomalies changing, as well as localized rock falls into the crater. We note that highest temperature anomalies are restricted by the central circular structure at the crater floor, consistent with the location of a thermal anomaly episode that peaked in late 2018, possibly representing the surface expression of the underlying conduit. Thus, by linking the satellite and drone data we derive important morphological, thermal and structural information and discuss the crater morphology and characteristics of episodic unrest phases at Láscar.

How to cite: Ai, L., Walter, T., Massimetti, F., Aguilera, F., Mania, R., Zimmer, M., Kujawa, C., and Pizarro, M.: Nested crater morphology, ring-structures and temperature anomalies detected by close-range photogrammetry and thermal remote sensing at Láscar volcano, Chile, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7941, https://doi.org/10.5194/egusphere-egu22-7941, 2022.

EGU22-8020 | Presentations | GMPV9.4

A global statistical study on the triggering of volcanic eruptions by large tectonic earthquakes 

Alex Jenkins, Alison Rust, and Juliet Biggs

Recent studies have shown that large tectonic earthquakes are capable of triggering volcanic eruptions (i.e. increasing the number of eruptions within a defined time period) up to hundreds of kilometres away. However, the prevalence of eruption triggering is less clear, with findings ranging from little evidence for triggered eruptions, to a fourfold increase in the number of eruptions following nearby large earthquakes. Some of this variability is likely due to differences in definitions of what constitutes a triggered volcanic eruption, including a lack of consensus on the maximum distance and time lag between an earthquake and a triggered volcanic eruption, the minimum magnitude of earthquake considered, and how aftershocks are incorporated into the analysis. A further source of variability arises from the different datasets used, including regional versus global studies, and the inclusion of incomplete earthquake and eruption records from before the modern instrumental era. To help address these issues, we provide a comprehensive statistical study of how large earthquakes affect volcanic eruption rates, using complete and unbiased global datasets spanning 1960-2021. We take a systematic approach to investigating how parameters such as the maximum distance and time lag between earthquake-eruption pairs, the minimum earthquake magnitude considered, and the declustering of aftershocks affects the results. We also investigate how previously unstudied earthquake parameters such as source depth and mechanism affect the prevalence of eruption triggering. Our results are placed in statistical context through the use of Monte Carlo simulations using randomised earthquake and eruption catalogues. Preliminary results indicate that, contrary to a previous focus on large subduction megathrust earthquakes, deep normal faulting earthquakes have the greatest eruption triggering tendency. However, when compared with randomised earthquake and eruption catalogues, the overall statistical significance of observed eruption triggering is fairly low.

How to cite: Jenkins, A., Rust, A., and Biggs, J.: A global statistical study on the triggering of volcanic eruptions by large tectonic earthquakes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8020, https://doi.org/10.5194/egusphere-egu22-8020, 2022.

EGU22-8341 | Presentations | GMPV9.4

Shoreline-crossing geomorphology of instable volcanic islands from a quantitative DEM analysis 

Elisa Klein, Morelia Urlaub, and Sebastian Krastel

Volcanic islands are known to be a source of many natural hazards associated with active volcanism. The processes leading to the instability of their flanks, however are less well understood. The movement of an instable volcanic flank occurs in either or both of two ways; slow sliding of several cm per year (i.e. Etna, Italy) and/or the catastrophic collapse of a large portion of the edifice (i.e. Anak Krakatau, Indonesia). The conditions and precursors leading to such events are often unknown.

The limited availability of high-resolution bathymetry data especially at the coast is often restricting the quantitative geomorphological investigation to the subaerial part of the volcanic island. It is essential, however, to include the entire volcanic edifice as instability affects the volcano from summit to seafloor. In this study, we test whether and in which way, the morphology of the volcanic edifice affects its instability.

We therefore combine openly available high-resolution bathymetric and topographic grids (50-150m grid spacing) to create shoreline-crossing DEMs of more than 25 volcanic islands in four areas (archipelagos of Hawaii, Canaries, Mariana Islands and South Sandwich Islands). Additionally, we define sections of equal angle (flanks) with the summit as the central point. Morphological parameters, such as area, volume, height from seafloor, slope etc. of both the entire volcano and each of the 8 flanks, respectively are derived from the DEM grids and inserted into a database. The statistical analysis of this data combined with the history of flank failure will shed light on the influence the morphology of a volcanic island has on its instability. This will lead to a better understanding of the processes involved in the movement of instable volcanic flanks.

How to cite: Klein, E., Urlaub, M., and Krastel, S.: Shoreline-crossing geomorphology of instable volcanic islands from a quantitative DEM analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8341, https://doi.org/10.5194/egusphere-egu22-8341, 2022.

Late Proterozoic to Early Palaeozoic metavolcano-sedimentary successions are important components of the Variscan massifs of Europe. Felsic and mafic metavolcanic rocks with Cambro-Ordovician protolith ages also occurs in the Staré Město Belt (SMB) in the Central Sudetes (Czech Republic, Poland) (e.g. Kröner et al. 2000). The SMB is the NNW-trending fold-and-thrust belt that forms the eastern margin of the Saxothuringian Zone of the Bohemian Massif. To constrain timing and geodynamic setting of the volcanism recorded in that part of the Saxothuringia, the whole rock geochemistry, zircon trace element geochemistry and U-Pb zircon geochronology of metabasalts, metagabbros and acid metavolcanites of the SMB were carried out.

Field and petrographic studies show that bimodal association in the SMB is mainly expressed by alternating layers of fine-grained amphibolites composed of Amp, Pl and Px and fine- and medium-grained acid metavolcanites composed of Qz, Pl, Kfs, Grt, Bt and Ms. Such close relationships between felsic and mafic meta-volcanic rocks suggest their common origin. Whole-rock geochemistry data suggest, however, a diversity both in the chemical composition and tectonic environments of formation of their igneous protoliths. Magmatic precursors of the amphibolites were tholeiitic and calc-alkaline basalts, andesitic basalts and andesites that were derived either from MORB, BABB, volcanic arc or within-plate magmas. The acid metavolcanites originated from rhyolites and dacites belonging to tholeiite, calc and calc-alkaline series. Geotectonic diagrams suggest that the felsic magmas were formed most likely in island arc or continental arc environments.

New LA-ICPMS zircon dating of two metadetrital rocks of the SMB revealed the predominance of Neoproterozoic-Cambrian and Palaeoproterozoic age clusters, characteristic for rocks of the Saxothuringian Zone. Zircon dating of four samples of acid metavolcanites, two samples of metabasalts and one sample of metagabbro confirmed that their igneous protoliths crystalized at the same time, at ca. 495-500 Ma. Trace elements in zircons were analyzed in all metavolcanic samples. Range of values of Nb/Yb = 0.001-0.1, U/Yb = 0.1-10 and Y = 25-6993 ppm are observed in both types of rocks and together indicate a contribution of continental crust in the SMB volcanites. Their values plotted on geotectonic classification diagrams of Grimes et al. (2015) suggest a continental arc setting for the whole Late Cambrian bimodal volcanism in the easternmost part of the Saxothuringian Zone.

The research was financed from the grant of the National Science Center, Poland No. 2018/29/B/ST10/01120.

 

References:

Grimes, C.B., Wooden, J.L., Cheadle, M.J., John, B.E., 2015.  “Fingerprinting” tectono-magmatic provenance using trace elements in igneous zircon. Contrib Mineral Petrol 170, 46.

Kröner, A., Štipská, P., Schulmann, K., Jaeckel, P., 2000. Chronological constraints on the pre-Variscan evolution of the northeastern margin of the Bohemian Massif, Czech Republic. In: Franke, W., Haak, V., Oncken, O., Tanner, D. (Eds.), Orogenic Processes: Quantification and Modelling in the Variscan Belt. Geological Society, London, Special Publications 179, pp. 175–197.

How to cite: Śliwiński, M., Jastrzębski, M., Machowiak, K., and Sláma, J.: Age and geotectonic setting of metavolcanic rocks in the eastern Saxothuringian margin: whole rock geochemistry, zircon trace element geochemistry and U-Pb geochronology of the Staré Město Belt (Czech Republic, Poland), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8363, https://doi.org/10.5194/egusphere-egu22-8363, 2022.

EGU22-8478 | Presentations | GMPV9.4

New age constraints for Early Palaeozoic volcanism and sedimentation of the Kaczawa Complex, the Sudetes (SW Poland) 

Mirosław Jastrzębski, Katarzyna Machowiak, Marek Śliwiński, and Jiří Sláma

In Variscan Europe, bimodal magmatism related to Early Palaeozoic thermal event in the northern part of Gondwana has been widely documented in rock successions extending from Spain to Poland (e.g. Franke et al. 2017). The Kaczawa Complex, the SW Poland, contains Early Palaeozoic felsic, intermediate to basic volcanic rocks, and Cambrian to Early Carboniferous sediments all involved in complex processes of the Variscan collision(s). This contribution provides new LA-ICPMS UP zircon data that specify the age and provenance of some important rocks occupying the lower part of the stratigraphic column of the Kaczawa Complex: 1) Osełka metarhyodacytes, 2) Lubrza metatrachytes, 3) Radzimowice slates and 4) Gackowa metasandstones.

The U-Pb dating of zircons coming from the Osełka metarhyodacites yields a crystallization age of 500±5 Ma, while the zircon dating of the Lubrza metatrachytes yields the Concordia age of 495±3 Ma. These data confirm the early Palaeozoic age of the volcanism of the Kaczawa Complex (e.g. Muszyński, 1994; Kryza et al. 2007), but they strongly suggest a single event of the bimodal volcanic activity. An inherited age component of c. 630 Ma is present in the Lubrza metatrachytes. The zircon dating of the accompanied metasedimentary rocks i.e. two samples of Radzimowice slates and one sample of the Gackowa metasandstones yields comparable detrital age spectra. The maximum depositional ages of these rocks are ca. 535 Ma. The Radzimowice and Gackowa metasedimentary rocks show the predominance of Neoproterozoic age zircons clustering around 580-605 Ma, 630-640 Ma and 730-770 Ma, which indicates that the sedimentary basins were mainly supplied by erosion of crystalline rocks of Ediacaran up to Tonian age. Paleoproterozoic and Archean components (1.7 Ga, 2.0-2.1 Ga and 2.9-3.0 Ga) are less common.

All these data show that rocks from the lower part of the lithostratigraphic column of the Kaczawa Complex represent the Late Cambrian metavolcano-sedimentary successions. The detrital zircon age spectra indicate that the source areas for the Kaczawa Complex metapelites may have been in the West Africa Craton of Gondwana.

The research was financed from the grant of the National Science Center, Poland No. 2018/29/B/ST10/01120.

 

References:

Franke, W., Cocks, L. R. M., Torsvik, T. H. 2017. The Palaeozoic Variscan oceans revisited. Gondwana Research 48, 257–284.

Kryza R., J.A. Zalasiewicz, S. Mazur, P. Aleksandrowski, S. Sergeev, S. Presnyakov, 2007. Early Palaeozoic initial-rift volcanism in the Central European Variscides (the Kaczawa Mountains, Sudetes, SW Poland): evidence from SIMS dating of zircons. Journal of the Geological Society, London 164, 207-1215

Muszyński A., 1994. Kwaśne skały metawukanogeniczne w środkowej części Gór Kaczawskich: studium petrologiczne. Wyd. Nauk. UAM., seria geologia, Nr 15: 144 pp

 

How to cite: Jastrzębski, M., Machowiak, K., Śliwiński, M., and Sláma, J.: New age constraints for Early Palaeozoic volcanism and sedimentation of the Kaczawa Complex, the Sudetes (SW Poland), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8478, https://doi.org/10.5194/egusphere-egu22-8478, 2022.

EGU22-9024 | Presentations | GMPV9.4

Joint analysis of GNSS and seismic data to track magma transport at Piton de la Fournaise volcano (La Réunion, France) 

Cyril Journeau, Aline Peltier, Nikolai Shapiro, François Beauducel, Valérie Ferrazzini, Zacharie Duputel, and Benoit Taisne

Geophysical measurements from the networks of instruments maintained by volcano observatories for several decades provide a large database that is rich in information concerning magma transport from deep storage zones to its shallow propagation before eruptions. In this study, we analyze multi-year time series of GNSS and seismic data acquired at Piton de la Fournaise (PdF) volcano (La Réunion, France) from 2014 up to now. These observations are sensitive to the dynamics of the magma within the volcanic system and their detailed study allows us to better apprehend its behavior both during pre-eruptive periods, by informing us about the preparation phases before an eruption and also during co-eruptive periods, by following the eruptions time-evolution and the corresponding dynamics.

We propose to scan continuously GNSS data by inverting them in time windows ranging from minutes to days using a point compound dislocation model (pCDM). This approach provides analytical expressions for surface displacements due to a complex source of deformation with variable geometry to model different shapes such as dikes, prolate ellipsoids, or pipes. As a result, we image a deep reservoir around 7-8 km below the PdF summit, as well as, in some cases, the upward magma migration dynamics in the crust over several days toward a shallow reservoir at sea level and the final dyke propagation over a few hours that ultimately feeds the eruptive site.

These observations are systematically compared to seismic data over the same time period and are jointly interpreted. We use both the seismicity catalog of "regular" volcano-tectonic events as well as the results of cross-correlations network-based methods obtained with the CovSeisNet package allowing the detection of “un-regular” signals and the location of their sources, such as micro-seismicity generated during dyke propagation, and long-period seismicity (tremor and LP events).

The joint use of information from geodetic and seismic networks constitutes an important step in improving our knowledge of volcanic systems. While the analysis of GNSS network data enables the imaging of active pressure-sources in the system with an estimation of the volumes of involved magma, the seismic network analysis allows for a more detailed view of the magma dynamics in the volcanic edifice.

How to cite: Journeau, C., Peltier, A., Shapiro, N., Beauducel, F., Ferrazzini, V., Duputel, Z., and Taisne, B.: Joint analysis of GNSS and seismic data to track magma transport at Piton de la Fournaise volcano (La Réunion, France), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9024, https://doi.org/10.5194/egusphere-egu22-9024, 2022.

EGU22-9033 | Presentations | GMPV9.4

Thermo-mechanical effects of dyke host rocks in response to turbulent magma flow 

Rahul Patel, D Srinivasa Sarma, and Aurovinda Panda

We study the thermal erosion and mechanical fragmentation of dyke host rocks using a thermodynamical and fluid-mechanical approach. It is inferred that the latent heat of magma mainly causes the thermal damage of dyke host rocks and encourages thermal erosion. The application of fluid-dynamical shear stress on the dyke walls induced by turbulence magma flow results in mechanical fragmentation., We calculated the Reynolds number to confirm these findings to decipher the nature of magma flow through the dykes. The estimated Reynolds number for 30 dykes is in excess of 2000 suggesting that magma ascends turbulently through the dykes. The turbulence of magma flow provides additional energy to derive thermal erosion and mechanical fragmentation.  In order to better understand the thermo-mechanical effect of dyke host rocks, we used the mass conservation principle. Equations for mass conservations are derived to better explain the complex interactions between magma and host rock. Heat transfer, magma flow rate, magma flow velocity, and host rock melting are calculated. The presence of xenoliths in the dykes is primary evidence that the dykes have been mechanically fragmented. We present an integrodifferential equation to understand the kinematic of mechanical fragmentation and size of xenoliths varies due to secondary Collison within a dyke. Presented results are useful to understand the nature of magma, dyke host rock melting, and magma evolution.

Key words: Thermal erosion, mechanical fragmentation, turbulent magma flow, dykes

How to cite: Patel, R., Sarma, D. S., and Panda, A.: Thermo-mechanical effects of dyke host rocks in response to turbulent magma flow, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9033, https://doi.org/10.5194/egusphere-egu22-9033, 2022.

EGU22-9059 | Presentations | GMPV9.4

Likely ring-fault activation at Askja caldera (Iceland) during the 2021 unrest 

Adriano Nobile, Hannes Vasyura-Bathke, Reier Viltres, Daniele Trippanera, Benedikt Gunnar Ófeigsson, Joël Ruch, and Sigurjón Jónsson

The Askja volcanic system, located in the North Volcanic Zone of Iceland, consists of a central volcano with three nested calderas (Kollur, Askja, and Öskjuvatn) and a 20 km wide and ~190 km long fissure swarm with a NNE-SSW trend. Kollur caldera is ~5 km wide and formed in the Pleistocene while the younger 8-km wide Askja caldera, the largest among the three, formed in the Holocene. The smaller (~4 km) and lake-filled Öskjuvatn caldera is located within the Askja caldera and formed following the 1875 Plinian eruption. This event was followed by several localized eruptions along the Öskjuvatn ring fault system (1921, 1922, and 1929) and the last eruption occurred in 1961 in correspondence with the Askja northern caldera border. After this eruption, the Askja caldera first underwent inflation for several years followed by slow (< 1 cm/yr) subsidence over decades. In early August 2021, the volcano entered a period of unrest with new earthquake activity located below the central volcano, and the GNSS station OLAC, located near the center of Askja caldera, started to uplift at a high rate (~3 cm/week). The uplift continued until the end of November 2021. Here we use SAR images acquired from four different orbits (two ascending and two descending) by the Sentinel-1 satellites to study the ground deformation during this unrest period. Only data from the first half of the unrest period could be used (until the end of September). Later, heavy snow resulted in the loss of interferometric coherence within the caldera, preventing retrieval of the deformation signal. The maximum ground displacement of ~10 cm (from the end of July to the end of September) was found at the center of the Askja caldera, near the western shore of Öskjuvatn Lake. Interestingly, the interferograms show an asymmetric deformation pattern that follows the ring faults in the northwestern part of Askja caldera. Analytical models suggest that a roughly 7 x 3 km2 NW-SE elongated sill inflated at a shallow depth of ~2 km below the Askja caldera. However, simple sill models cannot explain the asymmetrical deformation pattern observed in the InSAR data. Therefore, using boundary element modeling, we find that while the magmatic intrusion accounts for the broad uplift, possible ring-fault activity would localize the deformation close to the caldera rim. Furthermore, an elongated sill, like the one obtained from the first source estimation, would probably activate only a part of the ring-fault system, leading to an asymmetric deformation pattern.

How to cite: Nobile, A., Vasyura-Bathke, H., Viltres, R., Trippanera, D., Gunnar Ófeigsson, B., Ruch, J., and Jónsson, S.: Likely ring-fault activation at Askja caldera (Iceland) during the 2021 unrest, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9059, https://doi.org/10.5194/egusphere-egu22-9059, 2022.

EGU22-9161 | Presentations | GMPV9.4

Enrichment of immobile elements in synmagmatic fractures 

Taylor Witcher, Steffi Burchardt, Michael Heap, Alexandra Kushnir, Anne Pluymakers, Tobias Schmiedel, Iain Pitcairn, Tobias Mattsson, Pim Kaskes, Philippe Claeys, Shaun Barker, and Johan Lissenberg

Useful minerals containing rare Earth elements (REE) and metals are sourced from magma bodies, but exactly how these elements initially leave the magma is not well known. Here we present textural and chemical analyses of mineral-filled fracture bands within the rhyolitic Sandfell laccolith exposed in eastern Iceland. The fracture fillings showcase dynamic and complex textures and imply multiple energy levels during precipitation. The dominant mineral phases are Fe- and Mg-oxides, Mn carbonate, and La/Ce oxide. The textures they present are comb, laminate, radial, and a rounded reworked clastic texture filling the tips. Microtomography images of hand-samples show the fractures are stretched-penny shaped, and contain 80 vol% fillings and 20 vol% void space. The connectivity of fractures within one band is limited to 1-3 neighbours, via small oblique fractures joining two main fractures together. µXRF measurements revealed distinct halos of 0.8 wt% Fe depletion surrounding each facture, and within the fracture-fill a strong enrichment in an unusual suite of elements including Fe, Mn, Cl, Zn, Cr, Y, Ce, and La. This assemblage is puzzling, as many of these elements are typically carried by fluids which have strong alteration effects on the surrounding rock, and there is a lack of this kind of alteration at Sandfell. Our working hypothesis is that the formation of the fractures provided a degassing pathway through the impermeable magma. However, the nature and the composition of the magmatic volatiles are as yet unknown. The minimal connectivity between fractures (at hand-sample scale) suggests fluid would have travelled through the length of one to three fractures until intersecting with another fracture band system, and minerals precipitated along the way. Given the ubiquitous occurrence of the fracture bands within the laccolith, this small-scale process compounds into large amounts of mass transfer overall. The fractures at Sandfell may be a snapshot of the initial process of removing incompatible elements from silicic magma.

How to cite: Witcher, T., Burchardt, S., Heap, M., Kushnir, A., Pluymakers, A., Schmiedel, T., Pitcairn, I., Mattsson, T., Kaskes, P., Claeys, P., Barker, S., and Lissenberg, J.: Enrichment of immobile elements in synmagmatic fractures, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9161, https://doi.org/10.5194/egusphere-egu22-9161, 2022.

EGU22-9381 | Presentations | GMPV9.4

Deformation observations and geodetic modelling during the recent unrest at Askja volcano 

Michelle Parks, Benedikt Ófeigsson, Vincent Drouin, Freysteinn Sigmundsson, Andrew Hooper, Halldór Geirsson, Sigrún Hreinsdóttir, Hildur Friðriksdóttir, Erik Sturkell, Ásta Hjartadóttir, Chiara Lanzi, Siqi Li, Sara Barsotti, and Bergrún Óladóttir

At the beginning of August 2021, inflation was detected at Askja volcano, on a continuous GNSS station located to the west of Öskjuvatn and on interferograms generated using data from four separate Sentinel-1 tracks. Ground deformation measurements at Askja commenced in 1966 with levelling observations and since this time additional ground monitoring techniques have been employed, including GNSS and Satellite interferometry (InSAR) to detect long-term changes. Ground levelling measurements undertaken between 1966-1972 revealed alternating periods of deflation and inflation. Measurements from 1983-2020 detailed persistent subsidence of the Askja caldera, initially at an inferred rate of 7 cm/yr, decaying in an exponential manner. Suggested explanations for the long-term subsidence include magma cooling and contraction, or withdrawal of magma – eventually facilitated by an extensive magma-rich plumbing system, with an open conduit between the uppermost and the deeper parts of the magmatic system. This presentation will focus on the recent period of uplift and provide an overview of the GNSS and InSAR observations to date and present the latest geodetic modelling results which describe the best-fit source for the observed deformation.

How to cite: Parks, M., Ófeigsson, B., Drouin, V., Sigmundsson, F., Hooper, A., Geirsson, H., Hreinsdóttir, S., Friðriksdóttir, H., Sturkell, E., Hjartadóttir, Á., Lanzi, C., Li, S., Barsotti, S., and Óladóttir, B.: Deformation observations and geodetic modelling during the recent unrest at Askja volcano, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9381, https://doi.org/10.5194/egusphere-egu22-9381, 2022.

EGU22-9479 | Presentations | GMPV9.4

Current crustal movement in the East Eifel Volcanic Field – anthropogenic or volcanic? 

Michael Frietsch, Lidong Bie, Joachim Ritter, Andreas Rietbrock, and Bernd Schmitt

Monitoring crustal movements is essential to volcanic hazard assessment in areas of active volcanism. These surface movements occur on a wide range of time scales and wavelengths. However, the origin of crustal movements is not always associated with volcanic activities, particularly in areas with rigorous human activities (i.e., ground water extraction). It is challenging yet critical to distinguish between the ongoing volcanic and anthropogenic activities. In this study, we focus on the East Eifel Volcanic Field, which consists of multiple active Quaternary volcanoes. We report areas of uplift and subsidence 2-3 km away from each other near the Laacher See volcanic crater (2-3 km distance), and investigate the mechanisms responsible for the reversed deformation in such close proximity.

PS-InSAR measurements by the BodenBewegungsdienst Deutschland (BBD) show notable ground displacements in this area for the period between 2014 and 2019. The deformation is clearly mapped by three different tracks of the Sentinel-1 satellite – two ascending and one descending, which confirms the robustness of the signal being detected by PS-InSAR. The main deformation is round in shape, and the rates peak up to 10 mm per year in line-of-sight (LOS) for the uplift area near the village Glees and reach down to -4 mm LOS for the subsidence zone in the vicinity of the village Wehr. To investigate the likely mechanism responsible for the ground displacements, we model the crustal movements with two spherical pressure point sources (i.e., the Mogi sources) simultaneously using a combined global and local optimization scheme. In the inversion, we search for the optimal combinations for a set of four parameters (latitude, longitude, depth and volume) for each Mogi source. The global optimization is achieved by Multi-Level Single-Linkage algorithm and we use the PRAXIS algorithm to find the local minimum. We include all three tracks of data, of which the different satellite viewing geometries help stabilize the inversion.

Our results show that the uplift trend in Glees can be explained by an additional volume of 13000 m³ per year at 530 m depth. The subsidence near Wehr can be best fitted by a decrease in volume of 1700 m³ per year at 340 m depth. The modelling results show a trade-off between depth and volume, however, the uncertainties are smaller for the subsidence source near Wehr. Residuals trending in SW-NE direction are observed at the Glees uplift area, and the relatively large parameter uncertainties for Glees uplift zone are likely due to sparse persistent scatters there. Given the shallow depth of the Mogi sources, we interpret the Glees uplift being predominantly associated with fluid refilling in the respective volume caused by former CO2 extraction. The subsidence around Wehr is linked to ongoing industrial CO2 extraction. Our study identifies anthropogenic factors that may cause ground deformation in an active volcanic region, and has implications for future volcanic hazard assessment.

How to cite: Frietsch, M., Bie, L., Ritter, J., Rietbrock, A., and Schmitt, B.: Current crustal movement in the East Eifel Volcanic Field – anthropogenic or volcanic?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9479, https://doi.org/10.5194/egusphere-egu22-9479, 2022.

The location and volume change of pressurized magma chambers can be constrained by inverse modelling of the surface displacements they cause. Through a joint inversion of surface displacements and gravity changes the chamber mass change during the pressurization period can also be inferred. Such inversions often start with constraining the deformation source parameters using the deformation data alone (step 1). Using these parameters the gravity data are then corrected for the effect of mass redistribution in the host rocks and surface uplift/subsidence associated with the chamber expansion (step 2). Next, the corrected gravity changes together with the source location from the deformation inversion are used to infer the intrusion mass (step 3). Provided that the intrusion compressibility is known, the intrusion density can be estimated from the intrusion mass and source volume change from step 1 and step 3, respectively (step 4).

We show that the original gravity data (only corrected for ambient effects) are directly related to the deformation source parameters through the deformation-induced gravity changes and the free-air effect. Thus, both of these effects, which have been mostly considered as nuisance, in fact can be harvested to provide better constraints on the deformation source parameters and the mass changes. We propose a Bayesian framework for the joint inversion of deformation and gravity data by which all the deformation source parameters and chamber mass change are constrained simultaneously. This way, steps 1 to 3 of the previous approach are carried out at once. The advantages of the suggested approach are: (a) this way the gravity data help constrain deformation source parameters with smaller uncertainties, (b) it leads to a smaller uncertainty for the inferred mass change, (c) the optimal relative weights of various deformation and gravity datasets can be estimated as hyper-parameters within the Bayesian inference, thus, they are estimated directly and in an objective way, (c) the gravity and deformation stations need not be co-located, (d) errors associated with interpolation of vertical displacements at gravity benchmarks are avoided, (e) the uncertainty of vertical displacements is no longer propagated into the reduced gravity changes, and thus, mass changes are estimated more accurately.  

We apply this approach to the deformation and gravity data associated with the 1982-1999 inflation period at Long Valley caldera. The results agree with those from earlier efforts; however, show a clear improvement in the constrained source parameters and the intrusion mass. We discuss the implications and benefits of this approach depending on the relative quality of the deformation and gravity data.

How to cite: Nikkhoo, M. and Rivalta, E.: A new framework for simultaneous inversions of deformation and gravity data applied to the 1982-1999 inflation at the Long Valley caldera, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9620, https://doi.org/10.5194/egusphere-egu22-9620, 2022.

EGU22-10225 | Presentations | GMPV9.4

Bimodal maar volcanism in a post-collisional extensional regime: A case study of Acıgöl (Nevşehir) volcanic field (central Anatolia, Turkey) 

Göksu Uslular, Gonca Gençalioğlu-Kuşcu, Joël Ruch, Matteo Lupi, Oliver Higgins, Florence Bégué, and Luca Caricchi

The crustal structure is one of the fundamental factors that affects the type, composition, and spatial distribution of monogenetic volcanoes. The formation of maars, the second-most common type of monogenetic volcanoes, is mainly influenced by crustal lithologies, depth of explosions, and water-magma interactions together with magma rheology and tectonic structures. The Acıgöl caldera, located in the extensional setting of the central Anatolian plateau, contains both felsic and mafic maars. This rare compositional juxtaposition makes it a suitable location to better understand the relationship between magma chemistry and maar architecture. It includes closely spaced yet compositionally different monogenetic complexes (i.e., maars with either lava dome or scoria cone) and provides a fabulous opportunity to elucidate the role of crustal processes in the eruptional dynamics of maars.

Here we present an integrative study with detailed morphological (drone mapping), depositional (componentry, ash morphology), and petrological (whole-rock, glass, and mineral geochemistry) characteristics of rhyolitic (whole-rock; ~76.7 wt.% SiO2, glass; ~77.2 wt.% SiO2) İnallı, Kalecitepe, Acıgöl, and Korudağ maars, and mugearitic (~52.7 wt.% SiO2) İcik maar. Our observations show a wide range of morphological features with spectacular examples of nested and compound craters. Field observations, together with the detailed stratigraphical analysis and literature-based geochronological data, reveal that the formations of maars and the subsequent lava domes or scoria cones are spatially migrating events within the same magmatic episode. We hence relate this to the rejuvenation of conduits, along with the pre-existing structures of the Acıgöl caldera that are almost perpendicular to the local extensional direction (NE-SW).

Non-modal batch melting models reveal that all investigated maars have a similar parental magma source (i.e., the most primitive basalt in central Anatolia with the Mg# of 72.4). This is formed by partial melting of a metasomatized lithospheric mantle with contribution from an OIB-like asthenospheric melt. The uprising magma that also produced the entire Quaternary volcanics in central Anatolia was possibly trapped at different crustal depths beneath the Acıgöl caldera and formed the maars with various degrees of magmatic differentiation processes. We conclude that İcik maar emanated from a relatively deep (lower crustal?) mantle-derived magma source evolved by assimilation and fractional crystallization processes. In contrast, the felsic maars were presumably formed by the short-lived ponding of the same magma source at shallower depths, which was partially assimilated by the basement intrusive rocks and dominantly shaped by the feldspar-driven fractional crystallization. Finally, the well-exposed examples of felsic maars in the study area and their comparison with the mafic counterparts could be a good contribution to the ever-growing literature on maar volcanism.

How to cite: Uslular, G., Gençalioğlu-Kuşcu, G., Ruch, J., Lupi, M., Higgins, O., Bégué, F., and Caricchi, L.: Bimodal maar volcanism in a post-collisional extensional regime: A case study of Acıgöl (Nevşehir) volcanic field (central Anatolia, Turkey), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10225, https://doi.org/10.5194/egusphere-egu22-10225, 2022.

Volcanic eruptions present serious risk to human life and infrastructure. This risk can be minimized by improving eruption forecasts, which in turn requires increasing our capabilities to detect volcanic unrest and a better understanding of the physicochemical processes governing magma-hydrothermal interactions. The improvement of eruption forecasting techniques is especially important as some volcanic eruptions can occur with little to no precursory warning signs. That was the case of the most recent eruption at Okmok caldera, which took place in 2008 between July 12 – August 23, with a volcanic explosivity index of 4. This eruption highlighted the need to develop new methods to detect precursory activity and unrest.

Recently, through the analysis of satellite-based thermal spectroscopy data from MODIS instruments, Girona et al. (2021) found that low-temperature thermal anomalies along the flanks of volcanoes can predate their eruptions. In this work, we use an updated version of the method presented in Girona et al. (2021) to analyze the spatiotemporal distribution of low-temperature thermal anomalies at Okmok Caldera between July of 2002 and November of 2021. Preliminary analysis shows ~1-1.3 degrees of warming at Cone A in the ~3 years leading up to the 2008 eruption. This analysis also shows a warming trend in the caldera at several cones (D, E, A, and Ahmanilix), peaking in 2014, with brightness temperatures increasing by ~1-1.4 degrees for ~2 years (correlating with an observed inflation event); along with current warming at the same cones of ~0.8-1.2 degrees beginning in ~2017.

We propose that the low-temperature thermal anomalies observed at different cones of Okmok caldera are linked to the latent heat released during the condensation of magmatic and/or hydrothermal water vapor in the subsurface. In particular, we design a 1-dimensional thermal diffusion model to quantify how long it will take for the surface ground temperature to increase by one kelvin in response to the subsurface condensation of water vapor. Our preliminary analysis shows that, for realistic values of the parameters involved, the surface requires ~3.3 years to increase its temperature by one kelvin in response to a diffuse H2O flux of 161.5 kg/s condensing at 30m depth, and ~21.7 years for the surface to increase by one kelvin in response to the same gas flux condensing at 60m depth. The observed low-temperature thermal anomalies at Okmok are therefore consistent with the condensation of magmatic and/or hydrothermal water vapor at no more than a few tens of meters depth below the surface.

This work provides further insight into how volcanic hydrothermal subsurface processes manifest as thermal anomalies on the surface, and how these thermal anomalies can be used to detect unrest at Okmok and other active volcanoes. In the future, we aim to integrate the spatiotemporal distribution of low-temperature thermal anomalies with deformation, seismic signals, and diffuse gas emissions prior to and during eruptions.

 

Girona, T., Realmuto, V. & Lundgren, P. Large-scale thermal unrest of volcanoes for years prior to eruption. Nat. Geosci. 14, 238–241 (2021). https://doi.org/10.1038/s41561-021-00705-4.

How to cite: Puleio, C. and Girona, T.: Spatiotemporal distribution of low-temperature thermal anomalies at volcanic calderas: The case of Okmok volcano, Alaska, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10264, https://doi.org/10.5194/egusphere-egu22-10264, 2022.

EGU22-10486 | Presentations | GMPV9.4

Dyke-induced vs tectonic-controlled graben formation in a heterogeneous crust: Insights from field observations and numerical models 

Kyriaki Drymoni, Elena Russo, Alessandro Tibaldi, Fabio Luca Bonali, and Noemi Corti

Dyke propagation is the most common way of magma transfer towards the surface. Their emplacement generates stresses at their tips and the surrounded host rock initiating surficial deformation, seismic activity, and graben formation. Although active deformation and seismicity are studied in monitored volcanoes, the difference between dyke-induced and tectonic-controlled grabens is still less understood.

Here, we explore the difference between dyke-induced vs tectonic-controlled graben formation in stratovolcanoes with heterogeneous crustal properties like Mt. Etna (Italy) and Santorini (Greece). The field observations are related to Mt. Etna's 1928 AD fissure eruption, which partly generated dyke-induced grabens along its expression, and to the Santorini volcano, where tectonic-controlled grabens become pathways for later dyke injections. Field campaigns have revealed the stratigraphic sequence of the shallow host rock successions that became the basis of several suites of numerical models. The latter investigated the boundary conditions (overpressure or external stress field) and the geometrical and mechanical parameters that i) could produce temporary stress barriers and hence stall the propagation of a dyke towards the surface, and ii) shall form a graben at the surface. The detailed analysis, results and interpretations propose that soft materials in the stratigraphy, such as pyroclastic rocks, suppress the stresses at the vicinity of a propagating dyke and do not promote the generation of a graben above a propagating dyke. Also, the study explores the conditions where inclined ascending dykes produce semi-grabens and the generation of wide or narrow graben structures. Finally, the results give valuable insights on the field-related parameters that can encourage dyke deflection in pre-existing grabens in the shallow crust. All the latter can be theoretically applied in similar case studies worldwide.

How to cite: Drymoni, K., Russo, E., Tibaldi, A., Bonali, F. L., and Corti, N.: Dyke-induced vs tectonic-controlled graben formation in a heterogeneous crust: Insights from field observations and numerical models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10486, https://doi.org/10.5194/egusphere-egu22-10486, 2022.

EGU22-10766 | Presentations | GMPV9.4

Structure of a new submarine volcano and magmatic phases to the East of Mayotte, in the Comoros Archipelago, Indian Ocean. 

Charles Masquelet, Sylvie Leroy, Matthias Delescluse, Nicolas Chamot-Rooke, Isabelle Thinon, Anne Lemoine, Dieter Franke, Louise Watremez, Philippe Werner, and Daniel Sauter and the SISMAORE team

50 km East of Mayotte Island (North Mozambique Channel; Comoros Archipelago), a submarine volcanic edifice formed during the first year of a seismo-volcanic crisis, between May 2018 and May 2019. Thanks to the French ANR Project COYOTES and the SISMAORE oceanographic cruise (2021), a multichannel seismic profile gives the first in-depth image of the new East-Mayotte volcano and its surrounding volcanic area. The seismic interpretation reveals that several distinct magmatic phases affected the area. The new volcano is built on a ~150 m thick sedimentary layer. Beneath this sedimentary layer, we found a major volcanic layer, ~2.5 km thick, which extends ~91 km to the south and ~33 km to the north of the newly formed submarine volcano. This volcanic unit is composed of multiple seismic facies that may indicate distinct successive volcanic phases. We interpret this major volcanic layer as part of the Mayotte volcanic edifice, with the presence of a complex magmatic feeder system underneath. We observe a ~2.2-2.5 km thick sedimentary cover between the main volcanic layer, below the new volcano, and the top of the crust. We tentatively identified the top-Oligocene seismic horizon (~23 Ma) well above the main volcanic layer, and assuming a constant sedimentation rate we estimate the onset of the volcanism at Mayotte Island at 28 Ma.

How to cite: Masquelet, C., Leroy, S., Delescluse, M., Chamot-Rooke, N., Thinon, I., Lemoine, A., Franke, D., Watremez, L., Werner, P., and Sauter, D. and the SISMAORE team: Structure of a new submarine volcano and magmatic phases to the East of Mayotte, in the Comoros Archipelago, Indian Ocean., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10766, https://doi.org/10.5194/egusphere-egu22-10766, 2022.

EGU22-11437 | Presentations | GMPV9.4

The destructive 1928 fissure eruption of Mt Etna (Italy): surficial deformation revealed by field data and FEM numerical modelling 

Elena Russo, Alessandro Tibaldi, Fabio Luca Bonali, Noemi Corti, Kyriaki Drymoni, Emanuela De Beni, Stefano Branca, Marco Neri, Massimo Cantarero, and Federico Pasquarè Mariotto

The present research is aimed at evaluating the wide surficial deformation associated with the destructive 1928 fissure eruption on Mt. Etna, Italy: with its high effusion rates and the low elevation of the main eruptive vents, this eruption caused the destruction of the Mascali town. The main aim of our work is to reconstruct the geometry, kinematics and origin of the system of faults and fissures formed during the 1928 event. Our study has been performed through a multidisciplinary approach consisting of field observations, aerial photo interpretation and Finite Element Method (FEM) modeling through COMSOL Multiphysics® (v5.6). Field data consist of 438 quantitative measurements: azimuth values, opening direction and aperture of dry/eruptive fissures, as well as attitude and offsets of faults. Our detailed structural analysis allowed us to detect four different tectonic settings related to dike propagation scenarios, which, from west to east, are: 1) a sequence of 8 eruptive vents surrounded by a 385-m wide graben, 2) a 2.5-km long single eruptive fissure, 3) a half-graben up to 74-m-wide and a symmetric 39-m-wide graben without evidence of eruption, 4) alignment of lower vents along the pre-existing Ripe della Naca faults. 

As a next step, several numerical models have been developed to investigate the relationship between diking and surficial deformation. We performed sensitivity analyses, by modifying crucial parameters, such as a range of dike overpressure values (1-20 MPa), host rock properties (Young modulus ranging from 1 to 30 GPa), stratigraphic sequence, and layer thickness. Furthermore, the distribution of tensile and shear stresses above the dike tip has been evaluated. Results revealed the presence of temporary stress barriers, which consist of soft (e.g. tuff) layers, that control the surficial deformation above a dike propagating to the surface by suppressing the distribution of shear stresses.

How to cite: Russo, E., Tibaldi, A., Bonali, F. L., Corti, N., Drymoni, K., De Beni, E., Branca, S., Neri, M., Cantarero, M., and Pasquarè Mariotto, F.: The destructive 1928 fissure eruption of Mt Etna (Italy): surficial deformation revealed by field data and FEM numerical modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11437, https://doi.org/10.5194/egusphere-egu22-11437, 2022.

The Piton de la Fournaise volcano is located on the southeastern part of La Réunion Island and is inserted in the tectonic framework of the Indian Ocean. It is one of the most active worldwide volcanoes and it can be classified as a hot-spot basaltic one.

In this work, we focus on the eruption occurred from 11 to 15 August 2019 on the southern-southeastern flank of this volcano, inside the Enclos Fouqué caldera. In particular, this distal event was characterized by the opening of two eruptive fissures and accompanied by shallow volcano-tectonic earthquakes.

Firstly, we investigate the surface deformations induced by the occurred eruptive activity, by exploiting Differential Synthetic Aperture Radar Interferometry (DInSAR) measurements; they are obtained by processing the data collected by the Sentinel-1 satellite of the Copernicus European Program along ascending and descending orbits. Due to the position of the island in the southern hemisphere, the processed S1 interferograms are characterized by a 12-days temporal baseline; for this reason, they measure the ground deformations generated during both the pre- and co-eruptive phases. Then, we analyze the distribution of the relocated hypocenters to recognize the activated structures and to furnish further constraints to our model. Finally, we perform an analytical modelling to the computed coseismic DInSAR displacements, with the aim of investigating the volcanic source/s responsible for the measured surface deformation field.

The retrieved results reveal that several volcanic sources (one sill and four dikes, in particular) have been active during the pre- and the co-eruptive phases, allowing the magma transport towards the surface; their action can justify the complexity of the observed deformation pattern. Our findings are in good agreement with the seismicity recorded by the Observatoire Volcanologique du Piton de la Fournaise network and with several geophysical evidences, such as the comparison between the volume of the retrieved sources and the erupted magma volumes, and the fissures location.

How to cite: Valerio, E., De Luca, C., Manzo, M., Lanari, R., and Battaglia, M.: Geodetic modelling of a multi-source deformation pattern retrieved through Sentinel-1 DInSAR measurements: the 11-15 August 2019 Piton de la Fournaise (La Réunion Island) eruption case-study, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11497, https://doi.org/10.5194/egusphere-egu22-11497, 2022.

EGU22-12183 | Presentations | GMPV9.4

The 2021 unrest phase of Vulcano volcano (Aeolian islands) detected by SAR,GNSS and GB-RAR 

Guglielmino Francesco, Alessandro Bonforte, and Giuseppe Puglisi

Starting from July 2021, a gradual unrest of Vulcano volcano was recorded by monitoring system managed by INGV, marked by a progressive change of many parameters from the multi-disciplinary networks.

The fumaroles located on the crater rim and along the flank of the cone shown temperature increase ( up to 350 degree Celsius) and  an increase of the flux of carbon dioxide and sulfur dioxide in gas emissions. Furthermore, the increase of the occurrence of with very-long-period (VLP) events was recorded by seismic network, and a rapid uplift of about 1 cm/month was recorded at VCRA GNSS permanent station located on the North slope of the “La Fossa” cone.

In order to image the ground deformation accompanying the unrest phase, we analyzed the 2020-2021 ascending and descending ESA-Copernicus Sentinel-1A and 1B C-band SAR (Synthetic Aperture Radar) acquired in TopSAR (Terrain Observation with Progressive Scans SAR) Interferometric Wide mode with A-DINSAR techniques. On October 2021 a new GNSS survey was performed on the ”Lipari-Vulcano” network. We integrated the SAR data and the GNSS data applying the SISTEM method, and the preliminary results are consistent with the Vulcano hydrothermal system dynamics, with a deformation pattern limited to the cone area.

In order to monitoring continuously and more in detail the change in ground deformation, on December 2021 we installed 4 additional GNSS mobile stations and a permanent GB-RAR (ground-based real aperture radar) on the island. The GB-RAR system was installed at the Lipari Observatory, at a distance of about 5 km from Vulcano, and it is able to image the whole Vulcano north area, with a rectangular pixel resolution of 3x30 m and a precision of the displacement along the line of sight of about 1 mm.

At time of this abstract no ground deformation have been recorded in the last month, the microseismic activity reduced but the fumarole temperatures at the crater and gas emissions of carbon and sulphur dioxide remained at high level.

How to cite: Francesco, G., Bonforte, A., and Puglisi, G.: The 2021 unrest phase of Vulcano volcano (Aeolian islands) detected by SAR,GNSS and GB-RAR, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12183, https://doi.org/10.5194/egusphere-egu22-12183, 2022.

EGU22-12391 | Presentations | GMPV9.4

Gravitational volcano flank motion imaged by historical air photo correlation during the M7.7 Kalapana earthquake (1975), Big Island, Hawaii 

Stefano Mannini, Joel Ruch, James Hollingsworth, Don Swanson, and Ingrid Johanson

Volcanic islands are often subject to flank instability, being a combination of magma intrusions along rift zones, gravitational spreading and extensional faulting observable at the surface. The Kilauea is one of the most active volcano on Earth and its south flank show recurrent flank acceleration related to large earthquakes and magmatic intrusions. 
Here we focus on the M 7.7 Kalapana earthquake that occurred on 29 November 1975. It triggered ground displacement of several meters all over the south flank of the Kilauea volcano. The identification and quantification of the co-seismic rupture aim to better understand the overall flank motion and its connection to key structural components, such as between the southwest and east rift zones and the deep basal detachment where large earthquakes episodically nucleate.
Using optical imagery correlation technique, we analyzed the displacement that occurred during the 1975 earthquake. We used 26 and 22 historical air photos as pre-event (October 1974 and July 1975, respectively) and 7 and 44 for the post-event time period (December 1976 and March 1977, respectively).  Results show metrical horizontal displacement (north-south direction) along a 25 km long East West sector of the Kilauea south flank. We show that the ground rupture is continuous with most portions of faults that have been reactivated. Locally, the displacement values we found are in good agreement with punctual EDM measurements. Several fault segments have been activated close to the shore and their extension were previously unnoticed. Interestingly, we observe a constant increase of the offset away from the epicenter in the West direction, from a few meters up to ~12 meters, west of the Hilina Pali road. The deformation turns out to be higher where the faults are oriented NE-SW (western sector) compared to E-W oriented structures. It also shows that the flank is strongly influenced by gravitational effect, typical from large landslide processes. This observation provides additional information to better understand the connection between the Hilina fault system and the basal detachment.  Episodic flank motions on volcanic islands are rare events and this work contributes to the overall comprehension of volcano flank instability elsewhere.

How to cite: Mannini, S., Ruch, J., Hollingsworth, J., Swanson, D., and Johanson, I.: Gravitational volcano flank motion imaged by historical air photo correlation during the M7.7 Kalapana earthquake (1975), Big Island, Hawaii, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12391, https://doi.org/10.5194/egusphere-egu22-12391, 2022.

Volcano-tectonic systems involve a relation between magma propagation and faulting that is fundamental in volcanology research. Earth’s upper crust is often modelled as homogeneous and elastic. However, fracturing and reactivation of pre-existing structures plays a key role in volcano-tectonic processes and magma propagation. Moreover, obliquity affects > 70% of Earth’s rifts. This study aims at investigating inherited structures’ role on magma propagation in extensional settings, subject to different degrees of opening obliquity.

We performed a detailed and extensive structural mapping based on UAV imagery and field observations in the North Volcanic Zone, choosing representative rift segments that have likely a cyclic nature and display different obliquity degrees. We selected four zones within the Askja and Bárðarbunga volcanic systems, delimited by the Fjallagjá graben to the North and the Holuhraun graben to the South. Structures progressively bend from an almost N-S orientation in the North to a rather NE-SW to the South, while the strain field orientation of the rift shows a constant extension vector’s azimuth of ~104°. Recently, the 2021 Fagradalsfjall volcano-tectonic event show an extreme case of high obliquity end-member system along the plate boundary.

We did a detailed morphostructural analysis of the processed imagery (~3 cm/px DEMs and ~2cm/px orthomosaics) and analysed fracture orientations, sense of opening and the effect of topography on the rift segments. The strength of the obliquity signal increases going from North (where no clear obliquity dominance is observed) to South (where Holuhraun shows distinct obliquity with a left lateral sense of shear), following the curvature of the overall rift segments. The processed imagery revealed typical structures related to volcano-tectonic processes, such as monoclines, open fractures, nested grabens with fault scarps that suggest reactivation, and intrusions oblique to the graben shoulders. For example, in the northern zone, we observe that eruptive fissures are ~ parallel to the main orientation of the plate boundary extension, but ~10°-20°consistently oblique to the enclosing graben shoulders.

Our observations help constraining the stress configuration and their evolution during intrusions.
The aim is to unveil the processes that govern magma propagation in a fractured crust at divergent plate boundaries from depth to the surface, which exert a fundamental influence on eruptions locations.

How to cite: Panza, E. and Ruch, J.: Obliquity and rifting: Interaction of faulting and magma propagation during volcano-tectonic events in North Iceland using UAV-based structural data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12760, https://doi.org/10.5194/egusphere-egu22-12760, 2022.

EGU22-12860 | Presentations | GMPV9.4

New data on Campanian Ignimbrite of southern Italy: changing paradigm for Campi Flegrei caldera and the Campanian volcanism 

Giuseppe De Natale, Christopher R.J. Kilburn, Giuseppe Rolandi, Claudia Troise, Renato Somma, Alessandro Fedele, Gianfranco Di Vincenzo, Roberto Rolandi, and Judith Woo

We present a new stratigraphy, inferred from several drillings carried out in the framework of the ICDP Campi Flegrei Deep Drilling Project , for the largest volcanic eruption in Europe since at least the Late Pleistocene. The eruption produced the Campanian Ignimbrite of southern Italy. It is conventionally believed to have triggered collapse of the large Campi Flegrei caldera, which, in turn, has been identified as a source for future ignimbrite volcanism. New borehole and radioisotopic data challenge this interpretation. They indicate that the Campanian Ignimbrite was erupted through fissures in the Campanian Plain, north of Campi Flegrei, and was not responsible for caldera collapse. The results are consistent with ignimbrite volcanism being controlled by a common magmatic system beneath the Campanian Plain. Understanding the dynamics of the whole plain is thus essential for evaluating the likelihood of similar future events.

How to cite: De Natale, G., Kilburn, C. R. J., Rolandi, G., Troise, C., Somma, R., Fedele, A., Di Vincenzo, G., Rolandi, R., and Woo, J.: New data on Campanian Ignimbrite of southern Italy: changing paradigm for Campi Flegrei caldera and the Campanian volcanism, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12860, https://doi.org/10.5194/egusphere-egu22-12860, 2022.

EGU22-13057 | Presentations | GMPV9.4

Joint GNSS-InSAR analysis of ground deformation on the eastern flank of Mount Etna. 

Francesco Carnemolla, Alessandro Bonforte, Fabio Brighenti, Pierre Briole, Giorgio De Guidi, Francesco Guglielmino, and Giuseppe Puglisi

Mount Etna is located on eastern Sicily on the border of the collision zone between the Eurasia and Nubia plate. The regional geodynamic framework is characterized by two superimposed regional tectonic domains: a compressional one oriented N-S and an extensional one oriented approximately WNW-ESE. These two domains, together with the volcano-tectonic one, generated a tectonic system which is unique in the world. It exhibits a complex system of faults prevalently on the eastern flank of the volcano, which is the most complicated in terms of interaction between the tectonic, volcano and gravitational processes. The eastern flank of Mount Etna is the most active area of the volcano in terms of deformation and seismicity, because the deformation rates are at least one order of magnitude greater than the surrounding area, due to the eastwards sliding of this flank.

The monitoring and analysis of the high deformation occurring on the eastern flank of Mount Etna is the keystone for understanding the volcano-tectonic dynamics that, apart from the tectonic and volcanic processes, it is paramount relevant because involves the instability of this flank in a densely inhabited area. In this context the Istituto Nazionale di Geofisica e Vulcanologia – Osservatorio Etneo (INGV-OE) created one of the most sophisticated and complete monitoring networks in the world in terms of number of multi-disciplinary station (seismic, geodetic, geochemistry). Since 2014, the GeoDynamic & GeoMatic Laboratory (GD&GM-LAB) of the University of Catania started to create many GNSS sub networks, belonging to the UNICT-Net, in order to determine the offsets occurring on the blocks of each fault of the eastern flank.

In order to have a complete analysis of deformation, INGV-OE and the GD&GM-LAB started to consider this area as an “open-air laboratory” where integrate GNSS and InSAR data with the twofold objective: to characterize the dynamic of this area for contributing to the volcanic hazard assessment and to identify precursor phenomena on shear structures analysing the relationship between kinematics, dynamics and volcano processes in the frame of the ATTEMPT INGV project.

How to cite: Carnemolla, F., Bonforte, A., Brighenti, F., Briole, P., De Guidi, G., Guglielmino, F., and Puglisi, G.: Joint GNSS-InSAR analysis of ground deformation on the eastern flank of Mount Etna., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13057, https://doi.org/10.5194/egusphere-egu22-13057, 2022.

EGU22-2674 | Presentations | GMPV9.1

Swarm seismicity illuminates stress transfer prior to the 2021 Fagradalsfjall eruption, Iceland 

Tomas Fischer, Pavla Hrubcová, Ali Salama, Jana Doubravová, Josef Horálek, Thorbjorg Agustsdottir, Egill Gudnason, and Hersir Gylfi

 

The 6 months long effusive volcanic eruption of 19 March 2021 at Fagradalsfjall, Reykjanes Peninsula, Iceland was preceded by an intensive earthquake swarm lasting one month, with several earthquakes exceeding ML 5. We analyse seismic data recorded by the Reykjanet local seismic network to trace the processes leading up to the eruption in order to understand the relation between seismic activity and magma accumulation.

 

The precise relocations show that the seismicity is located in two clusters in the depth range of 1-6 km. A NE-SW trending cluster maps the dyke propagation; a WSW-ENE trending cluster follows the plate boundary. In comparison, we relocated the preceding earthquake swarms of 2017, 2019 and 2020 and found that they form two branches along the plate boundary, coinciding with the 2021 WSW-ENE trending cluster. These branches form a stepover of about 1 km offset, forming a pull-apart basin structure at the intersection with the dyke. This is the exact location of the eruption site, which shows that magma erupted at the place of crustal weakening.

 

The 2021 earthquake swarm initiated by a ML 5.3 earthquake on 24 February, which triggered the aftershocks along the plate boundary and in the dyke segment, both occurring in an area of elevated Coulomb stress. The swarm seismicity shows complex propagation of the dyke, which started at its northern end, migrated south-westward and then jumped back to the central part where the effusive eruption eventually took place. The strike-slip focal mechanisms of the larger magnitude events, with N-S striking fault planes, are interpreted as right-lateral antithetic Riedel shears that accommodate the left lateral slip along the plate boundary. The fact that both seismic and magmatic activities occur at the same location shows that the past seismic activity weakened the crust in the area of the eruption site. We show that the ML 5.3 earthquake on 24 February 2021 triggered the whole seismic swarm and perturbed the magma pocket which eventually led to the 19 March Fagradalsfjall eruption.

 

How to cite: Fischer, T., Hrubcová, P., Salama, A., Doubravová, J., Horálek, J., Agustsdottir, T., Gudnason, E., and Gylfi, H.: Swarm seismicity illuminates stress transfer prior to the 2021 Fagradalsfjall eruption, Iceland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2674, https://doi.org/10.5194/egusphere-egu22-2674, 2022.

EGU22-3140 | Presentations | GMPV9.1

Crater Rim Collapses Affect the Lava Fountaining Frequency during the Fagradalsfjall Eruption, Iceland 2021 

Eva P. S. Eibl, Thorvaldur Thórðarson, Ármann Höskuldsson, Egill Á. Gudnason, Thoralf Dietrich, Gylfi Páll Hersir, and Thorbjörg Ágústsdóttir

The Fagradalsfjall eruption on the Reykjanes peninsula, Iceland, lasted from 19 March to 18 September 2021. While it continuously effused lava at the beginning, it opened up 7 further vents in April and focused the activity from late April on Vent 5. Surprisingly the continuous effusion changed to pulses of lava effusion (as lava fountains or vigorous overflow) between 2 May and 14 June that was seismically recorded as tremor pulses. We examined the frequency of 6939 lava fountaining pulses based on seismological data recorded at NUPH at the SE corner of Núpshlíðarháls 5.5 km southeast of the active vent.

We subdivide the time period into 6 episodes based on sudden changes in the pattern. In this presentation we present the different fountaining patterns and systematic changes and discuss their origin. Our comparison with vent height, vent stability and lava effusion style, led us to conclude that the changes in the pulsing behaviour might be caused by collapses from the crater walls. The system is clearly unstable and evolving with time.

How to cite: Eibl, E. P. S., Thórðarson, T., Höskuldsson, Á., Gudnason, E. Á., Dietrich, T., Hersir, G. P., and Ágústsdóttir, T.: Crater Rim Collapses Affect the Lava Fountaining Frequency during the Fagradalsfjall Eruption, Iceland 2021, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3140, https://doi.org/10.5194/egusphere-egu22-3140, 2022.

EGU22-3149 | Presentations | GMPV9.1

Shallow conduit processes and sulfur release in the phreatomagmatic stages of the 1211 CE Younger Stampar eruption, Iceland 

Jacqueline Grech Licari, William M. Moreland, Thorvaldur Thordarson, Bruce F. Houghton, and Enikö Bali

The 2021 Fagradalsfjall basaltic eruption in Iceland was effusive, but a different eruptive scenario could have unfolded if its location had been shifted a few kilometres to the south to an offshore setting. Namely a shallow marine event similar to the phreatomagmatic stages of the 1211 CE Younger Stampar eruption. The 1211 CE eruption was the initial event of the 1211-1240 Reykjanes Fires and its first stage was a Surtseyan eruption just offshore of the point of Reykjanes. It constructed the ~0.006 km3 Vatnsfellsgígur tuff cone that featured a short-lived dry phase towards the end. A second phreatomagmatic stage took place ca. 500 m off the current Reykjanes coastline to produce the larger Karlsgígur tuff cone (~0.044 km3), with a combined cone/tephra volume of ~0.15 km3. Later, the activity migrated onshore onto a 4km-long fissure with an effusive eruption that generated the Yngri-Stampar crater row and associated lava flow fields. The Vatnsfellsgígur and Karlsgígur tuff cones consist of alternating pyroclastic surge-tephra fall units, intercalated with units formed by simultaneous deposition from surge and fall. The 3.5m-thick Vatnsfellsgígur section is composed of 8 units, whereas the 5.5m-thick Karlsgígur section consists of 9 units. Chemical analysis reveals that the cones are tholeiitic basalt (MgO 6.0-7.5 wt%) with sporadic olivine phenocrysts (Fo78 to Fo84) and dispersed plagioclase macrocrysts with core composition of An87 to An91. Two compositionally distinct groups of plagioclase-hosted melt inclusions are identified: one with composition comparable to the host magma and another more primitive in composition with lower FeO, TiO2 and K2O and higher MgO (ranging from 9-10 wt% and 9-11.5 wt% for Vatnsfellsgígur and Karlsgígur, respectively). This suggests that whilst upper crustal storage zones may have facilitated melt evolution, the erupting magma originated from a deeper, crystal-mush-dominated storage zone. Original and residual sulfur contents of ~2221.7 ± 150 ppm and ~966.2 ± 120 ppm respectively, indicate that ~0.658 ± 0.034 Tg of SO2 were released into the atmosphere during these two stages of phreatomagmatic activity. Moreover, vesicularity measurements on lapilli reveal unimodal, left-skewed vesicularity distributions with modes of 90% and 95% and a range of ~40% for Vatnsfellsgígur and Karlsgígur, respectively. These results indicate that magma had gone through vesicle nucleation to free growth and coalescence and probably initial dry (magmatic) fragmentation prior to contact with external water. The evidence strongly suggests that expansion of exsolved magmatic gases was the driver of explosivity and that the role of external water in these phreatomagmatic stages of the 1211 CE eruption was confined to secondary quench granulation. The analysed juvenile clasts also displayed sharp-bound domains of contrasting vesicularity with boundaries that cross-cut the clast margins. This confirms early mingling of melt batches with different histories of ascent and/or stalling in the shallow conduit. Given such heterogeneity, regions of contrasting vesicularity were analysed separately to construct two vesicle size and number distribution (VSD/VND) datasets. Results from the ongoing micro-textural and additional analysis of volatile degassing shall also be presented here.

How to cite: Grech Licari, J., Moreland, W. M., Thordarson, T., Houghton, B. F., and Bali, E.: Shallow conduit processes and sulfur release in the phreatomagmatic stages of the 1211 CE Younger Stampar eruption, Iceland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3149, https://doi.org/10.5194/egusphere-egu22-3149, 2022.

EGU22-5649 | Presentations | GMPV9.1 | Highlight

Deep seismicity preceding and during the 2021 Fagradalsfjall eruption, Reykjanes Peninsula, Iceland 

Tim Greenfield, Thomas Winder, Nicholas Rawlinson, Esme Southern, Conor Bacon, Thorbjörg Ágústsdóttir, Robert S. White, Bryndis Brandsdottir, John Maclennan, Josef Horalek, Egill Árni Gudnason, and Gylfi Páll Hersir

Using a dense network of seismometers located on the Reykjanes Peninsula of Iceland we image a cluster of earthquakes located at a depth of 10-15 km, beneath the brittle-ductile transition and active before and during the Fagradalsfjall eruption. The deep seismicity has markedly different properties to those earthquakes located in the upper, brittle crust with a lower frequency content and a high b-value suggesting that fluids and/or high temperature gradients could be involved in their initiation. Detailed relocation of the deep seismicity reveals that the locus of the activity shifts southwest after the onset of the eruption, suggesting that although the location of the deep seismicity is unlikely to be the source for the magma which erupted, nevertheless the eruption and the deep earthquakes are linked. We interpret the deep earthquakes to be induced by the intrusion of magma into the lower crust. In such an interpretation, the intruded region could be offset from the conduit that transports the magma from the source region near the base of the crust to the surface.  

How to cite: Greenfield, T., Winder, T., Rawlinson, N., Southern, E., Bacon, C., Ágústsdóttir, T., White, R. S., Brandsdottir, B., Maclennan, J., Horalek, J., Gudnason, E. Á., and Hersir, G. P.: Deep seismicity preceding and during the 2021 Fagradalsfjall eruption, Reykjanes Peninsula, Iceland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5649, https://doi.org/10.5194/egusphere-egu22-5649, 2022.

EGU22-8304 | Presentations | GMPV9.1

An overview of the geochemistry and petrology of the mantle-sourced Fagradalsfjall eruption, Iceland 

Edward Marshall, Maja Rasmussen, Saemundur Halldorsson, Simon Matthews, Eemu Ranta, Olgeir Sigmarsson, Jóhann Robin, Jaime Barnes, Enikö Bali, Alberto Caracciolo, Guðmundur Guðfinnsson, and Geoffrey Mibei

The recent eruption of the Fagradalsfjall complex in the Reykjanes Peninsula of Iceland represents incompletely mixed basaltic magma directly erupted from a sub-crustal storage region. The eruption comprises olivine tholeiite lava with whole rock MgO between 8.7 and 10.1 wt%. The macrocryst cargo comprises olivine up to Fo90, plagioclase up to An89, and Cr-rich clinopyroxene up to Mg# 89. Gabbro and anorthosite xenoliths are rare. Olivine-plagioclase-augite-melt (OPAM) barometry of the groundmass glass from tephra collected from 28th April to 6th May yield high equilibration pressures and suggest that this eruption is originally sourced from a deep (0.48±0.06 GPa) storage zone at the crust-mantle boundary.

 

Over the course of the eruption, Fagradalsfjall lavas have changed significantly in source signature. The first erupted lavas (mid-March) were more depleted (K2O/TiO2 ­= 0.14, La/Sm = 2.1, 87Sr/86Sr = 0.703108, 143Nd/144Nd = 0.513017, 206Pb/204Pb = 18.730) and similar in composition to basalts previously erupted on the Reykjanes Peninsula. As the eruption continued, the lavas became increasingly enriched and were most enriched in early May (K2O/TiO2 = 0.27, La/Sm = 3.1, 87Sr/86Sr = 0.703183, 143Nd/144Nd = 0.512949, 206Pb/204Pb = 18.839), having unusual compositions for Reykjanes Peninsula lavas and similar only to enriched Reykjanes melt inclusions. From early May until the end of the eruption (18th September), the lava K2O/TiO2 and La/Sm compositions displayed a sinuous wobble through time at lower amplitude than observed in the early part of the eruption. The enriched lavas produced later in the eruption are more enriched than lavas from Stapafell, a Reykjanes eruption thought to represent the enriched endmember on the Reykjanes. The full range of compositional variation observed in the eruption is large – about 2.5 times the combined variation of all other historic Reykjanes lavas.

 

The major, trace, and radiogenic isotope compositions indicate that binary mixing controls the erupted basalt compositions. The mixing endmembers appear to be depleted Reykjanes melts, and enriched melts with compositions similar to enriched Reykjanes melt inclusions or Snaefellsnes alkali basalts. The physical mechanism of mixing and the structure of the crust-mantle boundary magmatic system is a task for future study.

 

In contrast to the geochemical variations described above, the oxygen isotope composition (δ18O) of the groundmass glass (5.1±0.1‰) has little variation and is lower than MORB (~5.5‰). Olivine phenocrysts δ18O  values range from typical mantle peridotite values (5.1‰) to lower values (4.6‰), with the lower values in close equilibrium with the host melt. Given the crust-mantle boundary source of the eruption, these low δ18O values are unlikely to represent crustal contamination, and are more likely to represent an intrinsically low δ18O mantle beneath the Reykjanes Peninsula.

How to cite: Marshall, E., Rasmussen, M., Halldorsson, S., Matthews, S., Ranta, E., Sigmarsson, O., Robin, J., Barnes, J., Bali, E., Caracciolo, A., Guðfinnsson, G., and Mibei, G.: An overview of the geochemistry and petrology of the mantle-sourced Fagradalsfjall eruption, Iceland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8304, https://doi.org/10.5194/egusphere-egu22-8304, 2022.

EGU22-8479 | Presentations | GMPV9.1

Basalt production controlled by mantle source fertility at Fagradalsfjall, Iceland 

Olgeir Sigmarsson, Edward W. Marshall, Chantal Bosq, Delphine Auclair, Maja B. Rasmussen, Barbara I. Kleine, Eemu J. Ranta, Simon Matthews, Sæmundur A. Halldórsson, Matthew G. Jackson, Gudmundur H. Gudfinnsson, Enikö Bali, Andri Stefánsson, and Magnús T. Gudmundsson

Mantle melting processes and the characteristics of the source lithologies are mostly derived from basalt compositions of the mid-ocean ridge system and from oceanic islands. However, these basalts are in most cases the products of crustal processes resulting from magma storage, mixing, differentiation and crustal interaction. In Iceland, magma mixing and homogenization in thoroughly stirred magma reservoirs appear to be the norm, leading to restricted variations of Sr and Nd isotope ratio for a given volcanic system. In contrast, more primitive basalts were erupted during the 2021 Fagradalsfjall eruption on the Reykjanes Peninsula with a large spread in isotope ratios. A strong negative correlation between Sr and Nd isotopes is observed from ratios that span a range from a depleted mantle composition to values akin to the Icelandic mantle such as that of the basalts of the Grímsvötn volcanic system. The isotope ratios are also correlated with the measured discharge rate during the eruption, with a depleted Sr isotope ratio appearing during the period of low discharge (around 5 m3/s) for the first month and a half of the eruption. In early May, the magma flux doubled and basalts with more radiogenic Sr isotope composition were produced. During the summer 2021, the Sr isotope ratios declined, due to lower proportions of melts from undepleted mantle source in the basalt mixture erupted. Whether the eruption ended when melts from the enriched mantle was exhausted or not remains to be elucidated, but clearly the highest eruption discharge rate resulted from melts of a more fertile mantle source.

The variable proportions of depleted versus enriched melts in the eruption products demonstrate the absence of a magma reservoir in which homogenization could take place, and from which decreasing discharge rate with time would be expected.  Instead, the initially low and steady and then increasing magma extrusion rate measured, strongly indicate direct mantle melt ascent to surface, which is also supported by the primitive mineralogy of the high-MgO basalt produced. Leaky-transform faults on the mid-ocean ridge system are characterized by eruptions of primitive basalts on intra-transform spreading centres (e.g. Garrett and Siqueiros fracture zones in the East Pacific). The Fagradalsfjall complex appears to be of similar nature, and the primitive magma and the important compositional and temporal variations demonstrate the effect of mantle source composition and associated processes on the eruption behaviour, as reflected in the magma discharge rate.

How to cite: Sigmarsson, O., Marshall, E. W., Bosq, C., Auclair, D., Rasmussen, M. B., Kleine, B. I., Ranta, E. J., Matthews, S., Halldórsson, S. A., Jackson, M. G., Gudfinnsson, G. H., Bali, E., Stefánsson, A., and Gudmundsson, M. T.: Basalt production controlled by mantle source fertility at Fagradalsfjall, Iceland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8479, https://doi.org/10.5194/egusphere-egu22-8479, 2022.

EGU22-8679 | Presentations | GMPV9.1 | Highlight

Conduits feeding new eruptive vents at Fagradajsfjall, Iceland, mapped by high-resolution ICEYE SAR satellite in a daily repeat orbit 

Vincent Drouin, Valentyn Tolpekin, Michelle Parks, Freysteinn Sigmundsson, Daniel Leeb, Shay Strong, Ásta Rut Hjartardóttir, Halldór Geirsson, Páll Einarsson, and Benedikt Gunnar Ófeigsson

Using ground deformation measurements of high spatial and temporal resolution SAR, the understanding of new vents created during volcanic eruptions can be improved with 3D mapping of the activated shallow magma plumbing system. Interferometric analysis of radar data from ICEYE X-band satellites with daily coherent ground track repeat (GTR) provides unprecedented time series of deformation in relation to the opening of 6 eruptive vents over 26 days in 2021, at Fagradalsfjall, Iceland. Unrest started in this location at the end of February and tens of thousands of earthquakes were recorded during the following four weeks. The seismicity was linked to gradual formation of a magma-filled dike in the crust and triggered seismicity along the plate boundary. On 19 March, an eruptive fissure opened near the center of the dyke. New vents and eruptive fissures opened on the 5th, 7th, 10th, and 13th April. The daily acquisition rate of the ICEYE satellite facilitated the observation of the ground openings associated with each new vents. Each event can be observed individually and with minimal loss of signal caused by new lava emplacement, which would occur if images were acquired at a slower rate. Being able to retrieve deformation near the edge of the fissure ensures that we have the optimal constraints needed for modelling the subsurface magma path. The ICEYE dataset consists of Stripmap acquisitions (30x50km) in the period 3-21 March, and Spotlight acquisitions (5x5 km) from 22 March and onward. Images have a resolution of about 2 m x 3 m, and 0.5 m x 0.25 m, respectively. The descending 1-day interferogram covering each individual event is used to invert for the distributed opening along the dike plane. We find that each fissure was associated with opening of up to 0.5 meters in the topmost 200 m of crust. The conduits propagated vertically at least 50–80 m/h. The new fissure locations were influenced by local conditions and induced stress changes within the shallow crust.

How to cite: Drouin, V., Tolpekin, V., Parks, M., Sigmundsson, F., Leeb, D., Strong, S., Hjartardóttir, Á. R., Geirsson, H., Einarsson, P., and Ófeigsson, B. G.: Conduits feeding new eruptive vents at Fagradajsfjall, Iceland, mapped by high-resolution ICEYE SAR satellite in a daily repeat orbit, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8679, https://doi.org/10.5194/egusphere-egu22-8679, 2022.

EGU22-8804 | Presentations | GMPV9.1

Relatively-relocated seismicity during the 2021 Fagradalsfjall dyke intrusion, Reykjanes Peninsula, Iceland: Detailed evolution of a lateral dyke, and comparison to Bárðarbunga-Holuhraun 

Esme Olivia Southern, Tim Greenfield, Tom Winder, Þorbjörg Ágústsdóttir, Bryndís Brandsdóttir, Tomas Fischer, Jana Doubravová, Nick Rawlinson, Robert White, Egill Árni Gudnason, Gylfi Páll Hersir, Pavla Hrubcova, and Conor Bacon

The 2021 Fagradalsfjall eruption on Iceland’s Reykjanes Peninsula was preceded by more than 12 months of elevated activity, beginning around November 2019. This dominantly consisted of episodes of intense seismic swarms, but also featured inflationary episodes in both the Svartsengi and Krísuvík volcanic systems. On 24th February 2021, an exceptionally intense episode of seismicity covering the length of the Peninsula marked the initiation of a dyke intrusion, which continued to develop until the 19th of March, when melt first erupted at the surface. The fissure eruption lasted 6 months, ending on 18th September 2021.

During the intrusion, melt first propagated northeast towards Mt Keilir, then to the southwest, eventually forming a 10 km-long dyke. This was marked by more than 80,000 microearthquakes, recorded by a dense local seismic network and detected and located using QuakeMigrate[1].

We present high precision relative relocations of the seismicity, and tightly constrained focal mechanisms of earthquakes which are dominantly located along the base of the dyke. We compare the Fagradalsfjall seismicity to the 2014-2015 Bárðarbunga-Holuhraun intrusion and eruption seismicity [2], in the context of the contrasting tectonic settings, and markedly different precursory activity.

1: Winder, T., Bacon, C., Smith, J., Hudson, T., Greenfield, T. and White, R., 2020. QuakeMigrate: a Modular, Open-Source Python Package for Automatic Earthquake Detection and Location. https://doi.org/10.1002/essoar.10505850.1

2: Woods, J., Winder, T., White, R. S., and Brandsdóttir, B., 2019. Evolution of a lateral dike intrusion revealed by relatively-relocated dike-induced earthquakes: The 2014–15 Bárðarbunga–Holuhraun rifting event, Iceland. https://doi.org/10.1016/j.epsl.2018.10.032

How to cite: Southern, E. O., Greenfield, T., Winder, T., Ágústsdóttir, Þ., Brandsdóttir, B., Fischer, T., Doubravová, J., Rawlinson, N., White, R., Gudnason, E. Á., Hersir, G. P., Hrubcova, P., and Bacon, C.: Relatively-relocated seismicity during the 2021 Fagradalsfjall dyke intrusion, Reykjanes Peninsula, Iceland: Detailed evolution of a lateral dyke, and comparison to Bárðarbunga-Holuhraun, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8804, https://doi.org/10.5194/egusphere-egu22-8804, 2022.

EGU22-9207 | Presentations | GMPV9.1 | Highlight

Volume, effusion rate, and lava transport during the 2021 Fagradalsfjall eruption: Results from near real-time photogrammetric monitoring 

Gro Pedersen, Joaquin M. C. Belart, Birgir Vilhelm Óskarsson, Magnús Tumi Guðmundsson, Nils Gies, Thórdís Högnadóttir, Ásta Rut Hjartardóttir, Virginie Pinel, Etienne Berthier, Tobias Dürig, Hannah Iona Reynolds, Christpher W. Hamilton, Guðmundur Valsson, Páll Einarsson, Daniel Ben-Yehoshua, Andri Gunnarsson, and Björn Oddsson

The basaltic effusive eruption at Mt. Fagradalsfjall began on March 19, 2021, ending a 781-year hiatus on Reykjanes Peninsula, Iceland. At the time of writing (January 7, 2022), no eruptive activity has been observed since September 18, 2021. To monitor key eruption parameters (i.e., effusion rate and volume), near-real time photogrammetric monitoring was performed using a combination of satellite and airborne stereo images.

By late September 2021, 32 near real-time photogrammetric surveys were completed, usually processed within 3–6 hours. The results are a significant achievement in full-scale monitoring of a lava flow-field providing temporal data sets of lava volume, thickness, and effusion rate. This enabled rapid assessment of eruption evolution and hazards to populated areas, important infrastructure, and tourist centers.

The lava pathways and lava advancement were very complex and changeable as the lava filled and spilled from one valley into another and short-term prediction of the timing of overflow from one valley to another proved challenging. Analysis of thickness maps and thickness change maps show that the lava transport into different valleys varied up to 10 m3/s between surveys as lava transport rapidly switched between one valley to another.

By late September 2021, the mean lava thickness exceeded 30 m, covered 4.8 km2 and has a bulk volume of 150 ± 3 × 106 m3. Around the vent the thickness is up to 122 m. The March–September mean effusion rate is 9.5 ± 0.2 m3/s, ranging between 1–8 m3/s in March–April and increasing to 9–13 m3/s in May–September. This is uncommon for recent Icelandic eruptions, where the highest discharge usually occurs in the opening phase. This behavior may have been due to widening of the conduit by thermo-mechanical erosion with time, and not controlled by magma chamber pressure as is most common in the volcanic zones of Iceland.

How to cite: Pedersen, G., Belart, J. M. C., Óskarsson, B. V., Guðmundsson, M. T., Gies, N., Högnadóttir, T., Hjartardóttir, Á. R., Pinel, V., Berthier, E., Dürig, T., Reynolds, H. I., Hamilton, C. W., Valsson, G., Einarsson, P., Ben-Yehoshua, D., Gunnarsson, A., and Oddsson, B.: Volume, effusion rate, and lava transport during the 2021 Fagradalsfjall eruption: Results from near real-time photogrammetric monitoring, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9207, https://doi.org/10.5194/egusphere-egu22-9207, 2022.

EGU22-9802 | Presentations | GMPV9.1

The REYKJANET local seismic network ideally placed for capturing the 2021 Fagradalsfjall pre-eruptive seismicity: in operation since 2013 

Thorbjörg Ágústsdóttir, Josef Horálek, Egill Árni Gudnason, Jana Doubravová, Gylfi Páll Hersir, Jakub Klicpera, Fridgeir Pétursson, Rögnvaldur Líndal Magnússon, Jiri Málek, Lucia Fojtíková, Tomáš Fischer, Josef Vlček, and Ali Salama

The REYKJANET local seismic network was deployed on the Reykjanes Peninsula, SW Iceland, in 2013; funded by the Czech Academy of Science and supported by Iceland GeoSurvey. The network consists of 15 seismic stations, using Nanometrics Centaur digitizers sampling at a rate of 250 sps with a GPS timestamp. Additionally, 7 stations are equipped with microbarographs. In 2016, REYKJANET was substantially upgraded when short-period seismometers were replaced by Güralp CMG-3ESPC broadband seismometers (eigenperiod T0=30s). The instruments are buried in vaults on concrete pillars and are therefore well coupled with the bedrock. They are powered by batteries recharged by solar and wind power all year round, surviving harsh winter condition and corrosion from geothermal gases. These stations are deployed along the Reykjanes Peninsula, between the Svartsengi and Hengill high temperature geothermal fields, covering an area of about 60x20 km. In the summer of 2021 two new stations were deployed on the eastern part of the Peninsula, each consisting of a Güralp CMG-40T broadband seismometers and a Kinemetrics FBA ES-T EpiSensor also sampling at 250 sps with a GPS timestamp. Since early 2021, data from all REYKJANET stations are streamed in real-time to Iceland GeoSurvey and currently 8 of them are also streamed to the Icelandic Meteorological Office for improved earthquake locations for natural hazard monitoring purposes. Since the deployment of the network in 2013, it has been operated continuously and captured the largest seismic swarms on the Reykjanes Peninsula in 2017, 2019, 2020 and 2021.The REYKJANET network was ideally placed, as the 2021 Fagradalsfjall eruption occurred right in the central part of the network. Here we present the pre-eruptive seismicity of the 2021 Fagradalsfjall eruption in comparison to previous seismic swarms.

The maintenance of REYKJANET, data analysis and interpretation are currently done within the NASPMON project (NAtural Seismicity as a Prospecting and MONitoring tool for geothermal energy extraction), funded through EEA Grants and the Technology Agency of the Czech Republic within the KAPPA Programme.

How to cite: Ágústsdóttir, T., Horálek, J., Gudnason, E. Á., Doubravová, J., Hersir, G. P., Klicpera, J., Pétursson, F., Líndal Magnússon, R., Málek, J., Fojtíková, L., Fischer, T., Vlček, J., and Salama, A.: The REYKJANET local seismic network ideally placed for capturing the 2021 Fagradalsfjall pre-eruptive seismicity: in operation since 2013, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9802, https://doi.org/10.5194/egusphere-egu22-9802, 2022.

EGU22-9846 | Presentations | GMPV9.1

Temporal Fe-Zn isotopic variations in the chemically heterogeneous Fagradalsfjall eruption, 2021 

Madeleine Stow, Julie Prytulak, Kevin Burton, Geoff Nowell, Edward Marshall, Maja Rasmussen, Simon Matthews, Eemu Ranta, and Alberto Caracciolo

Lavas from the 2021 Fagradalsfjall eruption, Iceland, show remarkable, day to month scale temporal variations in trace element and radiogenic isotopic compositions. Changes have been attributed to variation in the depth and degree of melting and/or source lithology, with progressive melting of a deeper, more enriched source as the eruption proceeded [1]. Distinguishing melting processes from source composition can be difficult to untangle using trace elements alone. Radiogenic isotopes are unaffected by the melting processes, but pinpointing lithological variations requires that the radiogenic isotopic compositions of the (unknown) endmembers are distinct and fairly restricted to be able to calculate relative contribution(s) to a lava.

Stable isotopic composition may provide another perspective on the cause of the clear temporal chemical trends in the eruption. For example, it has been proposed that Fe stable isotopes may detect the contribution of distinct mantle lithologies to a lava, due to the contrasting bonding environment of Fe in mantle minerals. Both empirical and theoretical studies show that at equilibrium, pyroxenite should be enriched in heavy Fe isotopes compared to typical mantle peridotite [e.g. 2]. Due to limited (<0.1‰) isotopic fractionation during mantle melting, unevolved basalts should capture this lithological variation. However, more recent theoretical work has argued that unrealistically high proportions of pyroxenite are needed to cause resolvable variations in basalt Fe isotopic composition [3]. Zinc stable isotopes provide a complementary system, with variation in Zn isotopic composition detected between garnet and spinel bearing lithologies [4], and without the added complexities of redox-driven fractionation that may affect Fe isotopes. The basaltic Fagradalsfjall eruption thus provides a unique time series to test whether the changes in trace element chemistry of the erupted lavas is mirrored by Fe-Zn isotopic variation. Variation in degree of melting alone is not expected to cause significant Fe-Zn isotopic fractionation, whereas a change in contribution to the lavas from pyroxene and/or garnet bearing lithologies may be reflected in the Fe-Zn isotopic composition. By combining redox sensitive (Fe) and redox insensitive (Zn) isotope systems we can potentially investigate magmatic processes in terms of the redox evolution of the source. We will present the Fe and Zn isotopic compositions of 15 fresh, glassy basaltic lavas collected during the first 4 months of the eruption. We will discuss the possible cause(s) of isotopic variations and how this adds to our understanding of the Fagradalsfjall eruption, specifically. Finally, this timeseries allows us to re-visit and evaluate the efficacy of using Fe-Zn isotopes to determine variations in mantle lithology.

[1] Marshall et al. (2021), AGU FM Abstract [2] Williams and Bizimis (2014), EPSL, 404, 396-407 [3] Soderman et al. (2021), GCA, 318, 388-414 [4] Wang et al. (2017), GCA, 198, 151-167

How to cite: Stow, M., Prytulak, J., Burton, K., Nowell, G., Marshall, E., Rasmussen, M., Matthews, S., Ranta, E., and Caracciolo, A.: Temporal Fe-Zn isotopic variations in the chemically heterogeneous Fagradalsfjall eruption, 2021, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9846, https://doi.org/10.5194/egusphere-egu22-9846, 2022.

EGU22-10219 | Presentations | GMPV9.1

A comprehensive model of the precursors leading to the 2021 Fagradalsfjall eruption 

Ólafur Flóvenz, Rongjiang Wang, Gylfi Páll Hersir, Torsten Dahm, Sebastian Hainzl, Magdalena Vassileva, Vincent Drouin, Sebastian Heimann, Marius Paul Isken, Egill Árni Gudnason, Kristján Ágústsson, Thorbjörg Ágústsdóttir, Josef Horálek, Mahdi Motagh, Thomas R Walter, Eleonora Rivalta, Philippe Jousset, Charlotte M Krawczyk, and Claus Milkereit

A period of intense seismicity started more than a year prior to the 2021 Fagradalsfjall eruption in Iceland. During the same period, repeated cycles of surface uplift and subsidence were observed in the Svartsengi and Krýsuvík high-temperature (HT) fields, about 8-10 km west and east of the eruption site in Fagradalsfjall, respectively. Such an uplift has never been observed during 40 years of surface deformation monitoring of the exploited Svartsengi HT field. However, cycles of uplift followed by subsidence have been observed earlier at the unexploited Krýsuvík HT field.

Shortly after the start of the unrest, a group of scientists from GFZ-Potsdam and ÍSOR installed additional seismometers, used an optical telecommunication cable to monitor the seismicity and performed gravity measurements in the unrest area.

The data was used for multidisciplinary modelling of the pre-eruption processes (see Flóvenz et al, 2022. Cyclical geothermal unrest as a precursor to Iceland's 2021 Fagradalsfjall eruption. Nature Geoscience (in revision)). It included a poroelastic model that explains the repeated uplift and subsidence cycles at the Svartsengi HT field, by cyclic fluid intrusions into a permeable aquifer at 4 km depth at the observed brittle-ductile transition (BDT). The model gives a total injected volume of 0.11±0.05 km3. Constraining the intruded material jointly by the deformation and gravity data results in a density of 850±350 kg/m3. A high-resolution seismic catalogue of 39,500 events using the optical cable recordings was created, and the poroelastic model explains very well the observed spatiotemporal seismicity.

The geodetic, gravity, and seismic data are explained by ingression of magmatic CO2 into the aquifer. To explain the behaviour of cyclic fluid injections, a physical feeder-channel model is proposed.

The poroelastic model and the feeder-channel model are combined into a conceptual model that is consistent with the geochemical signature of the erupted magma. It explains the pre-eruption processes and gives estimates of the amount of magma involved.

The conceptual model incorporates a magmatic reservoir at 15-20 km depth, fed by slowly upwelling currents of mantle derived magma. Volatiles released from inflowing enriched magma into the sub-Moho reservoir migrated upwards. The volatiles were possibly trapped for weeks or months at the BDT at ~7 km depth beneath Fagradalsfjall, generating overpressure, but not high enough to lift the overburden (~220 MPa) and cause surface deformation. After reaching a certain limiting overpressure, or when a certain volume had accumulated, the magmatic volatiles were diverted upwards, just below the BDT towards the hydrostatic pressurized aquifer (~ 40 MPa) at 4 km depth at the bottom of the convective HT fields. They passed through the BDT and increased the pressure sufficiently (>110 MPa) to cause the uplift.

The lessons learned enlighten the most important factors to help detect precursory volcanic processes on the Reykjanes Peninsula; including detailed monitoring of seismicity, surface deformation, gravity changes and gas content in geothermal fluids. Furthermore, geophysical exploration of the deeper crust by seismic and resistivity measurements are crucial to map possible melt and possible pathways towards the surface.

How to cite: Flóvenz, Ó., Wang, R., Hersir, G. P., Dahm, T., Hainzl, S., Vassileva, M., Drouin, V., Heimann, S., Isken, M. P., Gudnason, E. Á., Ágústsson, K., Ágústsdóttir, T., Horálek, J., Motagh, M., Walter, T. R., Rivalta, E., Jousset, P., Krawczyk, C. M., and Milkereit, C.: A comprehensive model of the precursors leading to the 2021 Fagradalsfjall eruption, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10219, https://doi.org/10.5194/egusphere-egu22-10219, 2022.

EGU22-10330 | Presentations | GMPV9.1 | Highlight

Eruptive vent openings during the 2021 Fagradalsfjall eruption, Iceland, and their relationship with pre-existing fractures 

Ásta Rut Hjartardóttir, Tobias Dürig, Michelle Parks, Vincent Drouin, Vigfús Eyjólfsson, Hannah Reynolds, Esther Hlíðar Jensen, Birgir Vilhelm Óskarsson, Joaquín M. C. Belart, Joël Ruch, Nils Gies, Gro B. M. Pedersen, and Páll Einarsson

The Fagradalsfjall eruption started on the 19th of March 2021 on a ~180 m long eruptive fissure, following a dike intrusion which had been ongoing for approximately three weeks. The eruption focused shortly thereafter on two eruptive vents. In April, new fissure openings occurred northeast of the initial eruption on the 5th, 6/7th, 10th, and 13th of April. The northernmost eruption occurred on the 5th of April, approximately 1 km northeast of the initial fissure, whereas the other fissure openings occurred between this and the initial eruptive vents. Stills from web cameras and time-lapse cameras are available for five of the fissure openings. These data show that the eruptions were preceded by steam emitted from cracks in the exact locations where the eruptions started. The time between the first steam observations and the visual appearance of glowing lava ranged between 15 seconds and 1.5 minutes during night observations and 9 to 23 minutes during daytime observations, the difference is likely explained by different lighting conditions. The eruptive vents are located where the north-easterly oriented dike intersected pre-existing north-south oriented strike-slip faults. These strike-slip faults could be identified on both pre-existing aerial photographs and digital elevation models. A high resolution ICEYE interferogram spanning the first day of the eruption in March reveals deformation where the later vent openings occurred in April. This indicates how Interferometric Synthetic Aperture Radar Analysis (InSAR) could be used to predict where subsequent vent openings are likely. This is of great importance for hazard assessment and defining exclusion zones during fissure eruptions.

How to cite: Hjartardóttir, Á. R., Dürig, T., Parks, M., Drouin, V., Eyjólfsson, V., Reynolds, H., Jensen, E. H., Óskarsson, B. V., Belart, J. M. C., Ruch, J., Gies, N., Pedersen, G. B. M., and Einarsson, P.: Eruptive vent openings during the 2021 Fagradalsfjall eruption, Iceland, and their relationship with pre-existing fractures, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10330, https://doi.org/10.5194/egusphere-egu22-10330, 2022.

EGU22-10343 | Presentations | GMPV9.1

Sub-surface fault slip dynamics during the 2021 Reykjanes unrest (Iceland) 

Simon Bufféral, Elisabetta Panza, Stefano Mannini, and Joël Ruch

The dynamics of fault slip in the upper hundreds of meters of Earth’s crust has long been an open question, as their behavior differs from classical elastic dislocation models and their observation still raises challenges. Here, we analyze centimeter-scale ground resolution aerial optical images of the surface ruptures associated with the 8 Mw ≥ 5.0 sub-surface earthquakes that stroke during the Reykjanes seismo-tectonic unrest, starting on February 24, 2021, and ending with the start of an eruption at Fagradasfjall on March 19, 2021. For four major earthquakes, we apply a sub-pixel correlation technique of pre-, syn- and post-crisis aerial and drone orthomosaics to describe the displacement field on surface blocks. We find that surface offsets reached up to 50 cm, with almost pure dextral strike-slip in a NS direction. These orientations contrast with the overall NE-SW-oriented extensional structures originating from magmatic intrusions and appear as a bookshelf faulting system conjugated to the left-lateral strike-slip plate boundary, oriented ~N070.

On hard grounds (e.g.: lava flows), shallow ruptures reached the surface, reactivating pre-existing structures and displaying an en-échelon succession of hectometric-sized fractures. We believe these ruptures are representative of medium-sized faults behavior in the last few hundred meters of the crust. On soft grounds, however, the rupture was only betrayed by meter-sized en-échelon systems, evidenced by thousands of discrete sub-metric surface fractures we were able to observe in the field and map from the orthomosaics. The sharp deformation gradient we imaged indicates that the dislocation drastically decreased above ten to a few tens of meters below the surface. In this layer, diffuse deformation takes on most of the slip deficit, mainly through inelastic processes. As a result, evidence of the February 2021 earthquake did not endure erosion for more than a few months. Except for an isolated sinkhole which allowed us to assume that one fault pre-existed, there were no markers of its presence before the earthquake. We emphasize that this issue must frequently lead to an underestimation of the seismic hazard when performed from surface traces.

How to cite: Bufféral, S., Panza, E., Mannini, S., and Ruch, J.: Sub-surface fault slip dynamics during the 2021 Reykjanes unrest (Iceland), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10343, https://doi.org/10.5194/egusphere-egu22-10343, 2022.

EGU22-11386 | Presentations | GMPV9.1

Real-time prediction trace gases from the Fagradalsfjall volcanic eruption 

Páll Einarsson, Ólafur Rögnvaldsson, and Haraldur Ólafsson

During the Fagradalsfjall volcanic eruption in Iceland in 2021, the atmospheric flow was simulated at high-spatial and temporal resolutions with the numerical system WRF, including the WRF-Chem for the simulation of trace gases and aerosols.  The output of the real-time simulations of SO2 has been compared to observations, showing that on time-scales of 12-24 hours, the numerical system has considerable skill, but moving to temporal scales shorter than 6 hours leads to substantial drop in the model performance.  The data and the model output suggest that there may be strong long-lasting horizontal gradients in the trace gases and limited horizontal mixing at times, calling for a more dense network of monitoring of gases from the volcano.  Wind variability on the time scale of minutes up to few hours remains a challenge.

How to cite: Einarsson, P., Rögnvaldsson, Ó., and Ólafsson, H.: Real-time prediction trace gases from the Fagradalsfjall volcanic eruption, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11386, https://doi.org/10.5194/egusphere-egu22-11386, 2022.

EGU22-11537 | Presentations | GMPV9.1

Quantifying SO2 emissions from the 2021 eruption of Fagradalsfjall, Iceland, with TROPOMI and PlumeTraj 

Ben Esse, Mike Burton, Catherine Hayer, Sara Barsotti, and Melissa Pfeffer

Effusive eruptions are a significant source of volcanic volatile species, injecting various reactive and climate altering products into the atmosphere, while low-level emissions can be hazardous to human health due to the degradation of local or regional air quality. Quantification of the flux and composition of these emissions also offers an insight into the magmatic processes driving the eruption. These factors mean that gas flux measurements are a key monitoring tool for managing the response to such eruptions. The usual target species for gas flux measurements is sulphur dioxide (SO2) due to its high concentration in volcanic emissions but low ambient concentration, and its ability to be measured with UV and IR spectroscopy from both ground and space.

Fagradalsfjall volcano, Iceland, underwent an effusive eruption between March – September 2021, emitting over 100 million m3 of lava and producing significant SO2 emissions. The eruption progressed through several distinct phases in eruptive style, with different surface activity and gas emission behaviour for each. Satellite instruments have not traditionally been used for monitoring emissions from effusive eruptions such as this, as they often lack the spatial or temporal resolution to detect and quantify low-level effusive emissions. However, the launch of ESA’s Sentinel-5P, carrying the TROPOMI instrument, in October 2017 opened the door for such measurements, offering a step change in sensitivity to tropospheric emissions over previous missions.

Here, we will present measurements of altitude- and time-resolved SO2 fluxes from Fagradalsfjall by combining TROPOMI observations with a back-trajectory analysis toolkit called PlumeTraj. We compare the emissions with other geophysical monitoring streams throughout the eruption and explore changes across the different phases of the eruption. This will demonstrate the ability of TROPOMI and PlumeTraj for quantifying intra-day, low-level SO2 emissions and highlight the potential insight these measurements can provide for future effusive eruptions.

How to cite: Esse, B., Burton, M., Hayer, C., Barsotti, S., and Pfeffer, M.: Quantifying SO2 emissions from the 2021 eruption of Fagradalsfjall, Iceland, with TROPOMI and PlumeTraj, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11537, https://doi.org/10.5194/egusphere-egu22-11537, 2022.

EGU22-11995 | Presentations | GMPV9.1

Widespread ground cracks generated during the 2021 Reykjanes oblique rifting event (SW Iceland) 

Joël Ruch, Simon Bufféral, Elisabetta Panza, Stefano Mannini, Birgir Oskarsson, Nils Gies, Celso Alvizuri, and Ásta Rut Hjartardóttir

The Reykjanes Peninsula has recently been subject to a seismo-tectonic unrest triggering widespread ground cracks. This started with a strong seismic swarm from 24 February to 17 March 2021 and culminated in a volcanic eruption on March 19, terminating an 800 years quiescence period in the region. The Peninsula hosts four overlapping and highly oblique rift zones. The structural relations between the plate boundary (N070), the rift zones (N030 to N040) and the barely visible fault zones oriented N175 are challenging to assess, as most structures, beside the rifts, are poorly preserved or absent in the landscape. 

To get the full picture of the fracture field generated by the 2021 Reykjanes rifting event, we collected an unprecedented amount of structural data, mapping almost the entire fresh fracture field. Field observations show widespread ground cracks in up to ~7 km distance from the intrusion area with en-echelon metrical segments with a right-lateral sense of shear. Most of these structures are not visible anymore, either covered by lava flows or eroded due to weathering. They are unique testimony of the strong seismicity preceding the eruption and would have remained unnoticed if not caught up by our fixed-wing drone, surveying an area of ~30 km2. We used the resulting high-resolution (<5 cm) orthomosaics and DEMs to study three main NS-oriented fracture zones of 3 to 4 kilometers long, mostly generated by ten earthquakes ranging from M5 to M5.6. Results show metric to decametric en-echelon structures with cracks of very limited extension, even in the vicinity of the eruption site. Two of the three main fracture zones clearly show fault reactivation, suggesting episodicity in the rifting processes. Apart from local sinkholes, the third area has probably also been reactivated, but the loose ground composition did not preserve previous structures.

We further used high-resolution optical image correlation technique to analyze aerial photos and drone imagery acquired before and after the large earthquakes sequence in the three fracture zones. Results show clear NS-oriented shear structures with a right-lateral sense of motion of up to 50 cm. This is in good agreement with moment tensors we computed from waveform data at seismic stations up to 1000 km distance. We observe consistent non-double-couple mechanisms, with tension-crack components oriented northwest-southeast. The orientations suggest strike-slip faulting with nodal planes oriented in the same direction as the main fault traces. We also found that the three fracture zones have sigmoid shapes and their overall extension bounds the near-field deformation of the plate boundary. These sigmoids may suggest a local high geothermal gradient and elasto-plastic deformation affecting the Reykjanes Peninsula, that further decreases toward the South Icelandic Seismic Zone.

How to cite: Ruch, J., Bufféral, S., Panza, E., Mannini, S., Oskarsson, B., Gies, N., Alvizuri, C., and Hjartardóttir, Á. R.: Widespread ground cracks generated during the 2021 Reykjanes oblique rifting event (SW Iceland), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11995, https://doi.org/10.5194/egusphere-egu22-11995, 2022.

EGU22-12260 | Presentations | GMPV9.1

Monitoring volcanic plume height and fountain height using webcameras at the 2021 Fagradalsfjall eruption in Iceland 

Talfan Barnie, Manuel Titos, Tryggvi Hjörvar, Bergur Bergsson, Sighvatur Pálsson, Björn Oddson, Sara Barsotti, Melissa Pfeffer, Sibylle von Löwis of Menar, Eysteinn Sigurðsson, and Þórður Arason

The 2021 Fagradalsfjall basaltic fissural eruption in Iceland was closely studied due to its proximity to Reykjavík, which allowed easy installation and maintenance of monitoring equipment. Here we present the results from a network of calibrated webcameras maintained by the Icelandic Meteorological Office and Department of Civil Protection and Emergency Management which were used to monitor volcanic plume height and fire fountain height. A number of different camera designs optimised for different power and communications constraints were used, some built in house at IMO, and they will be presented here. To make a 3D height measurement from a 2D web camera image requires extra geometric constraints, which are provided by assuming the vent location and wind direction, in a similar manner to the method applied at Etna. We have implemented this technique as a react.js single page app, which is kept updated by a messaging queue system which pushes new images through the servers at IMO. Additionally, the webcameras have to be calibrated, in that the geometry of the camera and lens distortion parameters have to be known - this is either perfomed in the laboratory, or where the cameras were not available before installation, using one of a number of vicarious calibration techniques developed for this purpose. The resulting plume heights were used to constrain SO2 dispersion models that were the basis for air quality forecasts during the eruption. 

How to cite: Barnie, T., Titos, M., Hjörvar, T., Bergsson, B., Pálsson, S., Oddson, B., Barsotti, S., Pfeffer, M., von Löwis of Menar, S., Sigurðsson, E., and Arason, Þ.: Monitoring volcanic plume height and fountain height using webcameras at the 2021 Fagradalsfjall eruption in Iceland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12260, https://doi.org/10.5194/egusphere-egu22-12260, 2022.

EGU22-12435 | Presentations | GMPV9.1

Co-eruptive subsidence during the 2021 Fagradalsfjall eruption: geodetic constraints on magma source depths and stress changes 

Halldór Geirsson, Michelle Parks, Freysteinn Sigmundsson, Benedikt G. Ófeigsson, Vincent Drouin, Cécile Ducrocq, Hildur M. Friðriksdóttir, Sigrún Hreinsdóttir, and Andrew Hooper

Geodetic observations during volcanic eruptions are important to constrain from where the eruptive products originate in the sub-surface. Some eruptions are sourced from magma reservoirs shallow in the crust, whereas others may tap magma directly from the mantle. The 2021 Fagradalsfjall eruption took place on the Reykjanes Peninsula, Iceland, during March 19 to September 18, resulting in approximately 0.15 km3 of erupted basaltic lava. A wide-spread crustal subsidence and inward horizontal motion, centered on the eruptive site, was observed during the eruption. Nearest to the emplaced lava flows, additional localized subsidence is observed due to the loading of the lavas. The regional subsidence rate varied during the eruption: it was low in the beginning and then increased, in broad agreement with changes in the bulk effusive rate. In this study we use GNSS and InSAR data to model the deformation source(s) during different periods of the eruption, primarily aiming to resolve the depth and volume change of the magma source. We furthermore calculate crustal stress changes during the eruption and compare to the regional seismicity.

How to cite: Geirsson, H., Parks, M., Sigmundsson, F., Ófeigsson, B. G., Drouin, V., Ducrocq, C., Friðriksdóttir, H. M., Hreinsdóttir, S., and Hooper, A.: Co-eruptive subsidence during the 2021 Fagradalsfjall eruption: geodetic constraints on magma source depths and stress changes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12435, https://doi.org/10.5194/egusphere-egu22-12435, 2022.

EGU22-12548 | Presentations | GMPV9.1

Array observations of an oscillating seismic sequence in the Reykjanes Peninsula, SW-Iceland, in December 2021 

Hanna Blanck, Benedikt Halldórsson, and Kristín Vogfjord

In the evening hours of 21 December 2021, a seismic sequence started in south-central Reykjanes peninsula in SW-Iceland. Both the science community and the civil protection agency were alarmed due to the proximity of this sequence to the site of the 2021 Fagradalsfjall eruption (March – September 2021), especially as this was the most prominent sequence since the end of the eruption and it showed similar characteristic as the seismic activity that had been observed in the 3 weeks leading up to it. In addition, the December earthquake sequence was located along a NE-SW striking alignment which, together with GPS and InSAR measurements, has been interpreted as a dike intrusion, which also was the origin of the March eruption. We analyse the seismic activity using a small-aperture (D=1.7 km, d=0.5 km) urban seismic array, consisting of 5 Raspberry Shake 4D sensors (1 vertical geophone and 3 MEM accelerometric components) located in the nearby municipality of Grindavík about 10 km WSW from the former eruption site. During the first days of the seismic activity magnitudes reached up to ML 4.8 but on 30 December the activity subsided and then ceased, with only few events reaching more than ML 2, which coincides with the magnitude of completeness of the seismic array.  

We present the first insights into the spatiotemporal characteristics of the sequence provided by array processing of the most intense period of the sequence. To process the array data, we used the SeisComP module AUTOLAMBDA with both the FK and PMCC (Progressive Multi-Channel Correlation) method to obtain back azimuth and slowness pairs of incoming waves. During its first hours, the sequence showed a systematic behaviour in the back azimuthal distribution of the incoming waves. Namely, over a repeated interval of a couple of hours the back azimuthal estimates increase steadily at a rate of 5 to 12°/h after which the source of the activity appears to drop back to the initial azimuthal values, and the cycle repeats. Over the following days, these bursts of oscillating activity become less frequent with relatively calm phases between. These periods of oscillating behaviour show that the seismic activity was systematically migrating southwest to/from northeast and most likely is the signature of a pulsating magma pressure front in the dike itself. This behaviour is similar to some phases during the previous eruption when lava was actively erupting with hours of quiescence in between. These results show that the monitoring of automatic back azimuth and slowness estimates are a useful tool in revealing small-scale systematic behaviour of seismic sequences in the area in real-time. 

How to cite: Blanck, H., Halldórsson, B., and Vogfjord, K.: Array observations of an oscillating seismic sequence in the Reykjanes Peninsula, SW-Iceland, in December 2021, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12548, https://doi.org/10.5194/egusphere-egu22-12548, 2022.

EGU22-12772 | Presentations | GMPV9.1

Origin of gabbro and anorthosite mineral clusters in Fagradalsfjall lavas 

William Wenrich, Eniko Bali, Edward W. Marshall, and Gudmundur Gudfinnssonn

The 2021 Fagradalsfjall lava brought a number of mineral clusters/xenoliths <6cm in diameter to the surface. Of the >40 samples collected from the field, eight xenoliths and one plagioclase megacryst were analyzed by stereo- and petrographic microscopes and the electron microprobe. In hand specimen, the xenoliths were sub-rounded to rounded, and were olivine and clinopyroxene bearing anorthositic gabbros and anorthosites. During thin section characterization, deformed and undeformed textural types were distinguished. In deformed xenoliths, deformation textures such as undulose extinction, deformed albite twinning, and triple junctions were observed in plagioclases. Plagioclase in deformed samples was typically unzoned and had bimodal crystal size distribution. Olivines had normal zoning where they were in contact with interstitial melt and more pronounced zoning was observed on the edges on the clusters. Undeformed samples did not show deformation features and had ophitic and poikilitic texture. Clinopyroxene in undeformed xenoliths was commonly observed interstitially as well as discrete subhedral crystals. The interstitial clinopyroxene resorbed the edges of plagioclase and olivine and had uniform extinction in all but one sample. 
Electron microprobe results show that the compositional variation of minerals within the xenoliths overlaps and exceeds the compositional variation of the host lava macrocryst cargo. Olivine forsterite, plag anorthite, Cpx Mg#, and Cr# content ranged from 80-89, 76-89, 82-87, and 6-18, respectively in mineral cores and 59-86, 65-86, 71-87, and 0.4-12, respectively, in zoned rims. Mineral compositions overlap in both deformed and undeformed samples. In general, undeformed samples cover a broader range compared to deformed ones, the latter being much more uniformly primitive. One deformed sample is an outlier with significantly lower forsterite (~73-79), anorthite (~66-71), and Mg# (~74) in clinopyroxene compared to the rest of the clusters and lava phenocrysts.
Plagioclases in most xenoliths contained devitrified silicate melt inclusions. Melt compositions after post entrapment corrections are in equilibrium with their host plagioclases according to Putirka (2008). The calculated temperatures based on plagioclase melt pairs indicate a difference in crystallization environment between the clusters that overlap the lava phenocrysts and the evolved outlier. The average crystallization temperatures for most xenoliths is 1222°C, whereas for the deformed one is 1191°C, respectively. With an error of ±23°C, these two temperatures could be from separate sources.

How to cite: Wenrich, W., Bali, E., Marshall, E. W., and Gudfinnssonn, G.: Origin of gabbro and anorthosite mineral clusters in Fagradalsfjall lavas, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12772, https://doi.org/10.5194/egusphere-egu22-12772, 2022.

EGU22-13461 | Presentations | GMPV9.1

Evolution of deformation and seismicity on the Reykjanes Peninsula, preceding the 2021 Fagradalsfjall eruption, Iceland 

Michelle Parks, Kristín S. Vogfjörd, Freysteinn Sigmundsson, Andrew Hooper, Halldór Geirsson, Vincent Drouin, Benedikt G. Ófeigsson, Sigrún Hreinsdóttir, Sigurlaug Hjaltadóttir, Kristín Jónsdóttir, Páll Einarsson, Sara Barsotti, Josef Horálek, and Thorbjörg Ágústsdóttir

The 2021 effusive eruption at Mt. Fagradalsfjall, on the Reykjanes Peninsula oblique rift in Iceland, was preceded by a 14-month long period of volcano-tectonic unrest (comprising both significant ground deformation and intense seismicity). A seismic swarm was initially detected in the Fagradalsfjall region between the 15th to 20th December 2019. Following a short quiescence, activity re-commenced on the 21st January 2020, with a small cluster of earthquakes near Grindavík (~ 10 km west of Fagradalsfjall). Concurrent deformation was detected on two GNSS stations in this area and on Sentinel-1 interferograms. Geodetic modelling of these observations indicated the deformation most likely resulted from the intrusion of a magmatic sill, directly west of Mt. Thorbjörn, at a depth of about 4 km. This was followed by two additional sill-type intrusions in a similar location, between 6th March - 17th April and 15th May - 22nd July 2020 respectively. The three intrusions comprised a total volume change of about 9 million cubic meters. In mid-July 2020, inflation was again detected on the Reykjanes Peninsula, this time in the Kýsuvík volcanic system to the east of Fagradalsfjall. This episode of inflation lasted several weeks and geodetic inversions indicated the observed signal was produced by the combination of a deflating sill-like source at a depth of ~16 km and inflation of a body at a depth of ~6 km. The latter, corresponding to a volume change of about 5 million cubic meters. During this period of intrusive activity, seismicity shifted along various regions across the Peninsula, in relation to a combination of processes – magma migration, triggered seismicity and tectonic earthquakes.

 

Intense seismic swarms commenced on the 24th February 2021, concentrated at both Fagradalsfjall and also extending across a 20 km segment along the plate boundary – including triggered strike-slip earthquakes up to Mw5.64. At the same time, deformation was detected on local GNSS stations, and subsequent Interferometric Sythethic Aperture Radar Analysis (InSAR) of Sentinel-1 data confirmed the observed deformation was primarily the result of a dike intrusion and slip along the plate boundary. Geodetic inversions indicated a ~9 km long dike with a total intruded volume of around 34 million cubic meters (Sigmundsson et al., in review). During this period, stored tectonic stress was systematically released, resulting in a decline in deformation and seismicity over several days preceding the eruption onset, on 19th March 2021 in Geldingadalir at Mt. Fagradalsfjall. The eruption continued until the 18th September 2021 and produced a lava field covering an area of 4.8 km2 with an extruded bulk volume of 150 ± 3 × 106 m3 (Pedersen et al., in review).

 

References

Sigmundsson et al. (in review). Deformation and seismicity decline preceding a rift zone eruption at Fagradalsfjall, Iceland.

 

Pedersen et al. (in review). Volume, effusion rate, and lava transport during the 2021 Fagradalsfjall eruption: Results from near real-time photogrammetric monitoring. DOI:10.1002/essoar.10509177.1.

How to cite: Parks, M., Vogfjörd, K. S., Sigmundsson, F., Hooper, A., Geirsson, H., Drouin, V., Ófeigsson, B. G., Hreinsdóttir, S., Hjaltadóttir, S., Jónsdóttir, K., Einarsson, P., Barsotti, S., Horálek, J., and Ágústsdóttir, T.: Evolution of deformation and seismicity on the Reykjanes Peninsula, preceding the 2021 Fagradalsfjall eruption, Iceland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13461, https://doi.org/10.5194/egusphere-egu22-13461, 2022.

EGU22-13504 | Presentations | GMPV9.1

Imaging the anisotropic structure of the Reykjanes Peninsula across the 2021 Fagradalsfjall dyke intrusion through local shear-wave splitting analysis 

Amber Parsons, Conor Bacon, Tim Greenfield, Tom Winder, Thorbjörg Ágústsdóttir, Bryndís Brandsdóttir, Tomas Fischer, Jana Doubravová, Nicholas Rawlinson, Robert White, Egill Árni Gudnason, Gylfi Páll Hersir, and Pavla Hrubcova

Since late 2019, the Reykjanes Peninsula in Iceland has experienced elevated seismic activity, which culminated in a dyke intrusion beneath Fagradalsfjall on 24th February 2021, and an eruption on 19th March. Seismic anisotropy – the directional dependence of seismic wave speed – can be used to study structural properties of the crust, which may be controlled by the state of stress through preferential closure of micro-cracks. This provides an opportunity to investigate changes in crustal stress regime caused by a dyke intrusion, with potential applications in eruption monitoring and forecasting.

 

A dense seismic network spanning Fagradalsfjall recorded more than 130,000 earthquakes between June 2020 and August 2021; detected and located using QuakeMigrate1. From this dataset, we calculate the seismic anisotropy of the upper crust through shear-wave splitting analysis. Exceptional ray-path coverage allows for imaging at high spatial and temporal resolution. We present these results in relation to the regional stress regime and tectonic structure, and search for changes in anisotropy before, during, and after the dyke intrusion and eruption.

 

1: Winder, T., Bacon, C., Smith, J., Hudson, T., Greenfield, T. and White, R., 2020. QuakeMigrate: a Modular, Open-Source Python Package for Automatic Earthquake Detection and Location. https://doi.org/10.1002/essoar.10505850.1

How to cite: Parsons, A., Bacon, C., Greenfield, T., Winder, T., Ágústsdóttir, T., Brandsdóttir, B., Fischer, T., Doubravová, J., Rawlinson, N., White, R., Gudnason, E. Á., Hersir, G. P., and Hrubcova, P.: Imaging the anisotropic structure of the Reykjanes Peninsula across the 2021 Fagradalsfjall dyke intrusion through local shear-wave splitting analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13504, https://doi.org/10.5194/egusphere-egu22-13504, 2022.

TS12 – Imaging large-scale tectonic structures

EGU22-376 | Presentations | SM5.6

Three-dimensional electrical conductivity structure of the contiguous US from USArray MT data 

Federico Munch and Alexander Grayver

Knowledge about the electrical conductivity structure of the Earth's interior is a key to understanding its thermo-chemical state and evaluate the impact of space weather events. USMTArray is a high quality data set of magnetotelluric measurements that addresses both of these problems. Covering ~70% of the contiguous United States on a quasi-regular 70 km spaced grid, this unique publicly available data led to the development of several regional 3D electrical conductivity models. However, an inversion of the entire data set demands novel multi-scale imaging approaches that can handle and take advantage of a large range of spatial scales contained in the data. We present a 3D electrical conductivity model of the contiguous United States derived from the inversion of ~1100 USArray magnetotelluric stations. The use of state-of-the-art modeling techniques based on high-order finite-element methods allows us to take into account complex coastline and reconstruct Earth’s conductivity across many scales. The retrieved electrical conductivity variations are in overall agreement with well-known continental structures such as the active tectonic processes within the western United States (e.g., Yellowstone hotspot, Basin and Range extension, and subduction of the Juan de Fuca slab) as well as the presence of deep roots (~250 km) beneath cratons.

How to cite: Munch, F. and Grayver, A.: Three-dimensional electrical conductivity structure of the contiguous US from USArray MT data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-376, https://doi.org/10.5194/egusphere-egu22-376, 2022.

EGU22-562 | Presentations | SM5.6

Toward a three-dimensional tomographic model of the Pacific upper mantle with full resolution and uncertainties 

Franck Latallerie, Christophe Zaroli, Sophie Lambotte, and Alessia Maggi

Tomographic models suffer from unevenly distributed noisy data and therefore have complicated resolution and uncertainties that can hinder their interpretation. Using linear Backus & Gilbert inversion, it is possible to obtain tomographic models with resolution and uncertainties in a single step. Using such a method, we aim to produce a three-dimensional tomographic model of the Pacific upper mantle from surface-wave data. To linearise the forward problem, we use finite-frequency theory to describe the sensitivity of surface-wave phase-delays to the three-dimensional shear-wave velocity. We build a data-base of phase-delay measurements for surface-waves that cross the Pacific Ocean. We estimate the data uncertainties caused by measurement errors using a multitaper technique and those caused by poor knowledge of the seismic source and crust by a Monte-Carlo method. Using the Backus & Gilbert approach, the phase-delay dataset, and the data uncertainty estimates, we obtain a model of the shear-wave velocity of the Pacific upper mantle together with its three-dimensional resolution and uncertainties. These allow us to discuss, using robust statistical arguments, the existence and the three-dimensional organisation of structures we expect to see in the Pacific upper mantle, such as plume-like upwellings or small-scale sub-lithospheric convections.

How to cite: Latallerie, F., Zaroli, C., Lambotte, S., and Maggi, A.: Toward a three-dimensional tomographic model of the Pacific upper mantle with full resolution and uncertainties, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-562, https://doi.org/10.5194/egusphere-egu22-562, 2022.

EGU22-1567 | Presentations | SM5.6

LitMod3D_4inv: Multi-observable and multi-scale geophysical inversions for the physical state of the Earth. 

Ilya Fomin, Juan Afonso, and Constanza Manassero

Characterising the physical state of the Earth's interior with high resolution requires the joint inversion of complementary geophysical datasets. LitMod3D_4inv is a method/software that allows regional and continental scale joint inversions within a probabilistic framework for the 3D thermochemical structure of the lithosphere and upper mantle. The software can simultaneously invert gravity anomalies, geoid height, gravity gradients, Love and Rayleigh surface-wave dispersion curves, receiver functions, body-wave travel times, surface heat flow, absolute elevation and magnetotelluric data, or any combination of them. The result is a collection of Earth models (a probabilistic distribution) with exceptional explicative power and robust estimates for uncertainties.

We use equations of state and Gibbs free energy minimisation routines to produce self-consistent sets of the seismic velocities, densities, and other properties from the actual parameters (unknowns) of the inversion – mantle chemical compositions, thermal profiles, and properties of the crustal layers (thickness, reference densities, Vp/Vs). The code relies on highly-optimised solvers for gravity, seismic, and magnetotelluric forward problems and multi-level hybrid parallel architecture to make use of multiple interacting markov chains. The modular structure of the code allows for extending the set of solvers to include new observables or to implement new Markov chain Monte Carlo algorithms.

In this presentation we will discuss recent developments in the LitMod3D_4inv suite and illustrate their performance with real examples in eastern Canada, in southern and central Africa, and north eastern Australia.

How to cite: Fomin, I., Afonso, J., and Manassero, C.: LitMod3D_4inv: Multi-observable and multi-scale geophysical inversions for the physical state of the Earth., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1567, https://doi.org/10.5194/egusphere-egu22-1567, 2022.

EGU22-1920 | Presentations | SM5.6

Imaging oceanic basins with wave equation and radiative transfer models 

Chiara Nardoni, Luca De Siena, Fabio Cammarano, Fabrizio Magrini, and Elisabetta Mattei

When seismic information is used to map Earth structures, a primary challenge is modelling the response of seismic wavefields to strong lateral variations in medium properties. These variations are especially relevant across oceanic basins with mixed continental-oceanic crust and including magmatic systems. These highly-scattering and absorption media produce stochastic signatures that are hard to separate from complex coherent reverberations due to shallow Moho. The discrimination between these two effects is fundamental for improving full-waveform techniques when imaging oceanic basins at regional and global scales. Here, we present a joint tomographic and modelling approach focusing on the ~1 Hz frequency band, where seismic scattering and attenuation mechanisms are predominantly resonant. Firstly, we image late-time coda attenuation as a marker of seismic absorption across the Italian peninsula and the Tyrrhenian Sea. Regional-scale data provide the ideal benchmark to explore the potential of attenuation imaging using radiative-transfer-derived sensitivity kernels in a mixed continental-oceanic crust. Then, we explore the response of seismic wavefield to structural variations combining coda-attenuation imaging with simulations based on radiative transfer and wave-equation modelling. The results provide evidence of intra-crustal reverberations and energy leakage in the mantle, finally being able to map Moho depths with regional earthquakes. This work is an ideal forward model of seismic wavefields recorded across the oceanic crust for future full-waveform inversions and imaging of crustal discontinuities.

How to cite: Nardoni, C., De Siena, L., Cammarano, F., Magrini, F., and Mattei, E.: Imaging oceanic basins with wave equation and radiative transfer models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1920, https://doi.org/10.5194/egusphere-egu22-1920, 2022.

EGU22-2459 | Presentations | SM5.6

Surface-wave tomography of the South-East Asia by joint inversion of Rayleigh and Love phase velocities from seismic ambient noise and teleseismic earthquakes 

Fabrizio Magrini, Luca De Siena, Simone Pilia, Nicholas Rawlinson, and Boris Kaus

South-East Asia hosts the largest and most complicated subduction system of our planet, associated with extensive volcanism and seismicity. Obtaining high-resolution seismic images of South-East Asia can provide important constraints on the lateral variations of physical parameters such as density, composition, temperature, and viscosity of this dynamic patchwork. In turn, this has relevant implications on our ability to forecast its geodynamic evolution by numerical modeling. In this study, we join all the publicly-available seismic data distributed across the Malay Peninsula, Sumatra, Java, Sulawesi, South Borneo, and North Australia (amounting of 468 broad-band seismic receivers) with the continuous seismograms from 70 receivers recently installed in North Borneo, resulting in an unprecedented seismic coverage of the region.
We first use such data to extract Rayleigh and Love phase velocities based on both seismic ambient noise and teleseismic earthquakes. Overall, we retrieve 14,036 Rayleigh- and 12,005 Love-wave dispersion curves, covering surface-wave periods between 3 and 150 s and sensitive to both the shallow crust and the upper mantle. We then invert the dispersion curves for phase-velocity maps at different periods, using a linearized-inversion algorithm based on the ray theory with a roughness damping constraint. In doing so, we adopt an adaptive parameterization, allowing for a finer resolution of the resulting maps in the areas characterized by a relatively high density of measurements. At relatively short periods (<20 s), the phase-velocity maps are characterized by strong lateral heterogeneities. We find, for example, relatively low velocities in correspondence of the Central- and South-Sumatra Basin, ascribed to thick sedimentary layers, and higher velocities in the (adjacent) Barisan Mountains. Low velocities also characterize a large region approximately centered onto the Merapi volcano (Central Java), the Mentawai islands (in correspondence of the Mentawai Fault System), the Sahul Shelf (including the East Timor island), and the marine region between east Borneo and Sulawesi. Relatively high velocities are found below the Banda Sea. The amplitude of such lateral variations quickly decreases at larger periods and, among the most pronounced features, we observe relatively low velocities in the north-east of Borneo (as opposed to its south-western part), and high velocities in the Celebes Sea (north of the North-Sulawesi Trench).
At the time of writing, we are planning to translate the phase-velocity maps thus retrieved into shear-wave velocity (Vs) as a function of depth. Specifically, we plan to extract one Rayleigh- and one Love-wave phase-velocity profile for each grid cell constituting our phase-velocity maps, and (non-linearly) jointly invert them for Vs using the neighbourhood algorithm. The resulting 3-D tomographic model will thus be interpreted in light of the existing literature on the study area, involving (but not limited to) geodynamic and geologic models, geophysical, geochemical, and geodetic observations.

How to cite: Magrini, F., De Siena, L., Pilia, S., Rawlinson, N., and Kaus, B.: Surface-wave tomography of the South-East Asia by joint inversion of Rayleigh and Love phase velocities from seismic ambient noise and teleseismic earthquakes, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2459, https://doi.org/10.5194/egusphere-egu22-2459, 2022.

EGU22-2686 | Presentations | SM5.6

Scattering and Absorption Imaging of the North Anatolian Fault Zone, northern Turkey 

Panayiota Sketsiou, David Cornwell, and Luca De Siena

The North Anatolian Fault (NAF) is a right-lateral, strike-slip fault in the northern part of the Anatolian peninsula. It is estimated to have a length of up to 1500 km, extending westwards between the Karliova Triple Junction, where it nucleates, to the Aegean Sea. In the west and close to the Sea of Marmara, the NAF splays into northern (NNAF) and southern (SNAF) strands. The splay of the western part of the NAF separates the area into three primary terranes: the Istanbul Zone (north of the northern strand), the Armutlu-Almacik Block (between the two strands of the fault) and the Sakarya Zone (south of the southern strand).

There have been a series of high-magnitude earthquakes along the NAF since the 1930s, migrating from east to west. In order to investigate the western part of the North Anatolian Fault Zone (NAFZ), which is the most seismically active at the moment, the Dense Array for North Anatolia (DANA) temporary seismic network was deployed for 18 months between 2012 and 2013. A set of local earthquakes, recorded by DANA, were utilised to study the 2D scattering and coda attenuation structure in the western NAFZ, between 1 and 18 Hz. P-wave arrival times were manually picked and the events were re-located using the Non-Linear Location software. Peak-delay travel times were calculated as a measure of forward scattering, and the exponential decay of the coda wave envelopes was used to invert for the absorption structure using multiple scattering sensitivity kernels.

The obtained models are 2D averages of the first 10-15 km of the crust, where the majority of the seismic activity is located and they have been compared to recent geophysical studies in the same area. The scattering structure, between 1 and 6 Hz, highlights the three main tectonic units in the area. The absorption structure is generally more heterogeneous than the scattering structure, with the overall absorption decreasing as the frequency increases. The lithological variations and heterogeneity between and within the three terranes of the area, arising from the complex tectonic history of the region, are believed to be the main reasons for the scattering and absorption observations made. The high absorption zones observed along the two branches of the fault, and especially the southern branch, is a very important finding, as the signature of the southern branch in geophysical studies is often unclear.

How to cite: Sketsiou, P., Cornwell, D., and De Siena, L.: Scattering and Absorption Imaging of the North Anatolian Fault Zone, northern Turkey, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2686, https://doi.org/10.5194/egusphere-egu22-2686, 2022.

EGU22-3257 | Presentations | SM5.6

Using K-Means Clustering to Compare Adjoint Waveform Tomography Models of California and Nevada 

Claire Doody, Arthur Rodgers, Christian Boehm, Michael Afanasiev, Lion Krischer, Andrea Chiang, and Nathan Simmons

Full waveform inversion models by adjoint methods represent the most detailed seismic tomography models currently available for waveform simulations. However, the influence of starting models on final inversion results is rarely studied due to computational expense. To study this influence, we present three adjoint waveform tomography models of California and Nevada using three different starting models:  the SPiRaL global model (Simmons et al., 2021), the CSEM_NA model (Krischer et al., 2018), and the WUS256 model (Rodgers et al., 2021). Each model uses the same dataset of 103 events between magnitudes 4.5 and 6.5 that occurred from January 1, 2000 to October 31st, 2020. For each event, 175-475 stations record data, creating dense path coverage over California. The model iterations are computed using Salvus. We begin by  running iterations for each starting model at three period bands: 30-100 seconds, 25-100 seconds, and 20-100 seconds. For each period band, we run iterations until the average misfit for all events is no longer reduced; over all period bands, we run more than 55 iterations and see misfit reductions of up to 40% in some period bands. Each model shows velocity anomalies of up to 20%, but the difference in VS values between the models can be significant. Most of these differences seem to correlate with small-scale differences in the starting models. To test whether these differences between the models could affect the interpretation of their results, we utilize k-means clustering to analyze the similarities in large-scale structure in all three models (e.g. Lekic and Romanowicz, 2011). We separate each model into a crustal layer (0-30km depth) and uppermost mantle layer (30-150km), then run a k-means clustering algorithm on absolute Vs wavespeeds and anisotropy [(Vsh/Vsv)^2] separately. We show that regardless of the differences seen on visual inspection, all three models can resolve tectonic-scale structures equally.

 

This work was supported by LLNL Laboratory Directed Research and Development project 20-ERD-008. This work was performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under Contract DE-AC52-07NA27344. LLNL-ABS-830615.

How to cite: Doody, C., Rodgers, A., Boehm, C., Afanasiev, M., Krischer, L., Chiang, A., and Simmons, N.: Using K-Means Clustering to Compare Adjoint Waveform Tomography Models of California and Nevada, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3257, https://doi.org/10.5194/egusphere-egu22-3257, 2022.

EGU22-3507 | Presentations | SM5.6

Seismotomographic structure of the central zone of Kamchatka suprasubduction complex according to the dense seismological networks data 

Natalia Bushenkova, Olga Bergal-Kuvikas, Evgeny I. Gordeev, Danila Chebrov, Ivan Koulakov, Ilyas Abkadyrov, Andrey Jakovlev, Tatiana Stupina, Angelika Novgorodova, and Svetlana Droznina

The strongest earthquakes and the largest explosive eruptions are confined to plate convergent boundaries. Many geodynamics aspects attract the scientific community's attention since answers to the most important questions cannot be obtained without reliable information about the deep structure. Geophysical studies of the crust and mantle provide essential information for lithospheric blocks interactions, mantle convection and fluid migration. This data is necessary to identify reliable criteria for assessing volcanic and seismic risk.

The studied area is central Kamchatka, where the cities of Petropavlovsk-Kamchatsky, Elizovo, and Vilyuchinks are located. It includes territory from the Gorely and Mutnovsky volcanoes in the south to the Bakening volcano and the Verkhneavachinskaya caldera in the north. It extends from the eastern to the western peninsula coasts. The study area includes the Avachinskaya group of volcanoes, the Vilyuchinsky and Zhupanovsky volcanoes, Karymshina caldera and a number of monogenic cinder cones. This region is assumed to be located at a transition between two principle different subduction regimes in the north and south of Kamchatka. Previous studies are sparse and have poor resolution due to the low density and uneven distribution of seismic stations.

In this study, we used a large dataset recorded by a new dense temporary network deployed in 2019-2020, which was specially designed for performing high-quality seismic tomographic studies of the suprasubduction complex structure (crust and upper mantle) beneath central Kamchatka. This dataset was supplemented by data recorded by (1) the temporary network operated on the Avachinskaya group of volcanoes in 2018-2019 and (2) the permanent stations Kamchatka branch of the Federal Research Center of the GS RAS. The seismic model is based on the data from 2687 local earthquakes that occurred during the operation of the mentioned temporary networks and were recorded by 134 regional stationary and temporary stations. In the tomographic inversion we used 59088 travel times of P-waves and 34697 of S-waves.

The new model makes it possible to trace zones of fluid and melt release from the slab, their migration in the mantle wedge and crust, and allows assessing their role in feeding the magmatic systems. Volcanoes of the Avachinskaya group have a common magma plumbing system at a depth more than 50 km, which could be traced from the slab. The Vilyuchinsky volcano feds through an intermediate large magma chamber located at a depth of 30-55 km, which is also related to the feeding of the Bolshebannaya hydrothermal system situated to the west. This large chamber fed from a conduit originated on the slab at more than 70 km depth. The feeding system of the Gorely and Mutnovsky volcanoes is traced to the slab at depths of more than 100 km.

This work was supported by the Russian Science Foundation (project No. 22-27-00215) and the Ministry of Education and Science of the Russian Federation (megagrant No. 14.W03.31.0033). 

How to cite: Bushenkova, N., Bergal-Kuvikas, O., Gordeev, E. I., Chebrov, D., Koulakov, I., Abkadyrov, I., Jakovlev, A., Stupina, T., Novgorodova, A., and Droznina, S.: Seismotomographic structure of the central zone of Kamchatka suprasubduction complex according to the dense seismological networks data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3507, https://doi.org/10.5194/egusphere-egu22-3507, 2022.

EGU22-3755 | Presentations | SM5.6

Receiver Function analysis of noise reduced OBS data recorded at the ultra-slow spreading Knipovich Ridge 

Theresa Rein, Zahra Zali, Frank Krüger, and Vera Schlindwein

Ultra-slow spreading ridges are characterized by huge volcanic complexes which are separated by up to 150 km long amagmatic segments. The mechanisms controlling the ultra-slow spreading ridges are not yet fully understood. With the aim to better understand the spreading mechanisms and the flow of the magma beneath the volcanic complexes an ocean-bottom array has been installed along a segment of the ultra-slow spreading Knipovich Ridge in the Greenland sea. The array consists of 23 LOBSTER-type ocean bottom seismometers (OBS) from the DEPAS pool and 5 LOBSTERs from the Institute of Geophysics of the Polish Academy of Sciences. We aim to constrain the crustal and mantle structure beneath the segment of the Knipovich Ridge by using receiver functions calculated from teleseismic events.

Seismic data, recorded on the ocean bottom, are highly contaminated by different noise sources, which are dominating at frequencies below 1 Hz. During the experiment the DEPAS-LOBSTERs were equipped with a MCS recorder and a Güralp CMG-40T seismometer (changed now to 6D6 recorder and Trillium Compact seismometer). This characteristic design introduces electronic noise at selected stations at frequencies below 0.2 Hz. Recently head-buoy-strumming has been identified as additional noise source at frequencies above 0.5 Hz during tidal currents. Hence, most teleseismic signals are masked by the high noise level, especially on the horizontal components. However, a good signal to noise ratio on both, the vertical and horizontal components is crucial for seismological analysis, especially the receiver function method. Applying the HPS noise reduction algorithm on OBS data, as shown by Zali et al (submitted in 2021), allows to separate percussive or transient signals, such as the teleseismic earthquake from more harmonic and monochromatic signals, such as most of the noise generated at the ocean bottom.

The results of the HPS noise reduction algorithm processing of selected KNIPAS station data show a significantly reduced noise level below 1 Hz on all seismogram components, especially on the horizontals. Here, the signal-to-noise ratio increased by up to 3.2-3.7 (average by 1.4-1.6). The increased signal-to-noise ratio on the noise reduced data allows for more reliable receiver function results and their interpretation. Here, we show the reduced noise level on the OBS data and compare the receiver function results calculated from original data with the results from noise-reduced data.

How to cite: Rein, T., Zali, Z., Krüger, F., and Schlindwein, V.: Receiver Function analysis of noise reduced OBS data recorded at the ultra-slow spreading Knipovich Ridge, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3755, https://doi.org/10.5194/egusphere-egu22-3755, 2022.

EGU22-3850 | Presentations | SM5.6

Joint Geophysical and Petrological Inversion to Image the Lithosphere and Asthenosphere Beneath Ireland and Britain 

Emma Chambers, Raffaele Bonadio, Sergei Lebedev, Javier Fullea, Duygu Kiyan, Christopher Bean, Brian O'Reilly, Patrick Meere, Meysam Rezaeifar, Gaurav Tomar, and Tao Ye and the DIG Team

DIG (De-risking Ireland’s Geothermal Potential) integrates inter-disciplinary and multi-scale datasets in order to investigate Ireland’s low-enthalpy geothermal energy potential. Recent deployments of broadband seismic stations and the output surface-wave measurements yield dense data sampling of the crust and mantle beneath Ireland and neighbouring Great Britain, which can be used to determine the lithospheric and asthenospheric structure at a regional scale. In addition, we integrate magnetotelluric measurements, forming the foundations for a region-scale, multi-parameter modelling of the thermal and compositional structure of the lithosphere.

In this study, we utilise the large seismic dataset and extract Rayleigh and Love-wave phase velocity dispersion curves, measured for pairs of stations across Ireland and Great Britain. The measurements were performed using two methods with complementary period ranges; the teleseismic cross-correlation method and the waveform inversion method, yielding a 4-500 s period range for the dispersion curves. The joint analysis of Rayleigh and Love measurements constrains the isotropic-average shear-wave velocity, relatable to temperature and composition, providing essential constraints on the thermal structure of the region’s lithosphere. We demonstrate this by inverting the data using an integrated joint geophysical-petrological thermodynamically self-consistent approach (Fullea et al., GJI 2021), where seismic velocities, electrical conductivity, and density are dependent on mineralogy, temperature, composition, water content, and the presence of melt. The multi-parameter models produced by the integrated inversions fit the surface-wave and other data, revealing the temperatures and geothermal gradients within the crust and mantle, which will be used for future geothermal exploration and utilisation.

The project is funded by the Sustainable Energy Authority of Ireland under the SEAI Research, Development & Demonstration Funding Programme 2019 (grant number 19/RDD/522) and by the Geological Survey of Ireland.

How to cite: Chambers, E., Bonadio, R., Lebedev, S., Fullea, J., Kiyan, D., Bean, C., O'Reilly, B., Meere, P., Rezaeifar, M., Tomar, G., and Ye, T. and the DIG Team: Joint Geophysical and Petrological Inversion to Image the Lithosphere and Asthenosphere Beneath Ireland and Britain, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3850, https://doi.org/10.5194/egusphere-egu22-3850, 2022.

EGU22-4037 | Presentations | SM5.6

Ray theoretical investigations using matching pursuits 

Volker Michel, Naomi Schneider, Karin Sigloch, and Eoghan Totten

The three-dimensional structure of the Earth's interior shapes its geomagnetic and gravity fields, and can thus be constrained by observing these fields. 3-D Earth structure also causes seismological observables to deviate from those predicted for approximated, spherically symmetrical reference models. Travel time tomography is the inverse problem that uses these observed differences to constrain the 3-D structure of the interior.
On the planetary scale, i.e. in a spherical geometry, this linearized inverse problem has been parameterized with a variety of basis systems, either global (e.g. spherical harmonics) or local (e.g. finite elements). The Geomathematics Group Siegen has developed alternative approximation methods for certain applications from the geosciences: the Inverse Problem Matching Pursuits (IPMPs). These methods combine different basis systems by calculating an approximation in a so-called best basis, which is chosen iteratively from a so-called dictionary, an intentionally overcomplete set of diverse trial functions. In each iteration, the choice of the next best basis element reduces the Tikhonov functional. A particular numerical expertise has been gained for applications on spheres or balls. Hence, the methods were successfully applied to, for instance, the downward continuation of the gravitational potential as well as the MEG-/EEG-problem from medical imaging.
Our aim is to remodel the IPMPs for travel time tomography. This includes developing the data-dependent operator, deciding for specific trial functions and applying the operator to them. We also have to define termination criteria and develop the regularization in theory and practice. We introduce the IPMPs and show results from our remodelling.

How to cite: Michel, V., Schneider, N., Sigloch, K., and Totten, E.: Ray theoretical investigations using matching pursuits, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4037, https://doi.org/10.5194/egusphere-egu22-4037, 2022.

EGU22-4477 | Presentations | SM5.6

Optimal resolution tomography with error tracking and the structure of the crust and upper mantle beneath Ireland and Britain 

Raffaele Bonadio, Sergei Lebedev, Thomas Meier, Pierre Arroucau, Andrew J. Schaeffer, Andrea Licciardi, Matthew R. Agius, Clare Horan, Louise Collins, Brian M. O'Really, Peter W. Readman, and Ireland Array Working Group

The maximum achievable resolution of a tomographic model varies spatially and depends on the data sampling and errors in the data. The significant and continual measurement-error decreases in seismology and data-redundancy increases have reduced the impact of random errors on tomographic models. Systematic errors, however, are resistant to data redundancy and their effect on the model is difficult to predict; often this results in models dominated by noise if the target resolution is too high. Here, we develop a method for finding the optimal resolving length at every point, implementing it for surface-wave tomography. As in the Backus-Gilbert method, every solution at a point results from an entire-system inversion, and the model error is reduced by increasing the model-parameter averaging. The key advantage of our method consists in its direct, empirical evaluation of the posterior model error at a point.

We first measure interstation phase velocities at simultaneously recording station pairs and compute phase-velocity maps at densely, logarithmically spaced periods. Numerous versions of the maps with varying smoothness are then computed, ranging from very rough to very smooth. Phase-velocity curves extracted from the maps at every point can be inverted for shear-velocity (VS) profiles. As we show, errors in these phase-velocity curves increase nearly monotonically with the map roughness. We evaluate the error by isolating the roughness of the phase-velocity curve that cannot be explained by any Earth structure and determine the optimal resolving length at a point such that the error of the local phase-velocity curve is below a threshold.

A 3-D VS model is then computed by the inversion of the composite phase-velocity maps with an optimal resolution at every point. Importantly, the optimal resolving length does not scale with the density of the data coverage: some of the best-sampled locations display relatively low lateral resolution, due to systematic errors in the data.

We apply this method to image the lithosphere and underlying mantle beneath Ireland and Britain. Our very large data produces a total of 11238 inter-station dispersion curves, spanning a very broad total period range (4–500 s), yielding unprecedented data coverage of the area and providing state-of-the-art regional resolution from the crust to the deep asthenosphere. Our tomography reveals pronounced, previously unknown variations in the lithospheric thickness beneath Ireland and Britain, with implications for their Caledonian assembly and for the mechanisms of the British Tertiary Igneous Province magmatism.

How to cite: Bonadio, R., Lebedev, S., Meier, T., Arroucau, P., Schaeffer, A. J., Licciardi, A., Agius, M. R., Horan, C., Collins, L., O'Really, B. M., Readman, P. W., and Working Group, I. A.: Optimal resolution tomography with error tracking and the structure of the crust and upper mantle beneath Ireland and Britain, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4477, https://doi.org/10.5194/egusphere-egu22-4477, 2022.

EGU22-4784 | Presentations | SM5.6

Seismic and multi-parameter 1D reference models of the upper mantle 

Chiara Civiero, Sergei Lebedev, Yihe Xu, Raffaele Bonadio, and Javier Fullea

1D reference Earth models are widely used by the geoscience community and include global, regional and tectonic-type reference models. Seismic 1D profiles are used routinely as reference in imaging studies. Multi-parameter models can also include density, composition, attenuation, lithospheric thickness and other parameters, of interest in a broad range of studies. The recent growth in the number of seismic stations worldwide has yielded a dramatic increase in the global sampling of the Earth with seismic data and presents an opportunity for an improvement in the global and tectonic-type reference models. Concurrent developments in computational petrology have provided methods to constrain self-consistent multi-parameter Earth models with seismic and other data. Here, we use a large global dataset of Love and Rayleigh fundamental mode, phase-velocity measurements, performed with multimode waveform inversion using all available broadband data since the 1990s, and compute phase-velocity maps at densely spaced periods in a broad, 17-310 s period range. We then invert the phase velocity curves averaged globally and across 8 tectonic environments (4 continental: Archean cratons, stable platforms, recently active continents, and active rift zones; and 4 oceanic: old, intermediate and young oceans, and backarc regions) for 1D reference models of the upper mantle. For each tectonic type, a multi-parameter 1D model is computed in a petrological inversion, where the lithospheric thickness and temperature at the bottom of the lithosphere and in the underlying mantle are the inversion parameters, and steady-state conductive lithospheric geotherms are assumed. Lithospheric and asthenospheric compositions are taken from geochemical databases, and seismic velocities, densities and Q are computed from composition, temperature and pressure using computational petrology and thermodynamic databases. The models quantify the age dependence of the lithospheric thickness and temperature in continents and oceans. Radial anisotropy is also determined and shows notable variations with depth and with tectonic environments. For most tectonic types, the smooth, accurate observed phase velocity curves can be fit by the 1D models with a misfit under 0.1-0.2% of the phase velocity value. Additionally, we compute models with minimal complexity of seismic velocity structure, also fitting the data but without a sub-lithospheric low-velocity zone as in the thermal multi-parameter models. These purely seismic models, similar in appearance to ak135, do not correspond to realistic geotherms but provide useful reference for seismic imaging studies in different environments.

How to cite: Civiero, C., Lebedev, S., Xu, Y., Bonadio, R., and Fullea, J.: Seismic and multi-parameter 1D reference models of the upper mantle, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4784, https://doi.org/10.5194/egusphere-egu22-4784, 2022.

EGU22-4870 | Presentations | SM5.6

Shear-velocity structure and dynamics beneath the Central Mediterranean inferred from seismic surface waves 

Matthew Agius, Fabrizio Magrini, Giovanni Diaferia, Emanuel Kastle, Fabio Cammarano, Claudio Faccenna, Francesca Funiciello, and Mark van der Meijde

The evolution of the Sicily Channel Rift Zone (SCRZ), located south of the Central Mediterranean, is thought to accommodate the regional tectonic stresses of the Calabrian subduction system. It is unclear whether the rifting of the SCRZ is passive from far-field extensional stresses or active from mantle upwelling beneath. To map the structure and dynamics of the region, we measure Rayleigh- and Love-wave phase velocities from ambient seismic noise and invert for an isotropic 3-D shear-velocity and radial anisotropic model. Variations of crustal S-velocities coincide with topographic and tectonic features: slow under high elevation, fast beneath deep sea. The Tyrrhenian Sea has a <10 km thin crust, followed by the SCRZ (∼20 km). The thickest crust is beneath the Apennine-Maghrebian mountains (∼50 km). Areas experiencing extension and intraplate volcanism have positive crustal radial anisotropy (VSH>VSV); areas experiencing compression and subduction-related volcanism have negative anisotropy (VSH<VSV). The crustal anisotropy across the Channel shows the extent of the SW-NE extension. Beneath the Tyrrhenian Sea, we find very low sub-Moho S-velocities. In contrast, the SCRZ has a thin mantle lithosphere underlain by a low-velocity zone. The lithosphere-asthenosphere boundary rises from 40-60 km depth beneath Sicily and Tunisia to ∼33 km beneath the SCRZ. Upper mantle, negative radial anisotropy beneath the SCRZ suggests vertical mantle flow. We hypothesize a more active mantle upwelling beneath the rift than previously thought from an interplay between poloidal and toroidal fluxes related to the Calabrian slab, which in turn produces uplift at the surface and induces volcanism.

This project has received funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Skłodowska-Curie grant agreement No 843696.

How to cite: Agius, M., Magrini, F., Diaferia, G., Kastle, E., Cammarano, F., Faccenna, C., Funiciello, F., and van der Meijde, M.: Shear-velocity structure and dynamics beneath the Central Mediterranean inferred from seismic surface waves, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4870, https://doi.org/10.5194/egusphere-egu22-4870, 2022.

EGU22-5885 | Presentations | SM5.6

Seismic Attenuation of India, Himalaya and Tibet using Lg-coda waves 

Dibyajyoti Chaudhuri, Ayon Ghosh, Shubham Sharma, and Supriyo Mitra

We present maps to show the lateral variation of Lg coda attenuation at 1-Hz across India, Himalaya and Tibet. We use vertical component waveforms from regional earthquakes (epicentral distance<3500 km and Mw>5) recorded by the IISER-K seismological network, ones operated by the Indian Meteorological Department, and data acquired from the IRIS-DMC. Lg-coda waves are modeled as single back-scattered energy, sampling an ellipsoidal volume. The attenuation of Lg-coda is quantified using the quality factor (Q), which is frequency dependent. We use the stacked spectral ratio (SSR) method to calculate the single-trace Lg-coda Q at 1 Hz (Qo) and its frequency dependence (η). A moving-window stack of scaled-logarithmic ratios of spectral amplitudes, for window length of 25.6 s and different central lapse time, is computed for each frequency. Through a linear regression of log (stacked spectral ratio) and log (frequency), using least-squares fitting, we obtain (1-η) and log(Qo), respectively. Lg-coda is selected in a frequency range of 0.2-5 Hz, with coda window starting at 3.15 km/s. Our total coda window lengths vary between 140 s to 780 s. Our preliminary results show low Q values (~200-400) in the Eastern and Western Himalaya - possibly because of scattering of seismic energy from structural heterogeneities. Most of the Indian Shield and the intraplate regions of Shillong Plateau and Brahmaputra valley are characterized by intermediate to high Q values (~600-800), indicating fairly efficient propagation of seismic energy. Intermediate values of Q (~400-500) occur in the Indo-Burman Ranges which may be due to the cold elastic subducting oceanic lithosphere. Patches of low Q in the Tibetan Plateau (~200) are possibly the result of high temperatures and partial melts present in the crust. Our results show how the nature of the Indian Plate changes as we go from an active continent-continent collision zone in the north to eastward subduction of transitional material at the Indo-Burma ranges. Our plots of Qo and η as a function of epicentral distance, coda length and magnitude show no systematic variations.



How to cite: Chaudhuri, D., Ghosh, A., Sharma, S., and Mitra, S.: Seismic Attenuation of India, Himalaya and Tibet using Lg-coda waves, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5885, https://doi.org/10.5194/egusphere-egu22-5885, 2022.

EGU22-6235 | Presentations | SM5.6

Exploring the Earth's mantle structure based on joint gravimetric and seismometric group-velocity dispersion curves of Rayleigh waves 

Kamila Karkowska, Monika Wilde-Piórko, Przemysław Dykowski, Marcin Sękowski, and Marcin Polkowski

Gravimetric data show excellent capabilities in long-period seismology. Tidal gravimeters can detect surface waves of periods even up to 500-600 s, while a typical broad-band seismic sensor, due to its mechanical limitation, can detect them only up to the periods of 200-300 s. Consequently, gravimetric data can complement seismic recordings for longer periods, depending on what seismometer the station is equipped with and what seismometer’s cut-off period is. A superconducting gravimeter can act as a single-dimension (only vertical component) of a very broad-band seismometer. 

We selected over a dozen stations worldwide with co-located typical broad-band seismic sensors and superconducting gravimeters. A time series from broad-band seismometers have been downloaded from Incorporated Research Institutions for Seismology (IRIS) database. The raw gravimetric data (1-Hz or 1-min) are available in the International Geodynamics and Earth Tide Service (IGETS) database. Some of the data were made available courtesy of the station’s operators. 

This study presents a joint analysis of the gravimetric and seismometric data to determine group-velocity dispersion curves of Rayleigh surface waves. We created a database of recordings of earthquakes for all stations and instruments. Following, we calculated the individual group-velocity dispersion curves of fundamental-mode Rayleigh waves. Simultaneous seismic and gravity recordings at the same location allow exploring a broader response for incoming seismic waves. In this way, one joint group-velocity dispersion curve of Rayleigh surface waves for a broader range of periods has been estimated for all stations. All curves were then inverted by linear inversion and Monte Carlo methods to calculate a distribution of shear-wave seismic velocity with depth in the Earth’s mantle.    

This work was done within the research project No. 2017/27/B/ST10/01600 financed from the Polish National Science Centre funds.

How to cite: Karkowska, K., Wilde-Piórko, M., Dykowski, P., Sękowski, M., and Polkowski, M.: Exploring the Earth's mantle structure based on joint gravimetric and seismometric group-velocity dispersion curves of Rayleigh waves, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6235, https://doi.org/10.5194/egusphere-egu22-6235, 2022.

EGU22-6399 | Presentations | SM5.6

Hamiltonian Monte Carlo Inversion of Surface Wave Dispersion to Evaluate their Potential to Constrain the Density Distribution in the Earth. 

Ariane Lanteri, Lars Gebraad, Andrea Zunino, and Andreas Fichtner

We present a probabilistic approach to constrain the density distribution in the Earth based on surface wave dispersion. Despite its outstanding importance in studies of the Earth’s thermo-chemical state and dynamics, 3D density variations remain poorly known, thereby posing one of the major challenges in geophysics.

Since the sensitivity of most seismic data to density is small compared to sensitivity with respect to seismic velocities, regularisation in traditional deterministic inversion tends to bias the recovered density image significantly. To avoid this issue, we propose to solve a regularisation-free Bayesian inference problem using the Hamiltonian Monte Carlo Markov Chain algorithm.

In the interest of simplicity, we consider anisotropic stratified media, where dispersion curves and corresponding sensitivity kernels can be computed semi-analytically. Exploiting derivative information for efficient sampling, Hamiltonian Monte Carlo approximates the posterior probability density of all model parameters, namely the P-wave velocities vPV and vPH , the S-wave velocities vSV and vSH , the anisotropy parameter η, and, of course, density ρ.

The proposed method forms the foundation of an open-source tool box that can be used to assess the unbiased ability of surface wave dispersion data, characterised in terms of frequency and modal content, to constrain density variations and their trade-offs with other Earth model parameters.

How to cite: Lanteri, A., Gebraad, L., Zunino, A., and Fichtner, A.: Hamiltonian Monte Carlo Inversion of Surface Wave Dispersion to Evaluate their Potential to Constrain the Density Distribution in the Earth., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6399, https://doi.org/10.5194/egusphere-egu22-6399, 2022.

EGU22-6428 | Presentations | SM5.6

Interrogating the volume of the East Irish Sea sedimentary basins using probabilistic tomographic results 

Xuebin Zhao, Andrew Curtis, and Xin Zhang
The ultimate goal of a scientific investigation is usually to find answers to specific questions: what is the size of a subsurface body? Does a hypothesised subsurface feature exist? Which competing model is most consistent with observations? The answers to these and many other questions are low-dimensional, yet must often be inferred from high-dimensional models and data. To address the questions, existing information is reviewed, an experiment is designed and performed to acquire new data, and the most likely answer is estimated. Typically the answer is interpreted from geological and geophysical data or models, but is biased because only one particular forward function (model-data relationship) is considered, one inversion method is applied, and because human interpretation is a biased process. Interrogation theory provides a systematic way to answer specific questions using statistically unbiased estimators. It combines forward, design, inverse and decision theory, and focuses them to maximise information on the space of possible answers.

This study estimates the volume of the East Irish Sea sedimentary basins in the UK using 3D shear wave speed models derived from surface wave dispersion inversions. In order to answer volume-related questions, it is first necessary to define a target function that translates any (high-dimensional) model into (1-dimensional) volumes of interest. A key revelation of this study is that while the majority of computation may be spent solving inverse problems probabilistically, much of the skill and human effort involved in answering real-world questions may be spent defining and calculating those target function values in a clear and unbiased manner.

How to cite: Zhao, X., Curtis, A., and Zhang, X.: Interrogating the volume of the East Irish Sea sedimentary basins using probabilistic tomographic results, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6428, https://doi.org/10.5194/egusphere-egu22-6428, 2022.

EGU22-6780 | Presentations | SM5.6

An unusually long eclogitic lower crustal body imaged by the Korean nuclear explosion 

Xiaoqing Zhang, Hans Thybo, Irina M. Artemieva, Tao Xu, and Zhiming Bai

The Sino-Korean Craton (SKC), which consists of the North China Craton (NCC) in China and North Korea, is one of the oldest cratons on earth. Since the Paleozoic, the SKC has experienced multiple subductions of the peripheral plates and the northeastern SKC is located in a junction area. Its characteristics are being investigated by geophysical and geochemical methods, which provides insights into the formation and subsequent evolution of the continental lithosphere.

We interpret the crustal structure of the northeastern SKC with the refraction/wide-angle reflection perspective using North Korean Nuclear Explosion sources recorded by 40 permanent and 7 temporary broadband stations, which were operated by the China Earthquake Administration and the Institute of Geology and Geophysics, Chinese Academy of Science, respectively.

Primary reflection phases from a discontinuity at 30km depth have an apparent velocity of about 6.2 km/s. This phase is observed to 1200km ultra-long offset, which shows that the average crustal velocity is extremely low. Another spectacular observation is of extremely strong phases which we interpret as Moho to surface multiples of all main phases in the seismic sections. Clear upper mantle refractions (Pn) are observed with an apparent velocity around 8.05 km/s as first arrivals over the offset range 300-1000 km. All observations show that the crust of northeastern SKC is very thin (about 30km), it has a low average crust velocity (6.2km/s), and the velocity contrast at the Moho discontinuity is extraordinarily strong.

We detect the “Seismic Moho” discontinuity, which is marked by a very strong and sharp increase in velocity. We interpret this “Seismic Moho” as the top of a layer consisting of the lower crust in eclogite facies. This “Seismic Moho” does not coincide with the true Crust-Mantle Boundary, which is defined by a change from felsic/intermediate/mafic crustal rocks to the dominantly ultramafic rocks of the upper mantle in petrological terms.

How to cite: Zhang, X., Thybo, H., Artemieva, I. M., Xu, T., and Bai, Z.: An unusually long eclogitic lower crustal body imaged by the Korean nuclear explosion, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6780, https://doi.org/10.5194/egusphere-egu22-6780, 2022.

We present the theory and applications of the Distributional Finite Difference Method (DFD). The DFD method is an efficient tool for modeling the propagation of elastic waves in heterogeneous media in the time domain. It decomposes the modeling domain into multiple elements that can have arbitrary sizes. When using large elements, the DFD algorithm resembles the finite difference method because the wavefield is updated using operations involving band diagonal matrices only. This makes the DFD method computationally efficient. When small elements are employed, the DFD method permits to mesh complicated structures as in the finite element or the spectral element methods. We present numerical examples showing that the proposed algorithm accurately accounts for free surfaces, solid-fluid interfaces and accommodates non-conformal meshes. Seismograms obtained using the proposed method are compared to those computed using analytical solutions and the spectral element method. The DFD method requires fewer points per wavelength (down to 3) than the spectral element method (5 points per wavelength) to achieve comparable accuracy. We present examples demonstrating the advantages of the DFD method for modeling wave propagation in the Earth at the global and regional scales. 

How to cite: masson, Y.: Modeling seismic wave propagation in the earth using the distributional finite difference method, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6893, https://doi.org/10.5194/egusphere-egu22-6893, 2022.

EGU22-7544 | Presentations | SM5.6

Global gravity gradient inversion reveals variability of cratonic crust 

Peter Haas, Jörg Ebbing, and Wolfgang Szwillus

In this contribution, we present a global estimate of crustal thickness with emphasis to cratons. In an inverse scheme, satellite gravity gradient data are inverted for the Moho depth, exploiting laterally variable density contrasts based on seismic tomography. Our results are constrained by an active source seismic data base, as well as a tectonic regionalization map, derived from seismic tomography. For the global analysis, we implement a moving window approach to perform the gravity inversion, followed by interpolating the estimated density contrasts of common tectonic units with a flood-fill algorithm.

The estimated Moho depth and density contrasts are especially interesting for the cratons of the Earth. Our results reveal a surprising variability of patterns with average Moho depth between 32-42 km, reflecting an individual tectonic history of each craton. Statistical patterns of Moho depth and density contrasts are discussed for the individual cratons and linked to their stabilization age. For example, Australia shows the lowest average Moho depth (32.7 km), indicating early stabilization in the Archean and removal of a dense lower protocrust. This observation matches well with receiver function studies. The globally inverted Moho depth is validated by gridded seismic Moho depth information, which shows that for many cratons the inverted Moho depth is within expected uncertainties of the seismic Moho depth. In addition, the formerly connected cratons of South America and Africa are analyzed and discussed in a Gondwana reconstruction. Here, the once-connected West African and Amazonian Cratons have a shallow Moho depth, indicating that only little tectonic activity occurred during the Phanerozoic. The tectonically-linked Congo and Sao Francisco Cratons have intermediate Moho depths, with the Congo Craton having a slightly shallower Moho depth. This could reflect dynamic support of the upper mantle on the African side.

How to cite: Haas, P., Ebbing, J., and Szwillus, W.: Global gravity gradient inversion reveals variability of cratonic crust, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7544, https://doi.org/10.5194/egusphere-egu22-7544, 2022.

EGU22-7668 | Presentations | SM5.6

Ambient noise tomography of post-subduction setting in northern Borneo enhanced with machine learning 

Joseph Fone, Simone Pilia, Nicholas Rawlinson, and Song Hou

Given that subduction is an important driver of plate tectonics on Earth, it is notable that the effects of subduction termination are often complex and poorly understood. Northern Borneo is a prime example of a post-subduction environment, where two subduction zones have terminated within the last 20 Ma. The region however has seen very few seismic studies likely due to the low levels of seismicity in the region compared to the rest of Southeast Asia and due to the challenging deployment environment. The goal of the northern Borneo Orogeny Seismic Survey (nBOSS) network, which operated between 2018 and 2020 and consisted of 47 broadband instruments, was to provide constraints and answer first order questions about the structure of the lithosphere and asthenosphere in this post-subduction setting. Waveform data from this network were supplemented with data recorded by 33 permanent instruments operated by the Malaysian meteorological authority, METMalaysia. In this study we produce the first model of the crustal shear wave velocity structure under northern Borneo using surface wave ambient noise tomography to try and better understand the effects of subduction termination on the crust and to better understand the present day structure of the crust in this region which has not been imaged in this way before. We use a trans-dimensional tomography to produce variable resolution 2D Rayleigh wave phase velocity maps in the period range 2-30 seconds sampled every 2 seconds. Then to produce the final 3D shear wave velocity model a series of 1D inversions were used in combination with a neural network that is trained to find a generalised solution to the 1D inverse problem for this data set. This helps to prevent artefacts forming in the final model as a result of there being no lateral correlations in the 1D inversions by providing the more region specific trained neural network to perform the bulk of the 1D inversions. The result is a model that shows a detailed 3D shear wave velocity structure of the crust that matches expected velocity anomalies from known geological features. This includes the large sedimentary basins in the region, which are revealed as large slow velocity anomalies. Our new model agrees with results from other methods used to study this region, including receiver functions and surface wave tomography.

How to cite: Fone, J., Pilia, S., Rawlinson, N., and Hou, S.: Ambient noise tomography of post-subduction setting in northern Borneo enhanced with machine learning, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7668, https://doi.org/10.5194/egusphere-egu22-7668, 2022.

EGU22-7767 | Presentations | SM5.6

A consistent full waveform inversion scheme for imaging heterogeneous isotropic elastic media 

Li-Yu Kan, Sébastien Chevrot, and Vadim Monteiller

Multi-parameter teleseismic full-waveform inversion (FWI) can provide key insights on the composition and thermal state of the lithosphere. In the isotropic version of such inversions, one classically inverts for a set of independent model parameters,  for example (density, Vp, Vs). In this study, we demonstrate that by introducing model covariance matrices with non-diagonal terms to FWI, i.e. accounting for the existing correlations between density, Vp, and Vs, has a dramatic impact on the quality of the reconstructed models. We perform synthetic tests using with a simple subduction model. The teleseismic and regional wavefields are computed with our FK-SEM hybrid method. We invert vertical and radial component P waveforms from four teleseismic events coming from different epicentral distances and azimuths. We use a hierarchical iterative l-BFGS inversion, starting at long period (T > 10 s) to obtain a long wavelength model, and then progressively decreasing the spatial smoothing and cut-off period to 5 s and then 2.5 s. We also demonstrate that a complete non-diagonal model covariance matrix allows us to make the inversion results consistent, i.e. independent of the model parameterization. The inversions which account for the correlations between model parameters provide better models especially for density and Vs, less numerical artifacts, and are characterized by a faster convergence rate compared to inversions performed by assuming that model parameters are independent.

How to cite: Kan, L.-Y., Chevrot, S., and Monteiller, V.: A consistent full waveform inversion scheme for imaging heterogeneous isotropic elastic media, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7767, https://doi.org/10.5194/egusphere-egu22-7767, 2022.

EGU22-8121 | Presentations | SM5.6

Subduction history of the Caribbean from upper-mantle seismic imaging and plate reconstruction 

Benedikt Braszus, Saskia Goes, Rob Allen, Andreas Rietbrock, and Jenny Collier and the VoiLA Team

Even though the Caribbean region is constantly struck by the impact of geological hazards, the details of the Caribbean plate's evolution are still not completely understood. This interdisciplinary study combines and jointly interprets seismic tomography data with trench positions derived from plate reconstruction which constrains some of the most important events governing the evolution of the Caribbean plate. 
Our new teleseismic P-wave tomography model of the upper mantle beneath the Caribbean includes manually processed and analysed data from 32 ocean-bottom seismometers installed for 16 months during the VoiLA experiment as well as recordings from 192 permanent and temporary land stations. Reconstruction tests show improved resolution compared to previous models and a sufficient recovery of a synthetic anomaly assimilating the Caribbean slab. 
Based on reconstructed trench positions we attribute slab fragments residing in depths of 700-1200km to 90–115 Myr old westward subduction along the Great Arc of the Caribbean (GAC) prior to Caribbean Large Igneous Province volcanism, rather than to eastward dipping Farallon subduction. 
In the mantle transition zone, the imaged slab coincides with predicted trench positions from 50-70 Ma with a slab window approximately at the location of the subducted Proto-Caribbean spreading ridge.
Along the otherwise continous slab in the shallow upper mantle from Hispanola to Grenada several tears are interpreted as ruptures along fault zones in the Proto-Caribbean crust as well as the subducted extinct Proto-Caribbean spreading ridge. 

How to cite: Braszus, B., Goes, S., Allen, R., Rietbrock, A., and Collier, J. and the VoiLA Team: Subduction history of the Caribbean from upper-mantle seismic imaging and plate reconstruction, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8121, https://doi.org/10.5194/egusphere-egu22-8121, 2022.

EGU22-8319 | Presentations | SM5.6

3D Variational Full-Waveform Inversion 

Xin Zhang, Muhong Zhou, Angus Lomas, York Zheng, and Andrew Curtis

Seismic full-waveform inversion (FWI) produces high resolution images of the subsurface by exploiting information in full seismic waveforms, and has been applied at global, regional and industrial spatial scales. FWI is traditionally solved by using optimization, in which one seeks a best model by minimizing the misfit between observed waveforms and model predicted waveforms. Due to the nonlinearity of the physical relationship between model parameters and waveforms, a good starting model is often required to produce a reasonable model. In addition, the optimization methods cannot produce accurate uncertainty estimates, which are required to better interpret the results.

To estimate uncertainties more accurately, nonlinear Bayesian methods have been deployed to solve the FWI problem. Monte Carlo sampling is one such algorithm but it is computationally expensive, and all Markov chain Monte Carlo-based methods are difficult to parallelise fully. Variational inference provides an efficient, fully parallelisable alternative methodology. This is a class of methods that optimize an approximation to a probability distribution describing post-inversion parameter uncertainties. Both Monte Carlo and variational full waveform inversion (VFWI) have been applied previously to solve 2D FWI problems, but neither of them have been applied to 3D FWI. In this study we apply the VFWI method to a 3D FWI problem. Specifically we use Stein variational gradient descent (SVGD) method to solve the 3D Bayesian FWI problem and to obtain an optimised set of samples of the full posterior probability distribution. The aim of this study is to explore performance of the method in 3D, to assess the computational requirements and to provide useful information for practitioners. Our results demonstrate that the 3D VFWI is practical, at least for small problems, and can be applied to image the subsurface in reality.

How to cite: Zhang, X., Zhou, M., Lomas, A., Zheng, Y., and Curtis, A.: 3D Variational Full-Waveform Inversion, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8319, https://doi.org/10.5194/egusphere-egu22-8319, 2022.

EGU22-9636 | Presentations | SM5.6

Machine learning-based attenuation of steeply dipping events of seismic reflection image beneath the Korean Peninsula 

Youngseok Song, Joongmoo Byun, Sooyoon Kim, Yonggyu Choi, and Sungmyung Bae

Seismic reflection images derived by ambient-noise seismic interferometry (SI) can show subsurface structures without active sources. To image and interpret the upper mantle structures and tectonic boundaries beneath the southern part of Korean Peninsula, we applied SI method to seismic ambient noise data recorded at 119 seismic stations on the Korean Peninsula in 2014 (from the seismic network of the Korean Meteorological Administration). The factor that makes interpretation difficult is the steeply dipping events in reflection images. Most of these events of apparent steeply dips show as true reflection events from steep geologic boundaries. Therefore, we need to attenuate these events to interpret true reflection events. These events overlap many times. Also, the value of the slope has several values close to half of the Rayleigh waves or P waves. To attenuate these events with these complex features, we used machine learning techniques. We attenuated our steeply dipping events by applying the Extraction of diffractions method. As the steeply dipping events are attenuated, horizontal events were strengthened, and noises were attenuated. We can more clearly identify the reflection events of the Moho discontinuity and the lithosphere/asthenosphere (LAB) boundary near the two-way reflection times of 7-11 s and 17-22 s respectively.

How to cite: Song, Y., Byun, J., Kim, S., Choi, Y., and Bae, S.: Machine learning-based attenuation of steeply dipping events of seismic reflection image beneath the Korean Peninsula, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9636, https://doi.org/10.5194/egusphere-egu22-9636, 2022.

EGU22-10232 | Presentations | SM5.6

A new Integrated lithological model of the Iberian crust 

Carlos Clemente-Gómez, Javier Fullea, and Mariano S. Arnaiz-Rodríguez

The Earth’s crust hosts most of the geo-resources of societal interests (e.g. minerals, geothermal energy etc.). Integrative approaches combining geophysical and petrological observations to study the mantle assuming thermodynamic equilibrium are relatively common nowadays. However, in contrast to the mantle, where thermodynamic equilibrium is prevalent, vast portions of the crust are thermodynamically metastable. This is because equilibration processes are essentially temperature activated and the temperature in the crust is usually too low to trigger them. Consequently, the mineralogical assemblage of crustal rocks is mostly decoupled from the in situ pressure and temperature conditions, reflecting instead the conditions present at the moment of rock formation. Here we present a new methodology for integrated geophysical-petrological multi-data modelling of the crust. Our primary constraining data are fundamental mode Rayleigh wave surface wave dispersion curves determined by interstation cross-correlation measurements and teleseisms, as well as surface elevation (isostasy) and heat flow. Additional prior information is provided by P-wave velocities coming from controlled source and body wave tomography data. The inversion is framed within an integrated geophysical-petrological setting where mantle seismic velocities and densities are computed thermodynamically as a function of the in situ temperature and compositional conditions. In this work we develop a new parameterization of the crust where we first invert following global statistical correlations between Vp, Vs and crustal densities for different lithologies in a two-layered model. In a second step we compute the rock physical properties for different metamorphic facies and water contents using computational petrology to derive a plausible and consistent lithological model. In order to optimize the inversion procedure, we perform a sensitivity  analysis assessing the resolution of the different data sets. The new methodology is applied to the Iberian Peninsula and adjacent margins where we jointly invert for both the crustal and lithospheric mantle structure.

How to cite: Clemente-Gómez, C., Fullea, J., and Arnaiz-Rodríguez, M. S.: A new Integrated lithological model of the Iberian crust, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10232, https://doi.org/10.5194/egusphere-egu22-10232, 2022.

EGU22-650 | Presentations | G4.3

Investigation of different geoid computation techniques in the frame of the ModernGravNet project 

Vassilios Grigoriadis, Vassilios Andritsanos, Dimitrios Natsiopoulos, and Georgios Vergos

In the frame of the “Modernization of the Hellenic Gravity Network” project, we aim at computing a high resolution and accuracy geoid for Greece. For this reason, we selected initially two test areas in northern and southern Greece covering an area of about 100 km2 each, where gravity and GNSS/leveling measurements were carried out. Based on these recent, well documented and reliable measurements, we investigate the use of different techniques for the determination of the geoid, including Least-Squares Collocation, FFT and Input-Output Systems, following the Remove-Compute-Restore approach. For the remove/restore part, we examine different Residual Terrain Modeling schemes along with the use of older and recent Global Geopotential Models. Moreover, we compute the geoid-quasigeoid separation term using different approaches. We then validate the results obtained against the new GNSS/leveling measurements across the test areas and draw conclusions towards the determination of a regional geoid for Greece.

How to cite: Grigoriadis, V., Andritsanos, V., Natsiopoulos, D., and Vergos, G.: Investigation of different geoid computation techniques in the frame of the ModernGravNet project, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-650, https://doi.org/10.5194/egusphere-egu22-650, 2022.

EGU22-711 | Presentations | G4.3

The deep structure of the Richat magmatic intrusion (northern Mauritania) from geophysical modelling. Insights into its kinematics of emplacement 

El Houssein Abdeina, Sara Bazin, Gilles Chazot, Hervé Bertrand, Bernard Le Gall, Nasrrddine Youbi, Mohamed Salem Sabar, Mohamed Khalil Bensalah, and Moulay Ahmed Boumehdi

The famous circular structure of Richat, sometimes referred to as “the eye of Africa”, is located in the northwestern part of the Taoudeni basin, in the central part of the Mauritanian Adrar plateaus. It is expressed at the surface as a slightly elliptical depression, about 40 kilometers in diameter, marked by concentric ridges of Proterozoic-Lower Paleozoic sediments. Its origin as resulting from either a meteorite impact or a deep magmatic intrusion, has been long debated. Modelling of high-resolution airborne magnetic data as well as satellite gravity data reinforces the intrusion hypothesis. Geophysical modelling has been calibrated by determinations of rock properties from various types of magmatic lithologies sampled in the field. The three complementary types of geophysical data allow us to image at various scales and depths the buried structures of the Richat magmatic complex, to determine the areas most affected by hydrothermal alteration and finally to elaborate a kinematic model for its emplacement. We emphasize that : (1) the Richat intrusion is characterized by the presence of two important circular magnetic signals that coincide with gabbroic ring dykes partly exposed at the surface, (2) its overall circular structure rests above a deep mafic (gabbroic) body, (3) the upwelling of magma at the surface has been facilitated by the presence of concentric faults and (4) the central zone of the complex recorded intense hydrothermal alteration. This case study aims to provide insights for similar types of magma-induced ring structures observed worldwide.

How to cite: Abdeina, E. H., Bazin, S., Chazot, G., Bertrand, H., Le Gall, B., Youbi, N., Sabar, M. S., Bensalah, M. K., and Boumehdi, M. A.: The deep structure of the Richat magmatic intrusion (northern Mauritania) from geophysical modelling. Insights into its kinematics of emplacement, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-711, https://doi.org/10.5194/egusphere-egu22-711, 2022.

EGU22-780 | Presentations | G4.3

Effect of Gravity Data Coverage on the Gravity Field Recovery: Case Study for Egypt (Africa) and Austria 

Hussein Abd-Elmotaal and Norbert Kühtreiber

The coverage of the gravity data plays an important role in the geoid determination. This paper tries to answer whether different geoid determination techniques would be affected similarly by such gravity data coverage. The paper presents the determination of the gravimetric geoid in two different countries where the gravity coverage is quite different. Egypt (representing the same situation in Africa) has sparse gravity data coverage over relatively large area, while Austria has quite dense gravity coverage in a significantly smaller area. Two different geoid determination techniques are tested. They are Stokes’ integral with modified Stokes kernel, for better combination of the gravity field wavelengths, and the least-squares collocation technique. The geoid determination has been performed within the framework of the non-ambiguous window remove-restore technique (Abd-Elmotaal and Kühtreiber, 2003). For Stokes’ geoid determination technique, the Meissl (1971) modified kernel has been used with numerical tests to obtain the best cap size for both geoids in Egypt and Austria. For the least-squares collocation technique, a modelled covariance function is needed. The Tscherning-Rapp (Tscherning and Rapp, 1974) covariance function model has been used after being fitted to the empirically determined covariance function. The paper gives a smart method for such covariance function fitting. All geoids are fitted to GNSS/levelling geoids for both countries. For each country, the computed two geoids are compared and the correlation between their differences versus the gravity coverage is comprehensively discussed.

How to cite: Abd-Elmotaal, H. and Kühtreiber, N.: Effect of Gravity Data Coverage on the Gravity Field Recovery: Case Study for Egypt (Africa) and Austria, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-780, https://doi.org/10.5194/egusphere-egu22-780, 2022.

EGU22-787 | Presentations | G4.3

GOCE SGG data downward continuation to the Earth’s Surface 

Georgios S. Vergos, Eleftherios A. Pitenis, Elisavet G. Mamagiannou, Dimitrios A. Natsiopoulos, and Ilias N. Tziavos

The combination of GOCE Satellite Gravity Gradiometer (SGG) data with local free-air gravity anomalies, towards the estimation of improved geoid and gravity field models, requires their downward continuation to the Earth’s surface (ES). Within the GeoGravGOCE project, which aims to explore the local improvements in geoid and gravity field modeling offered by GOCE, optimal combination of GOCE and surface data was sought in order to acquire insights of their contribution especially over poorly surveyed areas. GOCE SGG data are first pre-processed, to filter out noise and reduce long-wavelength correlated errors, and are consequently reduced to a mean orbit (MO) so that downward continuation to the Earth’s surface can be carried out. The reduction from the orbit level to a MO was performed by estimating GGM gradient grids per 1 km from the MO to the maximum orbital level, and then linearly interpolating for the reduction from the actual satellite height. Having determined the filtered GOCE filtered SGG data to a MO, the next step referred to their downward continuation to the ES. Gravity anomalies from XGM2016 generated on the ES have been used as ground truth and were upward continued to the MO in the spectral domain through the input output system theory method. The evaluation of GOCE SGG data to the MO with GGM-derived gradients is performed using a Monte-Carlo annihilation method finding the global minimum of a cost function that may possess several local minima. The GOCE data that satisfy the aforementioned criteria of this simulated annealing method are frozen and the steps mentioned above are repeated until all generated SGG data meet the criterion. The developed procedure can be successfully applied for downward continuation of GOCE SGG from a MO to the ES for regional gravity field applications. The present work summarizes the results achieved while the evaluation is performed against local free-air gravity anomalies and residuals to XGM2019.

How to cite: Vergos, G. S., Pitenis, E. A., Mamagiannou, E. G., Natsiopoulos, D. A., and Tziavos, I. N.: GOCE SGG data downward continuation to the Earth’s Surface, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-787, https://doi.org/10.5194/egusphere-egu22-787, 2022.

EGU22-927 | Presentations | G4.3

Practical implementation of the IHRF employing local gravity data and geoid models 

Riccardo Barzaghi and Georgios Vergos

With the definition of the International Height Reference System (IHRS) and the development of a roadmap for its implementation through the International Height Reference Frame (IHRF), an analytical evaluation of the various approaches for the practical determination of potential values at IHRF is necessary. In this work we focus on two main approaches to estimate geopotential values at IHRF stations. The first approach resides on the use of either local gravity anomalies and gravity disturbances around each site and the geopotential determination based on Stokes’ and Molodensky’s boundary value problems, respectively. In this scheme, the influence of the classical residual terrain model (RTM) reduction as well as that of RTM effects based on spherical harmonics expansion of the topographic potential are investigated. Furthermore, the introduction of possible biases within the various pre- and post-processing steps are thoroughly investigated, as e.g., during the estimation of station geometric heights, along with the influence of the quasi-geoid to geoid separation estimation. In the second approach, we investigate the determination of geopotential values based on either national and regional geoid models, i.e., resembling the case that access to local gravity data is not available, and the determination has to be based on some available geoid model. In the present work we analyze the theoretical and methodological steps that need to be followed in each approach, identifying the possible sources of biases. Finally, some early results are presented aiming at providing a roadmap and an error assessment for the practical realization of the IHRF.

How to cite: Barzaghi, R. and Vergos, G.: Practical implementation of the IHRF employing local gravity data and geoid models, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-927, https://doi.org/10.5194/egusphere-egu22-927, 2022.

EGU22-1602 | Presentations | G4.3

Comparison between towed absolute and shipborne 3C fluxgate magnetic measurements in shallow water. Applications for marine geophysical surveys. 

Hugo Reiller, Jean-François Oehler, Sylvain Lucas, Guy Marquis, Didier Rouxel, and Marc Munschy

We compare marine magnetic measurements simultaneously acquired with absolute and three-component fluxgate sensors to evaluate their respective benefits for marine geophysical mapping and detection surveys.

Shom collected the data in shallow waters, in the Bay of Brest (France) and in the Iroise Sea, during two cruises in the Fall 2021. As per standard practice, an absolute Overhauser magnetometer was towed 180 m behind the 60 m-long Laplace and Lapérouse hydrographic vessels. In addition, two vector magnetometers were temporarily installed at the top of the ship’s mast and on the roof of a 10 m-long launch. Scalar data were processed following Shom’s standards: shift to sensor position, layback adjustments, removal of gyrations and spikes, filtering and calculation of magnetic anomalies by removing the IGRF model (Alken et al., 2021) and reducing external variations measured at a local reference station. Vector data were corrected for the strong magnetic fields generated by the hull and other steel components of the ship by the application of a “scalar compensation” using a least-squares regression analysis (Leliak, 1961) on data from figures of merit. The compensated vector data then need to be low-pass filtered to remove uncorrected variations of attitude and heading. Magnetic anomalies were finally computed by removing the median value for each profile and reducing external variations from the same local reference station.

Our first results show that maps of total-field anomalies derived from vector data acquired on the ship are very close to those of the absolute data upward-continued to the altitude of the mast. This similarity suggests that it is possible to perform good-quality magnetic surveys without the constraint of having to tow an instrument. The different processing steps however raise the detection threshold for anthropogenic objects lying on the seafloor or partially buried. Vector data acquired on smaller launchs are much more complicated to compensate as ranges of pitch, roll and heading variations are greater than for a large ship and potentially imperfectly sampled by the figures of merit.

How to cite: Reiller, H., Oehler, J.-F., Lucas, S., Marquis, G., Rouxel, D., and Munschy, M.: Comparison between towed absolute and shipborne 3C fluxgate magnetic measurements in shallow water. Applications for marine geophysical surveys., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1602, https://doi.org/10.5194/egusphere-egu22-1602, 2022.

EGU22-1673 | Presentations | G4.3

Crustal structures from receiver functions and gravity analysis in central Mongolia 

Alexandra Guy, Christel Tiberi, and Saandar Mijiddorj

3D forward gravity modelling combined with receiver function analysis characterize the structures of the southern part of the Mongolian collage. Recently, a multidisciplinary approach integrating potential field analysis with geology and magmatic geochemistry demonstrate that relamination of an allochtonous felsic to intermediate lower crust played a major role in southern Mongolia structure. Relamination of material induces a homogeneous layer in the lower crust, which contrasts with the highly heterogeneous upper crustal part composed of different lithotectonic domains. The seismic signals of the 48 stations of the MOBAL2003 and the IRIS-PASSCAL experiments were analyzed to get the receiver functions. The resulting crustal thickness variation is first compared with the topography of the Moho determined by the 3D forward modeling of the GOCE gravity gradients. In addition, seismic stations south of the Hangay dome display significant signal related to the occurrence of a low velocity zone (LVZ) at lower crustal level. The receiver function analysis also revealed a significant difference between the crustal structures of the Hangay dome and the tectonic zones in the south. Finally, these seismic analysis inputs such as crustal thickness, strike and dips of the seismic interfaces as well as the boundaries and the lithologies of the different tectonic zones constitute the starting points from the 3D forward gravity modelling. The combination of these two independent methods enhances the occurrence and the extent of a low velocity and a low density zone (LVLDZ) at lower crustal level beneath central Mongolia. These LVLDZ may demonstrate the existence of the relamination of a hydrous material in southern Mongolia.

How to cite: Guy, A., Tiberi, C., and Mijiddorj, S.: Crustal structures from receiver functions and gravity analysis in central Mongolia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1673, https://doi.org/10.5194/egusphere-egu22-1673, 2022.

EGU22-1899 | Presentations | G4.3

Bathymetric Effects on Geoid Modeling 

Xiaopeng Li, Miao Lin, Jordan Krcmaric, Yuanyuan Jia, Ck Shum, and Daniel Roman

Bathymetric data over lake areas are not included in previous NGS (National Geodetic Survey) geoid model computations. Mean lake surfaces are used as the bare rock surface during the modeling. This approximation treats the water body as rocks with the same size, and causes errors that can be avoided. This study uses the bathymetric model to rigorously compute the volume of water bodies instead of treating them as rocks, during geoid modeling. To make fair comparisons and show the effects clearly, three sets of geoid models are generated with the same theory currently used at NGS, and with the same parameters. Model-Base is computed without bathymetric information of the water body. In this model, the real water bodies are simply replaced by rocks. Model-Condensed and Model-Density are generated with bathymetric information. The treatments of water bodies are different between the two models, but both are based on the hypothesis of mass conservation. The water bodies are condensed into the equivalent rocks in the Model-Condensed, leading to the geometrical shape changes in the lake area. In the Model-Density, the density of each topographical column bounded by the lake surface and geoid is taken as the average of the density of water and rock bodies included in this column, resulting in the density changes in the lake area. The study area is focused on the Great Lakes area of North America. The geoid model differences between Model-Condensed and Model-Base range from -18 to 25 mm, forming a Gaussian distribution. The distribution of the geoid model differences between Model-Density and Model-Base are not in a Gaussian form, and their values are in the range between -1 and 18 mm. Both the nearby GNSS/Leveling bench marks from US and the multi-year averaged altimetry data are used to validate the results. Consistent geoid model precision improvements of about 2 mm are confirmed around the Lake Superior, which is the deepest and largest lake, over all selected frequency bands of the Stokes’s kernel. The numerical results prove the importance of considering water bodies in the determination of a high-accuracy geoid model over the Great Lakes area.

How to cite: Li, X., Lin, M., Krcmaric, J., Jia, Y., Shum, C., and Roman, D.: Bathymetric Effects on Geoid Modeling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1899, https://doi.org/10.5194/egusphere-egu22-1899, 2022.

EGU22-2625 | Presentations | G4.3

Magnetic and gravimetric modeling of the Monchique magmatic intrusion in south Portugal 

Gabriela Camargo, Marta Neres, Machiel Bos, Bento Martins, Susana Custódio, and Pedro Terrinha

The Monchique alkaline complex (MAC) crops out in southern Portugal with a roughly elliptical shape of about 80 km2 elongated along ENE-WSW direction. The MAC dates to Late Cretaceous (69-72 Ma) and intrudes the Carboniferous Flysh formation of the South Portuguese Zone. At the surface, it comprises two main types of syenites: a central homogeneous nepheline syenite surrounded by a heterogeneous syenite unit, and some less expressive outcrops of mafic rocks (gabbros, hornfels, breccia and basalts). This igneous complex belongs to the Upper Cretaceous West Iberia alkaline magmatic event, characterized by alkaline magmatism of sublithospheric origin and active from approximately 100 Ma to 69 Ma.

The Monchique region hosts the most active seismic cluster of mainland Portugal, with low magnitude earthquakes (M < 4) that occur along lineations with NNE–SSW and WNW–ESE preferred orientation.

In this work we study the Monchique region through gravimetric and magnetic methods in order to: 1) better understand how the MAC influences the geomagnetic and gravimetric field in the region; 2) to create a new and consistent 2D and 3D model for the intrusion; and 3) to help constraining the origin of the observed seismicity and its possible relation with the existence of subcropping magmatic bodies.

We process recently acquired data - ground gravity survey (49 points) and drone-borne aeromagnetic survey – and integrate it with existing data. The interpretation of gravimetric results is complemented by density analysis of magmatic and host rocks. We perform 3D magnetic and gravity inversion to model the geometry of gravity and magnetic sources, and 2D magnetic forward modeling along a representative profile.

The calculated Bouguer gravity anomaly shows a positive gradient towards the southwest with a negative peak in the center of the Monchique mountain. However, when applied the terrain correction (complete Bouguer anomaly), this peak vanishes. This is justified by the similar mean density values for the syenite and host rocks, respectively 2560 kg/m3 and 2529 kg/m3.

The new aeromagnetic data allows for mapping the Monchique magnetic anomaly with unprecedented detail and reveal a 10 km elongated anomaly with 30 m wavelength with maximum 1707 nT amplitude. 3D susceptibility inversion models show a 15km long body with maximum depth between 5-10km, and susceptibility >0.02 SI, in agreement with previous susceptibility analysis in the region. The highest magnetic signal is found at Picota hill (east), but the deepest parts of the intrusion seem to be bellow Foia hill (west). It is noteworthy that earthquake hypocenters concentrate at depths of 5-20 km, thus below most of the modeled magmatic intrusion.  

This work was developed for the MSc thesis of GCC, in the frame of ATLAS project (PTDC/CTA-GEF/31272/2017), POCI-01-0145-FEDER-031272, FEDER-COMPETE/POCI 2020) partly funded by FCT. FCT is further acknowledged for support through projects UIDB/50019/2020-IDL, PTDC/CTA-GEF/1666/2020 and PTDC/CTA-GEF/6674/2020.

How to cite: Camargo, G., Neres, M., Bos, M., Martins, B., Custódio, S., and Terrinha, P.: Magnetic and gravimetric modeling of the Monchique magmatic intrusion in south Portugal, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2625, https://doi.org/10.5194/egusphere-egu22-2625, 2022.

The presence of subglacial sediments is important in enabling streaming ice flow and may be a critical controlling factor in determining the onset regions of ice streams. Improving our knowledge of the location of sedimentary basins underlying large ice sheets will improve our understanding of how the substrate influences the ice streams.  Advancing our understanding of the interaction between subglacial sediments and ice flow is critical for predictions of ice sheet behavior and the consequences on future climate change. To date, no comprehensive distribution of onshore and offshore sedimentary basins over Antarctica has been developed. The goal of this project is to use a combination of large-scale datasets to characterize known basins and identify new sedimentary basins to produce a continent-wide mapping of sedimentary basins and provide improved basal parametrizations conditions that have the potential to support more realistic ice sheet models. The proposed work is divided into three main steps. In the first step, the Random Forest (RF), a supervised machine learning algorithm, is used to identify sedimentary basins in Antarctica. In the second step, a regression analyses between aerogravity data and topography is done to evaluate the gravity signal related to superficial heterogeneities (i.e. sediments) and compare the results to the depth of magnetic sources using the Werner deconvolution method. Last, the correlation between sedimentary basins and ice streams is investigated. Here, we will present the preliminary results from Step 1. The Random Forest uses ensemble learning method for classification and regression. The classification rules for this present work are based on the geophysical parameters of major known sedimentary basins. First we classify the known basins with all available geophysical compilations including topography, gravity and magnetic anomalies, sedimentary thickness, crustal thickness, geothermal heat flux, information on the geology, rocky type and bedrock geochemistry, and then use the Random Forest machine learning algorithm to classify the geology underneath the ice into consolidated rock and sediments based on these parameters.

How to cite: Constantino, R. R., Tinto, K. J., and Bell, R. E.: Using random forest machine learning algorithm to help investigating the relationship between subglacial sediments and ice flow in Antarctica, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2658, https://doi.org/10.5194/egusphere-egu22-2658, 2022.

EGU22-3409 | Presentations | G4.3

Short-wavelength Bouguer anomaly and folding with disclination in the northeastern Japan 

Mitsuhiro Hirano and Hiroyuki Nagahama

In the northeastern Japan arc with the active compressive stress field since ~3 Ma, it is reported that a characteristic relationship between crustal deformation including faulting and short-wavelength (< 160 km) Bouguer anomalies. According to previous studies, active faults tend to be located in negative regions, which are caused by cracks and volumetric strain due to accumulated fault dislocation. Especially, it is shown that in strain concentration zones with active faults and muti folding, the effect of accumulated fault dislocation forms the negative zones of gravity anomaly along the northeastern Japan arc, impacting the pattern of short-wavelength Bouguer anomalies throughout the entire arc. In this presentation, we extend this concept further and discuss the positive and negative zones of gravity zones along the entire northeastern Japan arc from the geometrical viewpoint of folding with one of the defect, disclination. Folding is described by Euler-Schouten curvature tensor, which defines the protrusion of included space (e.g., two-dimensional Riemannian space) from enveloping space (e.g., three-dimensional Euclid space). Based on previous studies, the density of earthquake occurrence is proportional to the curvature of the plastic folding deformation of the crust, which is related to Euler-Schouten curvature, and fault dislocation also accumulates at the regions with its high curvature. The row (accumulation) of fault dislocation can be replaced by the disclination, and Riemann-Christoffel curvature, derived from Euler-Schouten curvature tensor, also expresses disclination density. In particular, angular folding with local curvature accompanied by a pair of disclination is called Kink folding, forming the mass-loss or mass-excess regions around disclination. Since Kink folding can approximately be the same as the undulating region bounded by several faults (fault block) in strain concentration zones, it is expected that the northeastern Japan arc has not only negative zones of gravity anomaly but also positive zones along the arc due to the mass-loss or mass-excess regions around disclination. Therefore, we conclude that the positive and negative zones of gravity anomaly along the northeastern Japan arc reflect the geometric condition of the crust with disclination.

How to cite: Hirano, M. and Nagahama, H.: Short-wavelength Bouguer anomaly and folding with disclination in the northeastern Japan, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3409, https://doi.org/10.5194/egusphere-egu22-3409, 2022.

EGU22-3615 | Presentations | G4.3

Moho depth evaluation using GOCE gradient data and Least Square Collocation over Iran 

Carlo Iapige De Gaetani, Hadi Heydarizadeh Shali, Sabah Ramouz, Abdolreza Safari, and Riccardo Barzaghi

Investigating the crustal architecture, specifically the discontinuity interface between the upper mantle and lower crust of the Earth, so-called Moho, can be done in three prevailing techniques, namely lithology, seismicity, and gravity. In contrast to using the information from analyzing the characteristics of rocks and seismic waves, which are sparsed and expensive, inverting gravity data of satellite missions such as GOCE and GRACE is a suitable alternative for such purposes.

The present paper attempts to map the Moho surface using the gravity data as we considered a simplified Earth model based on three shells including the core, mantle and crust with a potential T on a given sphere outside this body. In this notation, by subtracting the topographic effects, compensating for density anomalies in the crust, and other known constants from the observation that are given on and outside the mean Earth radius, one is left with the potential of a single layer on the mean Moho sphere by taking into consideration the Helmert condensation approach. In planar approximation, this is to say that the topography is formally referred to an xy plane and also the condensation surface which is a plane, situated at a depth D below the previous one. Therefore, relating the topographic load of a mass column with height h over the same elementary area element at depth d, the measure of how deep the crust is sinking into the mantle material as a consequence of the load, we can interpret the Moho variations with respect to some mean crustal thickness.

To do this inversion, we applied the Least Square Collocation (LSC) approach which uses the functional relationships between the quantities, the auto-covariance and cross-covariance matrices based on a covariance function between observations and the unknowns. Practically, after constructing the required residual data, an empirical covariance is estimated, then fitted to analytical one to define the required covariance models.

Finally, the Moho variations has been estimated in an active tectonic zone created by the continental collision of the Arabian plate from South-West and Turan shield from North-East with respect to a mean Moho depth equal to 45 km. Results of this study are comparable and much the same with other studies so that different rheological zones of Iranian plateau can be seen in this estimated map of Moho. For instance, a maximum depth is estimated for Sanandaj-Sirjan zones in South-East and minimum depth for Caspian Sea in North.

How to cite: De Gaetani, C. I., Heydarizadeh Shali, H., Ramouz, S., Safari, A., and Barzaghi, R.: Moho depth evaluation using GOCE gradient data and Least Square Collocation over Iran, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3615, https://doi.org/10.5194/egusphere-egu22-3615, 2022.

EGU22-4230 | Presentations | G4.3

Crowd modelling: Launching an open gravity-modelling call to challenge the Balmuccia peridotite body 

György Hetényi, Ludovic Baron, Matteo Scarponi, Shiba Subedi, Konstantinos Michailos, Fergus Dal, Anna Gerle, Benoît Petri, Antonio Langone, Andrew Greenwood, Luca Ziberna, Mattia Pistone, Alberto Zanetti, and Othmar Müntener

Modelling of geophysical data is often subject to choices made by the researcher undertaking the work. The level of structural complexity in the model, the bounds on parameters imposed by a priori knowledge, the thoroughness and efficiency in exploring the parameter space may all lead to bias in determining what the best fitting models can be.

To avoid bias from our own ideas in constraining the subsurface shape of a given density anomaly, we hereby invite anyone interested to create their own models. This is planned by sharing the same gravity data measured in the field, the same digital elevation model, the main features of the local geological maps, and bounds on the encountered rock density values. These data will be shared openly, in the form of a modelling challenge: each participating researcher or group is expected to submit their solution(s). All these will be compared during a dedicated workshop, ultimately resulting in a joint publication.

The target of this modelling challenge is the world-famous Balmuccia peridotite body (45.84°N, 8.16°E) in the Ivrea-Verbano Zone (IVZ). Here mantle rocks are naturally exposed at the surface, in the broader context of the IVZ, a middle- to lower crustal terrain along the Europe-Adria plate boundary’s eastern side. The surface exposure of the Balmuccia peridotite is ~ 4.4 km N-S by 0.6 km E-W, with outcrop elevation changes exceeding 1000 m. About 150 new gravity data points have been measured within a radius of 3 km from the centre of the peridotite body, along more or less accessible paths and slopes. The measurements have been carried out with a Scintrex CG-5 relative gravimeter, tied to a reference point, and all points located via differential GPS with typical vertical precision of a few cm. Farther away regional gravity data is available at few km spacing.

Beyond the modelling challenge, the interest in constraining the subsurface shape of the Balmuccia peridotite body is its future target role in the ICDP DIVE continental drilling project (www.dive2ivrea.org).

How to cite: Hetényi, G., Baron, L., Scarponi, M., Subedi, S., Michailos, K., Dal, F., Gerle, A., Petri, B., Langone, A., Greenwood, A., Ziberna, L., Pistone, M., Zanetti, A., and Müntener, O.: Crowd modelling: Launching an open gravity-modelling call to challenge the Balmuccia peridotite body, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4230, https://doi.org/10.5194/egusphere-egu22-4230, 2022.

EGU22-4803 | Presentations | G4.3

Separation of gravimetric and magnetic anomalies with different degrees of regionality in the Eastern Carpathians, Romania 

Natalia-Silvia Asimopolos and Laurentiu Asimopolos

The gravity and magnetic anomalies separation operation consists in determining the number of sources, the characteristics of each (depth, density, shape, and dimensions) so as to result in cumulative total anomaly, measured at the Earth’s surface. This separation has to be done in the context of the fundamental ambiguity of gravimetric and magnetic information, based on the cause-effect ratio. There are various methods for achieving this separation of anomalies. This paper presents some examples of the use of the moving average method and the polynomial trend surfaces. In particular, we presented the results of the mobile mediation with different windows compared to the tendency surfaces with different degrees, for a case study in Eastern Carpathians mountains area. For this study we used data available from several sources.

From the International Gravimetric Bureau we used gravimetric data for the WGM2012 geoglobal model: Bouguer anomaly for density 2.67 g / cm3, outdoor anomaly, isostatic anomaly, gravitational disturbance and altitude.

From the geophysics portal of the Geological Institute of Romania we used the magnetic data resulting both from the scanning of the national geomagnetic maps and from the catalogs of measurements from the archive. We also used the deep geological sections made on the basis of seismic data, corroborated with gravimetric and magnetic data that cross the Eastern Carpathians.

Other data used for depth correlations were the isobath map of the Moho surface, the Conrad surface, the geoid, and the quasigeoid.

For the study of deep tectonics based on all the data used we used the correlation coefficient between various parameters, calculated in movable windows of different sizes both in plan and in space. For this we have developed specific calculation programs.  The moving average is a direct method for separating regional effects and local (residual) effects. Polynomial trend surfaces analysis contributes to the recognition, isolation and measurement of trends that can be calculated and represented by analytical equations, thus achieving a separation in regional and local variations. The analytical expressions of the polynomial trends based on the least squares method were calculated, highlighting the regional trend caused by the deep structures. Then, by calculating the residual values resulting from the difference between the initial values and the trend values from the network nodes used, we highlighted the superficial local effects. We also obtained information about the regional trend caused by geological structures at medium and large depths, by calculating the difference between gravity parameters, obtained with different moving average windows or tendency surfaces with different degrees, interpolated in same network.

How to cite: Asimopolos, N.-S. and Asimopolos, L.: Separation of gravimetric and magnetic anomalies with different degrees of regionality in the Eastern Carpathians, Romania, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4803, https://doi.org/10.5194/egusphere-egu22-4803, 2022.

EGU22-6489 | Presentations | G4.3

Drone-magnetic survey along the Alentejo coast (SW Portugal): a quest for the intruded Messejana fault 

Diogo Rodrigues, Marta Neres, Pedro Terrinha, Machiel Bos, and Bento Martins
 
 

How to cite: Rodrigues, D., Neres, M., Terrinha, P., Bos, M., and Martins, B.: Drone-magnetic survey along the Alentejo coast (SW Portugal): a quest for the intruded Messejana fault, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6489, https://doi.org/10.5194/egusphere-egu22-6489, 2022.

EGU22-6615 | Presentations | G4.3

Examination of magnetic map variability and uncertainty: crustal magnetic anomalies in oceanic areas 

Richard Saltus, Arnaud Chulliat, Brian Meyer, and Martin Bates

To paraphrase a common model aphorism: “all magnetic maps are wrong, some are useful”. In other words, all maps of the Earth’s magnetic field are subject to uncertainty, both observationally and dynamically. Depending on the intended use of the map, this uncertainty will have varying implications. For those of us who build and use magnetic maps it is important to gain understanding of the uncertainty in these maps to ensure that they are clearly presented and suitable for a given use.

Uncertainty evaluation is a general challenge that affects all magnetic maps and models, but here we concentrate on maps of magnetic anomalies (i.e., perturbations of the Earth’s main field primarily due to variations in magnetic minerals in the crust and shallow mantle) in oceanic areas.

Magnetic anomaly maps for oceanic regions are typically representations of gridded data. The grids are built from available data which generally consists of marine trackline data with a range of ages, collection parameters and uncertainty in original observations. Data coverage and trackline geometries are highly variable around the world. For example, near-shore regions in the Northern Hemisphere tend to be well sampled, whereas open ocean portions of the Southern Hemisphere are poorly sampled.

Quantification of cell by cell uncertainty for magnetic anomaly grids can be subdivided into two regimes: cells containing data and cells without data. For cells containing data, factors such as point-wise observation uncertainty, number of observations, and spatial distribution of data, can be analysed to estimate grid value uncertainty. For interpolated cells, factors such as distance to nearest data cells, local field behavior, and uncertainty in surrounding cells are relevant.

Using NOAA/NCEI trackline marine data for portions of the Caribbean Sea and North Atlantic we are constructing and testing uncertainty models and methods for representing this uncertainty for a variety of magnetic map uses. For a marine magnetic anomaly grid of a portion of the North Atlantic at a 4 km grid interval (the same grid interval used by our global EMAG2 magnetic anomaly compilation), the calculated cell level uncertainty ranges from 20 nT to 150 nT with a mean value of 90 nT. This mean value is similar to the average grid uncertainty of 100 nT/cell that we estimated for marine areas of EMAG2v3. Different gridding approaches, including kriging or minimum curvature algorithms, yield variations in individual cell values, but these variations fall within our estimated uncertainty ranges. 

How to cite: Saltus, R., Chulliat, A., Meyer, B., and Bates, M.: Examination of magnetic map variability and uncertainty: crustal magnetic anomalies in oceanic areas, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6615, https://doi.org/10.5194/egusphere-egu22-6615, 2022.

EGU22-6671 | Presentations | G4.3

Accuracy requirements of the gravity measurements for sub-centimetre geoid 

Ismael Foroughi, Spiros Pagiatakis, Mehdi Goli, and Stephen Ferguson

In this contribution, we estimate the uncertainty (error) of the input gravity measurements needed for the determination of the geoid with an internal sub-centimetre accuracy. The accuracy of the geoid height is a function of the resolution/accuracy of the input gravity and topographical data, and the methodology used to solve a geodetic boundary value problem. The purpose of this study is to estimate the maximum allowable error in the terrestrial gravity measurements based on a required standard deviation of the error in the geoid heights (e.g., ≤1cm). This is done with an assumption of a known Digital Elevation Model (DEM), and an Earth Gravitational Model (EGM) along with their error estimates.

 

We use the one-step integration method (one-step kernel) for the determination of the geoid. In this method, the anomalous gravity at any surface above the geoid is estimated by integrating over the geoid-level disturbing potentials in harmonic space. By applying the covariance law to the one-step integration method, the error of the gravity measurements at the Earth's surface can be estimated using the expected error of the geoid heights. Taking advantage of the remove-compute-restore technique, we estimate the error of the residual surface gravity measurements using the (known) error estimates of the topographical and EGM corrections.  

 

We select the Colorado test area (35°N - 40°N, 250°E - 258°E) to generate a 1¢×1¢ grid of geoid random errors with a standard deviation of 1cm. We use the topographical data from the Shuttle Radar Topography Mission (SRTM) Ver. 3.0. and the global model of DIR_R5 up to degree/order 140 to apply the remove-compute-restore technique. The uncertainty estimate of the SRTM heights and the covariance matrix of the spherical harmonic coefficients of the DIR_R5 are used to calculate the errors of the topographical gravitational attraction and low-degree EGM signals on the geoid heights and surface anomalous gravity data.

 

Our preliminary results show that to achieve a sub-centimetre accuracy in the Colorado area, we require grid surface gravity measurements with a standard deviation of less than 2.5mGal. This result is optimistic as in the geoid determination process, the anomalous gravity data are downward continued from the Earth’s surface to the geoid, whereas this step is not required in our experience. Besides, we assume a constant standard deviation of 1cm for all the errors of the geoid heights, whereas such high accuracy may not be needed in high mountains. We will provide further results for the elevation-dependent geoid error and also investigate the effect of downward continuation on our results.     

How to cite: Foroughi, I., Pagiatakis, S., Goli, M., and Ferguson, S.: Accuracy requirements of the gravity measurements for sub-centimetre geoid, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6671, https://doi.org/10.5194/egusphere-egu22-6671, 2022.

EGU22-7769 | Presentations | G4.3

Two-dimensional gravity and magnetic model along a new WARR profile in the transition zone from the Precambrian to Palaeozoic platform in the southern Baltic 

Małgorzata Ponikowska, Stanislaw Mazur, Tomasz Janik, Dariusz Wójcik, Michał Malinowski, Christian Hübscher, and Ingo Heyde

Defining a transition zone between the Precambrian East European Craton (EEC) and the Palaeozoic West European Platform (WEP) is still a matter of discussion despite a large body of geophysical and geological data. The main tectonic feature of the transition zone is the Teisseyre-Tornquist Zone (TTZ), which has been variously interpreted over the past decades mainly because of a thick (c. 10 km) Palaeozoic and Mesozoic sedimentary cover masking its crustal architecture.  We investigated the crustal structure of the TTZ using a 270-km long wide-angle reflection/refraction profile (WARR) measured along 15 ocean-bottom seismometers and 2 land stations during the course of the RV MARIA S. MERIAN expedition ‘MSM52’. This NE to SW profile is oriented nearly parallel to the Polish coast, located ~ 48 km south of the Danish island of Bornholm. We prepared a two-dimensional gravity and magnetic forward model along this profile, using the Geosoft GM-SYS software with layers of infinite length. The basis for the potential field modelling is a seismic velocity model that has been prepared through trial-and-error forward modelling.

The seismic velocity model shows a continuity of the lower and middle crust of the EEC towards the basement of the WEP. The synthetic magnetic profile is smooth and indicates that the seismic data accurately revealed the geometry and depth of the magnetic (crystalline) basement. However, the model was unable to replicate short-wavelength, high-amplitude magnetic anomalies in the ENE section of the profile, probably representing iron oxide mineralisation in the crystalline basement of the EEC. The gravity model shows 3 areas of misfit between the synthetic and observed gravity profile. The most prominent misfit coincides with the NE boundary of the TTZ. To remedy the misfit, we produced two alternative gravity models that deviate from the seismic velocity model in the problematic area. One model postulates a crustal keel underneath the NE section of the TTZ and the other suggests the presence of a middle crust magmatic intrusion. Both models equally and adequately reduce the misfit of the gravity model.

Our models suggest a SW-ward continuation of the Baltica middle and lower crust through the TTZ and seem to preclude the coincidence of the Caledonian Thor suture with the TTZ. An important perturbation of the upper crust and sedimentary cover within the latter is mostly associated with the superimposed effects of Devonian-Carboniferous and Permian-Mesozoic extension. The only conspicuous compressional event confirmed by our data is the Late Cretaceous-Paleogene inversion of the Permian-Mesozoic basin. Due to limited resolution, our models did not reveal the effects of Caledonian nor Variscan shortening, including the Caledonian Deformation Front.

This study was funded by the Polish National Science Centre grant no UMO-2017/27/B/ST10/02316.

How to cite: Ponikowska, M., Mazur, S., Janik, T., Wójcik, D., Malinowski, M., Hübscher, C., and Heyde, I.: Two-dimensional gravity and magnetic model along a new WARR profile in the transition zone from the Precambrian to Palaeozoic platform in the southern Baltic, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7769, https://doi.org/10.5194/egusphere-egu22-7769, 2022.

EGU22-8228 | Presentations | G4.3

New insights to characterize the La Cerdanya basin structure from 3D gravity modelling 

Pilar Clariana, Roberto Muñoz, Concepción Ayala, Fabián Bellmunt, Perla Piña-Varas, Ruth Soto, Anna Gabàs, Albert Macau, Félix Rubio, Carmen Rey-Moral, and Joan Martí

The acquisition and interpretation of gravity and magnetic data represents a cost-effective tool in geophysics since it allows to determine the geometry and distribution of the density and magnetic properties at depth of the subsurface rocks. The study area, where gravity and magnetic data have been interpreted, is the La Cerdanya basin (Eastern Pyrenees), a Neogene ENE-WSW oriented half graben located in the Axial Zone, the central part of the Pyrenees mainly formed by Paleozoic rocks. It is situated in the NW block of the La Tet fault and its Neogene sediments lie unconformably on top of the Paleozoic basement. Its dimensions are approximately 30 km long and 7 km wide. The tectonic evolution and geometry of the La Cerdanya basin is not well known and this work aims to add new constraints to help solving the Neogene tectonic evolution of the Eastern Pyrenees and to improve the knowledge of its 3D geometry. 

The magnetic anomaly map of the study area, based on airborne magnetic data, shows very little contrasts of the magnetic properties between the Neogene rocks of the La Cerdanya basin and the Paleozoic rocks surrounding it. Gravity data consist of previous and new acquired gravimetric stations and the residual Bouguer anomaly map shows density contrasts big enough to model the geometry of the basin and the neighbor intrusive bodies. They have been incorporated into a 3D geological model based on available geological and petrophysical data using the 3D GeoModeller software. The 3D potential fields model has been made taking into account the three most representative units outcropping in the study area: the Neogene rocks, the Late Carboniferous intrusive bodies and the Paleozoic basement. The resulting potential fields response of the model is consistent with the observed data. The 3D model shows a basin slightly deeper than shown in previous works and has helped to better define the 3D geometry of the basin and the along-strike geometry of the La Tet fault.

How to cite: Clariana, P., Muñoz, R., Ayala, C., Bellmunt, F., Piña-Varas, P., Soto, R., Gabàs, A., Macau, A., Rubio, F., Rey-Moral, C., and Martí, J.: New insights to characterize the La Cerdanya basin structure from 3D gravity modelling, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8228, https://doi.org/10.5194/egusphere-egu22-8228, 2022.

Magnetic surveys employing Uncrewed Aerial Systems (UAS) allow a fast and affordable acquisition of high-resolution data. We developed a self-built carbon-fiber frame which can be used to attach magnetometers 0.5 m below an UAS. In order to remove undesired signals from the magnetic recordings that originate from the aircraft and that can cause strong heading errors, we apply calibration processes often referred to as magnetic compensation. These processes are usually applied for manned aerial surveys for both scalar and vector magnetometer data and require flying a calibration pattern prior to a survey. We recently published open-source software written in Python to process data and compute compensations for both scalar and vector magnetometers. We tested our method with two commercially available magnetometer systems (scalar and vector) by flying dense grid patterns over a test site using different suspension methods (magnetometer system attached to 2.8 m long tethers, fixed on the landing gear of the UAS, and fixed on our frame configuration). The accuracy of the magnetic recordings was assessed using both standard deviations of the calibration pattern and tie-line cross-over differences from the grid survey. Our frame configuration resulted after magnetic compensation in the highest accuracy of all configurations tested. The frame also allows for the acquisition of aeromagnetic data under a wide range of flight conditions. This is of great advantage compared to the often-used tethered solutions to avoid recording the aircraft’s signals. Since tethered payloads are prone to rotations and swing motions, they require skilled pilots and can be difficult to fly safely. In contrast to that, our system is easy to use and due to its high in-flight stability, even fully autonomous flights are possible. Since the calibration flights that are required for magnetic compensation need to be collected in areas with low magnetic gradients, it can be difficult to find suitable locations in areas with strong magnetic gradients – such as in volcanic and geothermally active regions. However, a survey collected at the location of the calibration site can be used to evaluate the geological magnetic signal. The compensation process involves then two successive evaluations of the compensation parameters. First, an approximate evaluation of the compensation parameters is done assuming a constant value of the magnetic field at the calibration site. The resulting compensation parameters are then used to compensate the survey data collected over the calibration site and evaluate the magnetic field along the calibration pattern trajectory. Second, the compensation parameters are reevaluated taking the magnetic field variations into account. We tested this double calibration scheme on recordings that were collected over the Krafla geothermal area in the Northern Volcanic Zone of Iceland. The double calibrated data resulted in higher accuracy than a single calibration showing that this method can improve magnetic compensation in magnetically high-gradient areas.

How to cite: Kaub, L., Bouligand, C., and Glen, J. M. G.: Collecting and calibrating magnetic data from surveys with Uncrewed Aerial Systems (UAS) and an approach for regions with strong magnetic gradients, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11258, https://doi.org/10.5194/egusphere-egu22-11258, 2022.

EGU22-11302 | Presentations | G4.3

Gravimetric quasi-geoid of the Baltic Sea and comparison to GNSS levelling, DTU21 and tide gauges 

Hergeir Teitsson and René Forsberg

A gravimetric quasi-geoid model, based on the latest FAMOS database release, has been computed for the Baltic Sea region, aiming for a best-possible model on the sea, while not focusing on the surrounding land.

 The geoid computation is based on the FFT remove-compute-restore method. XGM2019 is used as global reference field, with a Wong-Gore linear tapering from 180 to 200. No terrain corrections are included in the computation, since these are not expected to contribute to the accuracy of the model on the sea.

The gravimetric quasi-geoid model is compared to a GNSS-levelled ITRF2008 zero-tide dataset, the altimetry based DTU21 Mean Sea Surface dataset, and to a few tide gauge stations distributed throughout the region. Some preliminary comparisons to the GNSS-levelling dataset indicates that the gravimetric geoid has an accuracy of ±25 mm in the region surrounding the Baltic Sea.

How to cite: Teitsson, H. and Forsberg, R.: Gravimetric quasi-geoid of the Baltic Sea and comparison to GNSS levelling, DTU21 and tide gauges, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-11302, https://doi.org/10.5194/egusphere-egu22-11302, 2022.

EGU22-12321 | Presentations | G4.3

eXperimental jOint inveRsioN (XORN) project: first results of a 3D joint gravity and magnetic inversion 

Martina Capponi and Daniele Sampietro

The Earth crust represents less than 1% of the volume of our planet but is exceptionally important as it preserves the signs of the geological events that shaped our planet. This thin layer is the place where the natural resources we need can be accessed (e.g.  critical raw materials, geothermal energy, water, oil and gas, minerals, etc.). For these reasons, a thorough understanding of its structure is crucial for both scientific and industrial future activities. It is well known that potential fields methods, exploiting gravity and magnetic fields, are among the most important tools to recover fundamental information on the Earth crust. In recent years, thanks to the increasing availability of seismic/seismological data and to gravity and magnetic satellite missions, the crust has been thoroughly investigated and modelled at global and continental scales. However, despite this progress, it remains poorly understood in many regions as global models are often too coarse to provide detailed information about the regional and local dynamics.  

With this respect, the challenge to be faced nowadays is represented by the development of ad-hoc techniques to fully exploit these different geophysical global data and to merge them with regional datasets compiled at the Earth’s surface. Currently, the different sources of information when analysed individually suffer from non-uniqueness. Magnetic and gravity signals detect different crustal parameters and rarely coincide because various combinations of geological structures generate similar observations outside the sources. A promising solution is represented by the joint processing in a consistent way of both gravity and magnetic fields data, possibly incorporating the available geological knowledge and constraints coming from seismic acquisitions, in such a way to reduce the space of possible solutions. 

In the eXperimental jOint inveRsioN (XORN) project, funded by the European Space Agency through the EO4society program, Geomatics Research & Development srl (GReD) together with Laboratoire Magmas et Volcans (LMV) of Clermont Auvergne University will develop an innovative algorithm aiming at performing complete 3D joint inversion of gravity and magnetic fields properly constrained by geological a-priori qualitative information. The developed algorithm will be used within the project to recover a 3D regional model of the Earth crust in the Mediterranean Area in terms of density and magnetic susceptibility distribution within the volume, and in terms of depths of the main geological horizons. Within this regional case study particular attention will be given to the bathymetric layer thus defining and testing a strategy that could potentially be applied worldwide to improve our knowledge of this layer which is fundamental for every application that aims at studying (e.g. for tsunami hazards), conserving and sustainably using the oceans, seas and marine resources. 

The first results about technical developments will be here presented together with preliminary modelling aspects of the Mediterranean test case. 

How to cite: Capponi, M. and Sampietro, D.: eXperimental jOint inveRsioN (XORN) project: first results of a 3D joint gravity and magnetic inversion, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12321, https://doi.org/10.5194/egusphere-egu22-12321, 2022.

EGU22-12459 | Presentations | G4.3

Geologic and Tectonic units in the Iranian Plateau from present and future satellite missions 

Carla Braitenberg, Tommaso Pivetta, Alberto Pastorutti, and Magdala Tesauro

The objective of this work is to investigate the geologic and tectonic units in the Iranian plateau in relation to the information that can be obtained from the gravity field observed from space. The objective requires to collect seismologic tomography, seismicity, geodetic observations of crustal movements, a database of active faults, active seismic investigations of sediment depths, heat flow measurements and to use this information as a constraint for gravity inversion with the present available satellite-derived gravity field. The gravity field correlated to the topography defines blocks of the plateau, which indicates varying crustal rigidity (Pivetta and Braitenberg, 2020). We find that mechanisms of vertical growth are tied to crustal thickening, coherently identified from the gravity field, seismic tomography and isostasy. Persistent high density crustal blocks are identified for instance SE of Isfahan, which require further investigation and validation, also in relation to magmatism. The study is embedded in a major project addressing the “Intraplate deformation, magmatism and topographic evolution of a diffuse collisional belt: Insights into the geodynamics of the Arabia-Eurasia collisional zones” financed by the Italian Ministry (PRIN 2017). When defining the density structure and its uncertainties, the question appears, what improvements on the knowledge of the structure, seismic faults, and on the block-structure can be expected from future gravity missions, with a payload of quantum gradiometers and atom-clocks in a multi satellite configuration. The geophysical sensitivity to quantum gravimetry in space is of interest to the MOCAST+ ASI project, a follower project of the MOCASS ASI project, in which the geophysical sensitivity of the quantum gradiometer payload has been studied (Pivetta et al., 2021).

Pivetta, T., & Braitenberg, C. (2020). Sensitivity of gravity and topography regressions to earth and planetary structures. Tectonophysics, 774, 228299. https://doi.org/10.1016/j.tecto.2019.228299

Pivetta, T., Braitenberg, C. & Barbolla, D.F. (2021) Geophysical Challenges for Future Satellite Gravity Missions: Assessing the Impact of MOCASS Mission. Pure Appl. Geophys. https://doi.org/10.1007/s00024-021-02774-3

How to cite: Braitenberg, C., Pivetta, T., Pastorutti, A., and Tesauro, M.: Geologic and Tectonic units in the Iranian Plateau from present and future satellite missions, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12459, https://doi.org/10.5194/egusphere-egu22-12459, 2022.

EGU22-12634 | Presentations | G4.3

Lithospheric architecture across the Zagros Orogen as sensed by the integration of isostatic analysis, gravity inversion, and seismic tomography 

Alberto Pastorutti, Carla Braitenberg, Tommaso Pivetta, and Magdala Tesauro

Regional-scale geophysics is a central tool in improving the knowledge on geologic and tectonic units and on their structural relationships in a complex convergent setting. Harmonization, reduction, and integrated modelling of data such as gravity models and seismic tomographies allows to constrain the geometry and properties of geologic bodies at depth and to test hypotheses on their evolution. In the context of an interdisciplinary project involving multiple Italian institutions, “Intraplate deformation, magmatism and topographic evolution of a diffuse collisional belt: Insights into the geodynamics of the Arabia-Eurasia collisional zones”, we present the result of an integrated analysis across the Zagros Orogen. It represents the most active collisional zone in the Iranian plateau, consequent to the NE-ward subduction of the Neo-Tethyan Ocean.

 

We integrate models of surface topography and gravity through isostatic analysis, i.e. by enquiring the relationship connecting the two observables – the former expressing the load on the lithosphere, the latter a proxy of the crust-mantle boundary undulations. We developed and employed two independent methods, one relying on plate flexure and providing estimates on the spatial distribution of the integrated rigidity of the lithosphere, the other a non-parametric residualization method, based on topo-gravity regression analysis (Pivetta and Braitenberg, 2020). We refine their estimates by including the additional information provided by locally available models of sedimentary infills, in order to correct the loads, and by seismological Moho depth data (e.g. Gvirtzman et al., 2016), to mitigate ambiguities in the crustal thickness inferred from gravity inversion. This analysis allowed the isolation of different rigidity domains - which reflect the assemblage of tectonic provinces and the shallow expression of deep structures - and to obtain the anomalous quantities (e.g. residual gravity disturbance, residual topography) which the initial model does not explain. These include intra-crustal loads, which correlate with areas affected by magmatism and can provide further constrain on the geometry of buried structures.

 

We then improve these estimates with the data derived from seismic tomographies, including the recent shear-wave velocity model by Kaviani et al. (2020). By employing a velocity-to-density conversion strategy and gravity forward modelling, we show the impact of prior reduction of gravity data for upper-mantle signal sources. In addition to that, we use tomography-derived temperature modelling to estimate the variations of lithospheric strength profiles throughout the study area, comparing it with the independently estimated flexural rigidity.

 

Pivetta, T., & Braitenberg, C. (2020). Sensitivity of gravity and topography regressions to earth and planetary structures. Tectonophysics, 774, 228299. https://doi.org/10.1016/j.tecto.2019.228299

Gvirtzman, Z., Faccenna, C., & Becker, T. W. (2016). Isostasy, flexure, and dynamic topography. Tectonophysics, 683, 255–271. https://doi.org/10.1016/j.tecto.2016.05.041

Kaviani, A., Paul, A., Moradi, A., Mai, P. M., Pilia, S., Boschi, L., Rümpker, G., Lu, Y., Zheng, T., Sandvol, E. (2020). Crustal and uppermost mantle shear wave velocity structure beneath the Middle East from surface wave tomography. Geophysical Journal International, 221(2), 1349–1365. https://doi.org/10.1093/gji/ggaa075

How to cite: Pastorutti, A., Braitenberg, C., Pivetta, T., and Tesauro, M.: Lithospheric architecture across the Zagros Orogen as sensed by the integration of isostatic analysis, gravity inversion, and seismic tomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12634, https://doi.org/10.5194/egusphere-egu22-12634, 2022.

EGU22-12704 | Presentations | G4.3

Joint inversion of gravity and electromagnetic data — New constraints on the 3-D structure of the lithosphere beneath Central Mongolia 

Matthew Joseph Comeau, Max Moorkamp, Michael Becken, and Alexey Kuvshinov

Joint inversion of complementary datasets is an important tool to gather new insights and aid interpretation, especially in regions which show structural complexity. Using the joint inversion framework jif3D [1] with a newly developed coupling for density and resistivity, based on a variation of information approach which is a machine-learning method that constructs a possible relationship between the properties [2], we combine satellite gravity measurements with electromagnetic data, from broadband and long-period magnetotellurics [3,4,5,6].

Central Mongolia is located in the continental interior, far from tectonic plate boundaries, yet has a high-elevation plateau and enigmatic widespread low-volume basaltic volcanism [7,8,9]. The processes responsible for developing this region remain unexplained and there are questions about its tectonic evolution. A recent project employed thermo-mechanical numerical modeling [10] to simulate the temporal evolution of various tectonic scenarios, offering an opportunity to test hypotheses and determine which are physically plausible mechanisms. Constraints on lithospheric properties, e.g., density distribution, are important for evaluating the geodynamic models. Furthermore, they can help shed light on questions regarding the nature of lower crustal electrical conductors [11], which may be related to tectonically-significant low-viscosity zones.

We will present preliminary results that provide new constraints on the 3-D structure of the lithosphere beneath Central Mongolia, as well as a roadmap for moving towards integrating geophysical results into geodynamic modeling to better understand the evolution of the lithosphere.

 

References:

[1]  Moorkamp, M. et al. 2011. A framework for 3-D joint inversion of MT, gravity and seismic refraction data. Geophysical Journal International, 184(1). https://doi.org/10.1111/j.1365-246X.2010.04856.x 

[2]  Moorkamp, M., 2021. Deciphering the state of the lower crust and upper mantle with multi-physics inversion. ESSOAr. https://doi.org/10.1002/essoar.10508095.1 

[3]  Comeau, M.J., et al., 2018. Evidence for fluid and melt generation in response to an asthenospheric upwelling beneath the Hangai Dome, Mongolia. Earth and Planetary Science Letters, 487. https://doi.org/10.1016/j.epsl.2018.02.007 

[4]  Käufl, J.S., et al., 2020. Magnetotelluric multiscale 3-D inversion reveals crustal and upper mantle structure beneath the Hangai and Gobi-Altai region in Mongolia. Geophysical Journal International, 221(2). https://doi.org/10.1093/gji/ggaa039 

[5]  Becken, M., et al., 2021a. Magnetotelluric Study of the Hangai Dome, Mongolia. GFZ Data Services. https://doi.org/10.5880/GIPP-MT.201613.1 

[6]  Becken, M., et al., 2021b. Magnetotelluric Study of the Hangai Dome, Mongolia: Phase II. GFZ Data Services. https://doi.org/10.5880/GIPP-MT.201706.1 

[7]  Comeau, M.J., et al., 2021a. Images of a continental intraplate volcanic system: from surface to mantle source. Earth and Planetary Science Letters, 587. https://doi.org/10.1016/j.epsl.2021.117307 

[8]  Papadopoulou, M., et al., 2020. Unravelling intraplate Cenozoic magmatism in Mongolia: Reflections from the present-day mantle or a legacy from the past? Proceedings of the EGU. https://doi.org/10.5194/egusphere-egu2020-12002 

[9]  Ancuta, L.D., et al., 2018. Whole-rock 40Ar/39Ar geochronology, geochemistry, and stratigraphy of intraplate Cenozoic volcanic rocks, central Mongolia. Geological Society of America Bulletin, 130. https://doi.org/10.1130/b31788.1 

[10]  Comeau, M.J., et al., 2021b. Geodynamic modeling of lithospheric removal and surface deformation: Application to intraplate uplift in Central Mongolia. Journal of Geophysical Research: Solid Earth, 126(5). https://doi.org/10.1029/2020JB021304

[11]  Comeau, M.J., et al., 2020. Compaction driven fluid localization as an explanation for lower crustal electrical conductors in an intracontinental setting. Geophysical Research Letters, 47(19). https://doi.org/10.1029/2020gl088455 

 

 

 

How to cite: Comeau, M. J., Moorkamp, M., Becken, M., and Kuvshinov, A.: Joint inversion of gravity and electromagnetic data — New constraints on the 3-D structure of the lithosphere beneath Central Mongolia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12704, https://doi.org/10.5194/egusphere-egu22-12704, 2022.

The U.S. National Geodetic Survey (NGS), an office of the National Oceanic and Atmospheric Administration (NOAA), is preparing for the release of a new vertical datum, the North American-Pacific Geopotential Datum of 2022 (NAPGD2022). This new datum will be based on a high degree spherical harmonic model of the Earth’s gravitational potential, and will yield a geoid undulation model (GEOID2022) to calculate orthometric heights from GNSS-derived ellipsoid heights.

As part of the preparation for the new vertical datum, NGS has computed annual experimental geoid models (xGEOID) since 2014. The xGEOID model released in 2020 (xGEOID20) uses an updated digital elevation model (DEM) composed of TanDEM-X, MERIT, and USGS 3DEP data. The DEMs are merged together to create a seamless elevation model across the extent of the xGEOID20 model. The accuracy of the merged DEM is tested using independent datasets such as GPS observations on leveled bench marks and ground elevations from ICESat-2. The effect of the updated DEM on the geoid model is also determined by comparing geoid models computed with previous DEMs to the new xGEOID20 model, and with comparisons to the NGS Geoid Slope Validation Survey lines.

How to cite: Krcmaric, J.: Development and evaluation of the xGEOID20 Digital Elevation Model at NGS, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13101, https://doi.org/10.5194/egusphere-egu22-13101, 2022.

EGU22-13195 | Presentations | G4.3

4D Antarctica: recent aeromagnetic, aerogravity and satellite data compilations provide a new tool to estimate subglacial geothermal heat flux 

Fausto Ferraccioli, Ben Mather, Egidio Armadillo, Rene Forsberg, Jörg Ebbing, Jonathan Ford, Karsten Gohl, Graeme Eagles, Chris Green, Javier Fullea, Massimo Verdoya, and Juan Luis Carillo de la Cruz

Geothermal heat flux (GHF), coupled with subglacial topography and hydrology, influences the flow of the overlying Antarctic ice sheet. GHF is related to crustal and lithospheric structure and composition and tectonothermal evolution, and is also modulated by subglacial sedimentary basins and bedrock morphology. Despite its importance for both solid earth and cryosphere studies, our knowledge of Antarctic GHF heterogeneity remains limited compared to other continents- especially at regional scale. This is due to the paucity of direct measurements and the spatial gap wrt much larger scale geophysical proxies for GHF, based on continental-scale magnetic and seismological predictions that also differ considerably from each other in several regions. To reduce this major knowledge gap, the international community is increasingly active in analysing geophysical, geological and glaciological datasets to help constrain GHF (e.g. Burton-Johnson et al., SCAR-SERCE White Paper, 2020). Here we focus on 4D Antarctica- an ESA project that aims to help link bedrock, crust, lithosphere and GHF studies, by analysing recent airborne and satellite-derived potential field datasets. 

We present our recent aeromagnetic, aerogravity and satellite data compilations for 5 study regions, including the Amundsen Sea Embayment sector of the West Antarctic Ice Sheet (e.g. Dziadek et al., 2021- Communications Earth & Environment) and the Wilkes Subglacial Basin (WSB), the Recovery glacier catchment, the South Pole and Gamburtsev Subglacial Mountains and East Antarctic Rift region. We apply Curie Depth Point (CDP) estimation on existing aeromagnetic datasets and compilations in our study regions conformed with SWARM satellite magnetic data (Ebbing et al., 2021- Scientific Reports). We tested the application of different methods, including the centroid (e.g. Martos et al., 2017, GRL) and Bayesian inversion approaches of Curie depth and uncertainty (e.g. Mather and Fullea, 2019- Solid Earth) and defractal and geostatistical methods (e.g. Carrillo-de la Cruz et al., 2021- Geothermics). We then compare our CDP results with crust and lithosphere thickness and interpretations of crustal and lithospheric setting.

Using our new aeromagnetic interpretations we define Precambrian and early Paleozoic subglacial basement in East Antarctica that is mostly concealed beneath Phanerozoic sedimentary basins and ice sheet cover. This enables us to discuss whether different basement provinces differ in terms of CDP estimates (as expected), or if these are either not or only partially resolved. A particularly informative case is the WSB. Here our magnetic assessments of GHF heterogeneity for the Terre Adelie Craton, Wilkes Terrane and Ross Orogen can be indirectly tested by exploiting independent geological and geophysical information derived from their Australians correlatives, namely the Gawler and Curnamona cratons and the Delamerian Orogen. 

Our Curie depth estimates yield geologically reasonable thermal boundary conditions required to initialise new thermal modelling efforts in several study areas. However, developing 3D models of crust and lithosphere thickness and intracrustal composition (as a proxy for the ranges of radiogenic heat production and thermal conductivity) with reasonably detailed crustal architecture, derived from both potential field and seismological datasets is a key next step to constrain Antarctic geothermal heat flux heterogeneity at higher-resolution ice stream scale.  

How to cite: Ferraccioli, F., Mather, B., Armadillo, E., Forsberg, R., Ebbing, J., Ford, J., Gohl, K., Eagles, G., Green, C., Fullea, J., Verdoya, M., and Carillo de la Cruz, J. L.: 4D Antarctica: recent aeromagnetic, aerogravity and satellite data compilations provide a new tool to estimate subglacial geothermal heat flux, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13195, https://doi.org/10.5194/egusphere-egu22-13195, 2022.

EGU22-13231 | Presentations | G4.3

Geostatistical Gravity Inversion for Estimating Sub-Ice-Bathymetry 

Jonas Liebsch, Jörg Ebbing, Hannes Eisermann, and Graeme Eagles

Sub-ice-bathymetry is an important boundary condition when modelling the evolution of ice shelves and ice sheets. Radar sounding is a proven method to reveal the sub-ice-topography beneath grounded ice. However, it fails to image the bathymetry beneath the floating ice shelves due to the strong radar reflectivity of sea water. As an alternative, the inversion of gravity measurements has been used increasingly frequently in recent years. To overcome the ambiguity of inverse modelling, this method benefits from independent depth constraints derived from direct measurements distributed throughout the model area, such as by active seismic, hydroacoustic, and radar methods.

Here, we present a novel geostatistical approach to gravity inversion and compare it to the classical and more commonly used FFT approach. Instead of only fitting individual points, we also include the spatial continuity of the sub-ice morphology. To do so, we calculate a variogram that fits the available depth measurements and derive a covariance matrix from it. The covariance matrix and an initial bathymetry model obtained by kriging together describe an a-priori probability density. For the inversion, the model bathymetry is related to the measured gravity using a quasi-Newton method, for which the derived probability density serves as the inversion’s regularization term. We successfully apply the algorithm to airborne gravity data across the Ekström ice shelf (Antarctica) and compare our results with those of previous studies based on the classical approach. The simplified addition of constraints both for the geometry and the density structure in our approach proves to be advantageous.

How to cite: Liebsch, J., Ebbing, J., Eisermann, H., and Eagles, G.: Geostatistical Gravity Inversion for Estimating Sub-Ice-Bathymetry, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13231, https://doi.org/10.5194/egusphere-egu22-13231, 2022.

TS13 – Plate Tectonics and the evolution of the Earth

The Taibai granitic plutons lie between the Taibai ductile shear zone to the north and the Shangdan suture to the south. The deformation mechanism of the ductile shearing is crucial to understanding the exhumation processes of the multiple plutons after the Late Mesozoic period. Geological investigations, microstructures, and kinematic vorticity calculations (RGN and Wallis method) indicate that the Taibai shear zone deformed in response to pure shear-dominated (54–65%) transpression and top-to-NW shear sense as a result of NE-SW oblique contractional tectonics. The quartz crystallographic preferred orientations of the prism <a> slip system, the grain boundary migration, and sub-grain rotation dynamic recrystallization of quartz—combined with the plagioclase–hornblende thermometer—constrain the main deformation temperatures to a range of 400–650 °C, which suggests amphibolite to greenschist facies conditions. In addition, it is extremely likely that the mylonites experienced late-stage, lower temperature deformation as demonstrated by the sporadic bulging recrystallization, the quartz basal <a> slip system, and the two-feldspar geothermometer calculation. The samples collected from the weakly deformed mylonitic granite pluton and the undeformed quartz-feldspathic dike that intruded into the mylonites yield zircon U–Pb ages of 129 ± 1 Ma and 115 ±1 Ma, respectively. This information, with the lower intercept ages of ca. 120 Ma obtained from the mylonite samples, suggests that the ductile shearing probably occurred from ca. 129 Ma to 115 Ma. Combined with the regional geological data, these findings suggest that the Taibai shear zone and the Shangdan suture accommodated the oblique upward extrusion of the Taibai plutons during the Early Cretaceous time.

How to cite: Cheng, C., Sun, S., Dong, Y., Zhang, B., and Guo, Z.: Exhumation of plutons controlled by boundary faults: Insights from the kinematics, microfabric and geochronology of the Taibai shear zone, Qinling Orogen, China, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1053, https://doi.org/10.5194/egusphere-egu22-1053, 2022.

EGU22-1869 | Presentations | TS13.3

Juvenile source of the North Tianshan turbidites and implication for continental growth of the Central Asian Orogenic Belt 

Meng Wang, Ming Cao, Youxin Chen, Jinjiang Zhang, Xianzhi Pei, and Hai Zhou

The Central Asian Orogenic Belt (CAOB), also known as the Altaids, is one of the world's largest accretionary orogen and it is estimated that ca. 50% of the present crust in Central Asia is juvenile. However, some researchers argued that the amount of continental growth in the CAOB was overestimated. One evidence is that many intra-arc sediments and accretionary wedges in the CAOB contain heterogeneous sources (large proportion of detritus from basement rocks), and no examples from the CAOB where the sediment mainly derived from erosion of juvenile crust has been reported. Here, we conducted geochemistry and Nd isotope study on the turbidites from the North Tianshan Accretionary Complex (NTAC) in the Chinese West Tianshan orogen, which might be an good example of sediment derived from juvenile materials. The turbiditess in the NTAC are mainly composed of fine-grained sandstone, siltstone and argillaceous siliceous rocks. In the southern part near the North Tianshan Fault, the turbidites were deformed and metamorphosed into slate. Geochemically, all the collected rocks (sandstoen/siltstone and slates) have relatively low CIA (Chemical Index of Alteration) values (35 to 63) and PIA (plagioclase index of alteration ) values (34 to 68), indicating that their source rocks experienced relatively weak weathering before erosion and deposition. Both the sandstone/siltstone and slate samples display high ICV (Index of Compositional Variability) values of 0.89 to 1.50 and 0.89 to 0.93, higher than the PAAS, suggesting a relatively immature source. Based on geochemical data, it is suggested that the sandstone/siltstone were mainly derived from intermediate and felsic igneous rocks, while the slates were mainly derived from felsic igneous rocks, and their source rocks were most likely formed in oceanic/continental arc settings. Most of the samples from the NTAC display high positive εNd(t) values (+5.5 to +7.9) with only one exception of +0.8, and the Nd model ages (cluster between 672 Ma and 522 Ma, with one exception of 1.1 Ga) are only slightly older than their depositional age (Carboniferous). Our previous study has revealed that the detrital zircons from the turbidites display unimodal age patterns with peaks at 320 to 310 Ma, and have high positive εHf(t) values (+2.9 to +15.8, mostly greater than +10). These results indicate that the turbidites in the NTAC were mainly derived from intermediate to felsic igneous rocks with juvenile arc signature. The northern Chinese West Tianshan is a typical site with significant Phanerozoic continental growth, and the mechanism needs further study.

How to cite: Wang, M., Cao, M., Chen, Y., Zhang, J., Pei, X., and Zhou, H.: Juvenile source of the North Tianshan turbidites and implication for continental growth of the Central Asian Orogenic Belt, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1869, https://doi.org/10.5194/egusphere-egu22-1869, 2022.

EGU22-2045 | Presentations | TS13.3

Structures and geodynamics of the Mongolian tract of the Central AsianOrogenic Belt constrained by potential field analyses 

Alexandra Guy, Karel Schulmann, Igor Soejono, Nils Holzrichter, Ondrej Lexa, and Marc Munschy

A multidisciplinary approach integrating potential field analysis with geological and geochemical data provides new insights into the understanding of the crustal structure and evolution of the Mongolian collage. Magnetic and gravity data demonstrate the inconsistency between the geologically defined terranes and the geophysical domains in the southwestern part of the Mongolian collage. The combination of potential field analysis and modelling with whole rock geochemistry and isotopic mapping of Carboniferous–Permian granitoids indicates the presence of a homogeneous lower crust composed of a felsic to intermediate juvenile material beneath geophysically heterogeneous upper crust. This feature is interpreted as a result of a trench-directed lower crustal emplacement of an arc type crust underplating deformed Paleozoic oceanic crust. The potential field data also confirmed the occurrence of two orthogonal late Devonian and Permian–Triassic deformation upper crustal fabrics at the scale of the southwestern Mongolian collage. The prominent magnetic highs correspond to the tectono-metamorphic domains and magmatic provinces. The gravity anomalies highlight a periodicity of the signal correlating with alternating Permian–Triassic high and low strain zones, forming a zone of major deformation wrapping around the hinge of Mongolian orocline. The geometry and kinematics of dextral and sinistral transpressive faults are explained to result from the reactivation of Permian–Triassic deformation zones in the Cenozoic stress field.

How to cite: Guy, A., Schulmann, K., Soejono, I., Holzrichter, N., Lexa, O., and Munschy, M.: Structures and geodynamics of the Mongolian tract of the Central AsianOrogenic Belt constrained by potential field analyses, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2045, https://doi.org/10.5194/egusphere-egu22-2045, 2022.

EGU22-2390 | Presentations | TS13.3

PTt history from kyanite-sillimanite migmatites and garnet-staurolite schists from the Bayankhongor area, Mongolia indicates suprasubduction switching from extension to compression during Rodinia assembly 

Pavla Štípská, Vít Peřestý, Igor Soejono, Karel Schulmann, Andrew R. C. Kylander Clark, Carmen Aguilar, Martin Racek, Nikol Novotná, Pavel Hanžl, and Ondrej Lexa

The tectonometamorphic evolution of the peri-Siberian tract of the Central Asian Orogenic Belt is mainly characterized by Baikalian Late Proterozoic – Early Cambrian cycle related to amalgamation of Proterozoic oceanic and continent fragments to Siberain landmass.  Here we present in-situ monazite geochronology linked to P−T modelling of micashischsts and migmatite gneisses at the northern part of the Precambrian Baydrag block (central Mongolia) previously considered as a part of Baikalian metamorphic belt. Garnet-sillimanite-kyanite gneiss records first burial to the sillimanite stability at ~725 °C and 6.5 kbar, followed by burial to the kyanite stability at ~650 °C and ~8 kbar. The garnet-staurolite schist records burial to the staurolite-stability at ~620 °C and 6 kbar, followed by a nearly isothermal burial to ~580 °C and 9 kbar. The monazite data yield a continuum of 207Pb-corrected 238U/206Pb dates of c. 926−768 Ma in the Grt−Sil−Ky gneiss, and c. 937−754 Ma in the Grt-St schist. Based on monazite textural positon and internal zoning, the time of prograde burial and peak under a thermal gradient of 28–32 °C/km is estimated at c. 870−890 Ma. It is not clear whether such high grade conditions prevailed until a phase of further burial under a geothermal gradient of 18–22 °C/km and dated at 800−820 Ma.  Additionally, monazite with dates of c. 568−515 Ma occurs as whole grains or as rims with sharp boundaries on Grenvillean monazite in Grt-St schist testifying for minor Baikalian overprint. Metamorphic zircon rims with Th/U ratio ~0.01–0.06 in Grt−Sil−Ky gneiss with 877 ± 7 Ma age, together with lower intercepts of zircon discordia lines in both Grt-Sil-Ky gneiss and Grt-St schist further support the Tonian age of high grade metamorphism. The P−T and geochronology data show anticlockwise P−T evolution from c. 930 to 750 Ma which is interpreted as a result of thickening of supra-subduction extensional and hot edifice – probably of back arc or arc type. This kind of prograde metamorphism was so far described only on the northern part of the Tarim block and interpreted as a result of initiation of peri-Rodinian subduction of Mirovoi Ocean. Here, we further discuss geodynamic consequences of a unique discovery of Tonian metamorphism in term of tectonic switch related to initiation of peri-Rodinian oceanic subduction during supercontinent assembly followed by strong mechanical coupling potentially related to onset of Rodinia splitting.

How to cite: Štípská, P., Peřestý, V., Soejono, I., Schulmann, K., Kylander Clark, A. R. C., Aguilar, C., Racek, M., Novotná, N., Hanžl, P., and Lexa, O.: PTt history from kyanite-sillimanite migmatites and garnet-staurolite schists from the Bayankhongor area, Mongolia indicates suprasubduction switching from extension to compression during Rodinia assembly, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2390, https://doi.org/10.5194/egusphere-egu22-2390, 2022.

EGU22-2483 | Presentations | TS13.3

The Cambrian volcanic arc terrane: a peri-East European Craton assemblage in the heart of the European Variscan Belt 

Stephen Collett, Karel Schulmann, Stanisław Mazur, Anne-Sophie Tabaud, and Igor Soejono

Cambrian age volcanic arc-related rocks crop-out in high-grade metamorphic complexes marking the principal Devonian age suture zone in the Bohemian Massif. The age and tectonic setting of these rocks are established from whole-rock geochemical and isotopic data from basic-intermediate rocks transformed to eclogite and granulite, and U-Pb and Lu-Hf isotopic data of detrital zircon in associated meta-sediments. Recent works have established that these rocks can be correlated on the basis of their age and tectonic setting as well as their Variscan metamorphic evolution with allochthonous complexes in NW Iberia, and potentially, the whole European Variscan Belt (Martínez Catalán et al., 2020). Detrital zircon spectra from the high-grade metasediments associated with the Cambrian volcanic arc are superficially similar to the classically interpreted ‘West African signature’ with Neoarchean, Paleoproterozoic and late Neoproterozoic maxima. Nonetheless, limited Cryogenian input and shifting of the late Neoproterozoic maxima into the early Cambrian is in contrast to Variscan autochthonous complexes. Moreover, Lu-Hf isotopic data show important contrasts in the source of the Paleoproterozoic detritus. The Variscan autochthon is charecterised by Paleoproterozoic detritus with negative ɛHfi values indicating reworking of an Archean crust. However, the Paleoproterozoic detritus in the Cambrian arc terrane exhibits mostly positive ɛHfi values indicating a juvenile Paleoproterozoic source.

In fact, the data from the Cambrian arc terrane show remarkable similarity to detrital zircon data from early Cambrian sediments on the southern margin of the East European Craton (Paszkowski et al., 2021). These sediments incorporate significant juvenile late Neoproterozoic-early Cambrian detritus from an as yet unidentified volcanic arc and their whole-rock geochemical composition is consistent with immature sediments sourced from intermediate igneous rocks. If true, this correlation suggests that the Cambrian arc terrane is a peri-East European Craton assemblage and necessitates a re-evaluation of the role of the East European Craton within the Variscan Orogeny.

Catalán, J. R. M., Collett, S., Schulmann, K., Aleksandrowski, P., and Mazur, S., 2020. Correlation of allochthonous terranes and major tectonostratigraphic domains between NW Iberia and the Bohemian Massif, European Variscan belt. International Journal of Earth Sciences, 109, 1105-1131.

Paszkowski, M., Budzyń, B., Mazur, S., Sláma, J., Środoń, J., Millar, I.L., Shumlyanskyy, L., Kędzior, A. and Liivamägi, S., 2021. Detrital zircon U-Pb and Hf constraints on provenance and timing of deposition of the Mesoproterozoic to Cambrian sedimentary cover of the East European Craton, part II: Ukraine. Precambrian Research, 362, 106282.

How to cite: Collett, S., Schulmann, K., Mazur, S., Tabaud, A.-S., and Soejono, I.: The Cambrian volcanic arc terrane: a peri-East European Craton assemblage in the heart of the European Variscan Belt, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2483, https://doi.org/10.5194/egusphere-egu22-2483, 2022.

EGU22-3990 | Presentations | TS13.3

Zircon provenance analysis of the local extensional basins of the Sudetian orogen in the East Ural zone 

Alexander Tevelev, Alexandra Borisenko, Ivan Sobolev, Alexey Kazansky, Natalia Pravikova, Egor Koptev, Jiri Žák, and Vasiliy Chervyakovskiy

Introduction. Two structural zones are traditionally distinguished in the Eastern Urals. They are the Magnitogorsk zone and the East Ural zone, which are divided by a narrow suture. The Early Sudetian (Visean) orogenic phase is marked by a structural unconformity in the base of Upper Visean terrigenous-carbonate sequence both in the suture zone and the East Ural zone. According to drilling data granitic-pebble-bearing conglomerates are present at the base of this sequence. The Sudetian rearrangement is implied in the Magnitogorsk zone by the end of rifting and the initiation of carbonate deposition.

The Pre-Sudetian basement of the East Ural zone is comprised of the Lower Paleozoic deformed metamorphic rocks (gneisses, schists and carbonaceous quartzites), clastic deposits of the Ordovician (wackes and meta-arkoses) and the Lower Carboniferous (greywackes), as well as the volcanic rocks of the Tournasian-Early Visean and the granitoids of the Neplyuevka complex, dated 355-340 Ma. The Pre-Sudetian basement of the Magnitogorsk zone is represented by igneous complexes of the Devonian – Early Carboniferous age.

This research aims to determine the source areas and migration paths of the sediments for local basins associated with the Sudetian orogenic phase. The basins at the conjunction of the two megazones could derive clastic material from both.

Materials and methods. The specimens were collected from quarries near the Novinka village where sandstones of the terrigenous-carbonate succession are exposed. The sandstones are commonly cross-bedded, medium to coarse-grained, have sub-arkose, arkose, greywacke or, sometimes, quartz-arenitic composition. 210 zircon grains were extracted from two samples. 99 zircon grains characterized by discordancy no more than 5% have been chosen for the evaluation of age distribution parameters.

Results and discussion. The dating results appeared to be unexpected. Firstly, no single analysis yielded a Devonian isotope age, and only a single grain yielded the Tournaisian isotope age. Secondly, the vast majority of the zircon grains appeared to have the Cambrian and Ordovician isotope ages, with the main peak corresponding to the beginning of the Ordovician (480 Ma) and secondary ones corresponding to the beginning of the Late Ordovician (450-460 Ma), the Middle Cambrian (510-520 Ma) and the Early Cambrian (530-540 Ma).

So, the Magnitogorsk zone could not house the zircone source area for the local basin associated with the Sudetian orogenic phase. The clastic material could only be derived from the East Ural zone. However, the study area does not contain any known igneous complexes with suitable ages. The local source areas of detrital zircons are, in fact, associated with the scarps of metamorphic complexes of the East Ural zone, which host the zircons with the isotope ages of 478±5 Ma and 529±6 Ma.

Financial support. The research has been funded by RFBR and CNF as a part of the research project № 19-55-26009. The U-Pb dating of the zircon is executed as a part of the research project № АААА-А18-118053090045-8 of State task of IGG UB RAS. Centre of collective usage ‘Geoportal’,  Lomonosov Moscow State University (MSU), provided access to remote sensing data.

How to cite: Tevelev, A., Borisenko, A., Sobolev, I., Kazansky, A., Pravikova, N., Koptev, E., Žák, J., and Chervyakovskiy, V.: Zircon provenance analysis of the local extensional basins of the Sudetian orogen in the East Ural zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3990, https://doi.org/10.5194/egusphere-egu22-3990, 2022.

EGU22-4058 | Presentations | TS13.3

The first results of U-Pb dating of the granitoids of the Neplyuevka pluton(The Southern Urals) 

Alexandra Borisenko, Alexander Tevelev, Ivan Sobolev, Natalia Pravikova, Alexey Kazansky, Egor Koptev, Irina Kosheleva, and Jiri Zak

Introduction. The Neplyuevka pluton is situated in the Chelyabinsk region of the Southern Urals, in the western part of the Eastern Uralian megazone. The area of pluton is 20×14 km. The Neplyuevka intrusion is comprised of 4 phases: 1) gabbro and diorites, 2) quartz diorites and granodiorites, 3) adamellites, 4) leukogranites. The granitoids intrude the terrigenous rocks of the Lower Ordovician. The overlying terrigenous deposits of the Upper Visean contain granitic lithoclasts. The isotope Rb-Sr ages of the rocks comprising the Neplyuevka pluton lie in the range of 346-340 Ma. The variations in the isotopic ages are consistent with the order of individual phases: 346 Ma for the 2nd phase, 342 for the 3rd phase and 340 for the 4th phase. So, according to the isotope ages, the evolution of the pluton took at least 6 Ma. The pluton also contains Cisuralian leucogranites (278 Ma).

Materials and methods. We have studied the zircon grains extracted from 4 specimens: 1 – granodiorites of the 2nd phase, 2 and 3 – adamellites from the 3rd phase, 4th – leucogranites of the 4th phase. The specimens themselves have been collected from the exact locations and the same rock types as previous sampling for Rb-Sr isotope dating. We have studied the morphology of the grains and their internal structure using cathodoluminescence imaging. The U-Pb dating was performed at the Russian Geological Research Institute (VSEGEI) using SHRIMP-II.

Results and discussion. The zircon grains from the granodiorites and adamellites are represented by transparent and light-yellow, idiomorphic, bipyramidal-prismatic crystals, 200-600 μm in length. The crystals are characterized by medium intensity of luminosity with apparent medium-contrast coarse and fine oscillatory zonation. By their obtained isotopic ages the zircons can be divided into 2 populations 1) 334-342 Ma and 2) 354-356 Ma. The isotopic ages of the 1st population are close to those obtained by Rb-Sr dating.

The formation of the Neplyuevka complex in the beginning of the Carboniferous signifies an important event in the geodynamic evolution of the Southern Urals – the fast transition from island arc magmatism, which continued during the whole Devonian, to the rift magmatism, which ceased only in the middle of the Visean. The termination of island arc magmatism is usually explained by the slab delamination at the Devonian-Carboniferous boundary, while the initiation of the rifting is attributed to the oblique collision between the Paleo-Ural island arc with the Laurussia in the middle of the Tournaisian. The obtained data allows us to reevaluate the age of the rifting initiation, assigning it to the Devonian-Carboniferous boundary.

Financial support. The research has been funded by RFBR and CNF as a part of the research project № 19-55-26009. Interpretation of U-Pb data was carried out within the framework of the government assignment of IGEM RAS.

How to cite: Borisenko, A., Tevelev, A., Sobolev, I., Pravikova, N., Kazansky, A., Koptev, E., Kosheleva, I., and Zak, J.: The first results of U-Pb dating of the granitoids of the Neplyuevka pluton(The Southern Urals), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4058, https://doi.org/10.5194/egusphere-egu22-4058, 2022.

EGU22-4701 | Presentations | TS13.3

Paleozoic geodynamics and architecture of the Mongolian Altai Zone 

Turbold Sukhbaatar, Ondrej Lexa, Karel Schulmann, Carmen Aguilar, Pavla Štípská, Jean Wong, Yingde Jiang, Jitka Míková, and Dingyi Zhao

The Mongolian Altai Zone is a part of the extensive Cambrian–Ordovician accretionary system located at the junction of the Siberian craton to the north and Tarim and North China cratons to the south. It extends approximately 2,000 km from Russia to Mongolia and represents one of the critical elements for reconstructing the early Paleozoic geodynamics of the Central Asian Orogenic Belt (CAOB). The studied section comprises a succession of deformed low- and high-grade metasedimentary rocks characterised by dominant terrigenous components mixed with volcanogenic material. The detrital zircons analysis revealed two separate groups a) more mature siliciclastic sediments (mostly sandstones) with maximum depositional age of Cambrian–Ordovician (ca. 463–489 Ma; zircon U-Pb) and b) more juvenile greywacke type sediments with Ordovician–Silurian (ca. 438–446 Ma; zircon U-Pb) maximum depositional age. U-Pb ages of detrital zircons show Cambrian-Ordovician (εHf(t) values –24.8 to +16.0) and Late Archean to Neoproterozoic source (εHf(t) values –35.5 to +10.4) and are interpreted as derived from the Ikh Mongol continental arc and the Baydrag continent. The greywackes, in addition, contain Silurian detrital zircons, with εHf(t) values from –0.5 to +13, suggesting syn-depositional contribution of juvenile material from a nearby magmatic arc. Both types of sediments are affected by Devonian (ca. 369–382 Ma; zircon U-Pb) metamorphism and magmatism granites, as well as stroingly reworked during the Permian (ca. 271–296; zircon U-Pb) under various metamorphic conditions. Late Devonian granitoids associated with felsic migmatites, and their zircon εHf(t) values from –9.5 to +13.5, indicate extensive melting of the sedimentary pile. A Permian high-temperature metamorphism is associated with granodiorite intrusions (εHf(t) values from –22.0 to +12.6) that contain Devonian zircon xenocrysts, suggesting melting of a Devonian source. The tectonic evolution of the Mongolian Altai Zone can be discretized in four events from which the first two were related to early Paleozoic metamorphic and magmatic evolution. The third one is associated with crustal-scale detachment that exhumed the early Permian migmatite-magmatite core complex in the south. The whole edifice was later affected by significant Permian-Triassic horizontal N-S shortening leading to juxtaposition of contrasting crustal levels thereby forming “apparent” terrane structure of the Mongolian Altai Zone. The whole edifice is interpreted as a Cambrian to Silurian fore-arc, affected by Devonian syn-extensional deep crustal melting. In addition,the Permian anatectic zone is interpreted as a deep part of an inverted continental rift.

How to cite: Sukhbaatar, T., Lexa, O., Schulmann, K., Aguilar, C., Štípská, P., Wong, J., Jiang, Y., Míková, J., and Zhao, D.: Paleozoic geodynamics and architecture of the Mongolian Altai Zone, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4701, https://doi.org/10.5194/egusphere-egu22-4701, 2022.

EGU22-4984 | Presentations | TS13.3

Ordovician geodynamics of the Sardinia block: a key for the reconstruction of the pre-Variscan paleogeography 

Fabrizio Cocco, Alfredo Loi, and Antonio Funedda

The crystalline basement of the Sardinia block is made up of an almost complete segment of the Variscan belt. Along a SW-NE transect of roughly 200 km, it is possible to observe the structure of the chain from the shallowest to the deepest domains, starting from an anchimetamorphic external zone in the SW of the Island, to a green-schist facies nappe zone in the center and to a medium to high-grade metamorphic inner zone in northern Sardinia. The exceptional exposure of the chain in Sardinia makes it an essential piece for the reconstruction of the pre-Variscan geodynamics and the Paleozoic terranes puzzle.

In several reconstruction of the pre-Variscan paleogeography, Sardinia is considered a whole single block that experienced, since Cambrian times, several geodynamic settings as part of the northern Gondwana margin, before being involved in the Variscan Orogeny during lower Carboniferous. As stated by previous Authors, the most relevant pre-Variscan geodynamic events recorded in Sardinia occurred during the Lower-Middle Ordovician, when the Sardinian block was located close to a subduction zone where a volcanic arc developed. According to this interpretation, the external, nappe and inner zones acted as back-arc, arc and fore-arc, respectively, belonging to the same lithospheric block.

The main evidences of Ordovician tectonics and volcanic activity are a folding event that affect only the Cambrian-Lower Ordovician successions and an angular unconformity related to the folds sealed by continental and tidal deposits in the external zone and by calc-alkaline volcanic products in the nappe zone.

The review of the paleontological, stratigraphic, magmatic and structural data highlights significant discrepancies between the external and nappe zones, suggesting that these domains did not share the same geodynamic setting and, possibly, paleogeographic position during the Ordovician, implying they drew close and amalgamated only in Variscan times.

This hypothesis is supported by the different ages of the unconformities, Upper Ordovician in the nappe zone and Middle Ordovician in the external zone, and the extent of the stratigraphic gap, long-lasting in the external zone. Furthermore, the activity of the volcanic arc in the nappe zone is contemporaneous to the continentalization and erosive processes in the external zone, that is totally devoid of magmatism and volcano-sedimentary deposits. The Upper Ordovician succession in the external zone define a rift that evolve to a passive margin, whereas in the nappe zone the onset of a passive margin is marked by a nonconformity above the volcanic arc. Note that also the faunas show remarkable differences between the external and nappe zones. Finally, a different paleogeographic position is suggested by the Hirnantian glaciomarine deposit in the external zone, lacking in the nappe zone.

The recognition that the Sardinian block consisted of two distinct terranes before the Variscan Orogeny, entails alternative correlations and an adjustment of the arrangement of the now scattered Variscan terranes. In particular, the external and nappe zones should be located in different positions in order to fit the proper geodynamic setting in the paleogeographic reconstruction at the snapshot time.

How to cite: Cocco, F., Loi, A., and Funedda, A.: Ordovician geodynamics of the Sardinia block: a key for the reconstruction of the pre-Variscan paleogeography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-4984, https://doi.org/10.5194/egusphere-egu22-4984, 2022.

EGU22-9227 | Presentations | TS13.3

LP-HT metamorphism in the Jebilet Massif (Moroccan variscan belt): from Paleothetys opening to Pangea formation 

Francis Chopin, Martin Simon, Karel Schulmann, Pavla Štípská, Mohamed El Houicha, Anne-Sophie Tabaud, Rémi Leprêtre, Ryma Chebli, Delphine Bosch, and Jitka Míková

In the westernmost part of the Variscan belt, petro-structural observations, mineral equilibria modelling and U-Pb age determination were carried in the Jebilet massif (Morocco), in order to precise the deformation–metamorphism of NW Africa during Late Paleozoic Variscan events. A first episode corresponds to the emplacement of the main Oulad Ouaslam intrusion at 335.2 ± 0.8 Ma (U-Pb LA-ICP MS on zircon) within a Visean intracontinental basin. A second episode correspond S to SE convergence resulting into nappe stacking and upright folding in the supracrustal level together with the progressive development of a sub-horizontal metamorphic foliation around the pre-heated pelitic country rocks of the intrusion up to the sillimanite zone. Crd-And growth during this event in metapelite indicate indicating heating and increase of pressure up to 600–625 °C and 1.6–2.0 kbar. The timing of this sequence in metapelite is constrained by the U-Pb monazite age of 323.4 ± 3.6 Ma, interpreted as minimum age of metamorphic peak conditions, ca. <15 Ma younger than the emplacement of the intrusion. This very moderate thickening is followed by WNW convergence, sub-orthogonal to the first one, affecting all the previous structures and continuing probably up to the Cisuralian, similar to neighboring massifs. The first episode coincides with emplacement of magma within Visean intracontinental basins at the western tip of the ongoing opening Palaeo-Tethys Ocean, whereas the monazite dating document for the first time the precocious onset, during Late Serpukhovian–Early Bashkirian of the convergence in the NW African Variscan segment.

How to cite: Chopin, F., Simon, M., Schulmann, K., Štípská, P., El Houicha, M., Tabaud, A.-S., Leprêtre, R., Chebli, R., Bosch, D., and Míková, J.: LP-HT metamorphism in the Jebilet Massif (Moroccan variscan belt): from Paleothetys opening to Pangea formation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9227, https://doi.org/10.5194/egusphere-egu22-9227, 2022.

EGU22-9378 | Presentations | TS13.3

Pre-Jurassic tectonic evolution of the central part of West Siberian basin: the new data from the Frolov-Krasnoleninsky region 

Anton Latyshev, Ivan Panchenko, Petr Kulikov, Maria Smirnova, Ivan Fedyukin, and Ivan Gusev

The basement of West Siberian plate has mosaic architecture and consists of the Paleozoic fold belts and supposed Precambrian massifs. The Frolov-Krasnoleninsky region is located in the central part of the West Siberian basin (near the town of Khanty-Mansiysk) and occupies the key position in its structure.  The junction of the Uralian fold belt, Kazakhstan superterrane, and Irtysh-Zaysan fold zone is located there. However, the pre-Jurassic tectonic evolution of this area is still poorly constrained. Based on the new representative data on drill cores from deep boreholes and geophysical data, whole-rock geochemistry and U-Pb ages, we reconstructed the main stages of the geological history of this area:

  • In the Neoprotertozoic the ancient metamorphic complexes of the Krasnoleninsky and Aprel’sky uplifts were formed. Based on the detrital zircons ages and correlation with similar rocks in the nearby fold belts, we suggest that this stage terminated about 600-540 Ma.
  • In the Early Paleozoic volcano-terrigenous rocks were accumulated mainly in the island arc tectonic setting. This stage ended with the emplacement of gabbro-granitic plutons, fold deformations and amalgamation of the Kazakhatan superterrane with the Krasnoleninsky block in the beginning of Silurian (446-440 Ma).
  • In the Devonian – Early Carboniferous carbonate and overlying mainly clastic sediments were accumulated. The first manifestation of supra-subduction volcanic activity and granitic intrusions are identified as Late Devonian-Early Carboniferous. At the end of Early – beginning of Middle Carboniferous fold deformations related to the closing of back-arc basin took place.
  • In the Middle – Late Carboniferous differentiated volcanic series and coeval granodiorite massifs of the continental arc tectonic setting were formed (310-307 Ma). This stage corresponds to the convergence of continental masses of Siberian and East European platforms and Kazakhstan superterrane and the closing of relic oceanic basins between them.
  • The Early-Middle Permian is a time of collision, manifested by large granitic plutons in the Krasnoleninsky uplift and other areas of the West Siberia and Uralian fold belt (290-260 Ma). At this stage, main structural features of the basement of West Siberian plate were formed.
  • In the Late Permian – Early Triassic West Siberia was an area of wide-scale rifting, caused by the post-collisional extension and the mantle plume ascent. Thick sequences of the contrasting basaltic and felsic lavas were erupted. Volcanic piles are overlain by clastic coal-bearing sediments of the Triassic and, possibly, Early Jurassic age.

How to cite: Latyshev, A., Panchenko, I., Kulikov, P., Smirnova, M., Fedyukin, I., and Gusev, I.: Pre-Jurassic tectonic evolution of the central part of West Siberian basin: the new data from the Frolov-Krasnoleninsky region, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9378, https://doi.org/10.5194/egusphere-egu22-9378, 2022.

EGU22-12505 | Presentations | TS13.3

U-Pb geochronology of granitoids from northern Morocco: a two-step tale for the evolution of the Variscan domain in NW Africa 

Rémi Leprêtre, Francis Chopin, Mohamed El Houicha, Anne Sophie Tabaud, Karel Schulmann, Jocelyn Barbarand, Jitka Míková, and Ryma Chebli

The Variscan belt in NW Africa represents an intraplate orogen, which mainly developed from Late Carboniferous (ca. from the Bashkirian: 323–315 Ma) to the end of Cisuralian (283–273 Ma), in response to the closure of an oceanic domain between NW Gondwana and Laurentia. The orogenic events were accompanied by an important magmatic activity, distributed across the whole northern Morocco, north of the South Meseta Fault Zone which separates the Meseta domain in the north from the Anti-Atlas domain to the south, where no magmatic activity was recorded at that time. Moreover, an older magmatic phase occurred during the Late Devonian-Early Carboniferous however the associated geodynamic context remains under debate.

In northern Morocco, existing geochronological results for these magmatic activities are mainly obtained using Rb-Sr methods (whole rock or on different minerals). However, recent U-Pb datings on different massifs in Morocco have revealed older ages. Therefore, Rb-Sr ages should be considered with caution.

In this contribution, we present new U-Pb geochronological data (LA-ICP MS on zircons) for several plutonic massifs of northern Morocco from the Western (Jebilet) and Eastern Meseta. In the later, we provide new datings on 3 magmatic facies in the High Moulouya massif, but also for the Boudoufoud, Beni Snassen, Tanncherfi, Zekkara and Merguechoum massifs. These new data reinforce the idea that two main magmatic events must be properly separated in northern Morocco. First, a clear Early Carboniferous event, possibly beginning as soon as the end of Late Devonian, is recorded within both Western and Eastern Meseta, and this magmatic event ends at around 330 Ma. Afterwards, from ca. 310–305 Ma to ca.280–275 Ma, the second magmatic event is also expressed across both Western and Eastern Meseta. While this second magmatic event is clearly related to the Variscan orogenic events, the unclear geodynamic context for our new Early Carboniferous ages allows the re-opening of the discussion about the « Eovariscan » phase in NW Africa. Finally, these two magmatic phases are compared to the magmatic records from West Europe Variscan belt.

How to cite: Leprêtre, R., Chopin, F., El Houicha, M., Tabaud, A. S., Schulmann, K., Barbarand, J., Míková, J., and Chebli, R.: U-Pb geochronology of granitoids from northern Morocco: a two-step tale for the evolution of the Variscan domain in NW Africa, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12505, https://doi.org/10.5194/egusphere-egu22-12505, 2022.

EGU22-540 | Presentations | GD7.2

3D Modeling of Crust-Mantle Dynamics on Cratonic Regions: Implications for the Deformation of North China Craton 

Açelya Ballı, Oğuz Göğüş, and Jeroen van Hunen

A number of geological, geochemical and seismological studies suggest that cratonic lithospheres may be associated with thinning and destruction. For such unique plate configurations, the most well-known example is the North China craton. Geological studies suggest that during the Mesozoic era (120-80 Ma), a surge of magmatism occurred across the North China Craton as a response to the removal of the portions of the lithosphere beneath it. However, the question of which processes control lithospheric thinning/removal is yet to be understood. The one that is the subject of this study is the deformation controlled by gravitational instabilities (convective removal), that develop because of density variations between the lithosphere and the underlying sub-lithospheric (asthenospheric) mantle.

In accordance with numerical model predictions conceptual geological hypotheses are inferred to invoke the phase transitions in the lower crust and densification of this layer through the transformation of the basalt to eclogite during late Jurassic where Pacific flat-slab subduction led to shortening in the continental back arc (e.g Andean type tectonics). The removal event possibly occurred following the plate shortening during Early Cretaceous and various surface geological features, for instance, normal faulting/extension and pull apart basins and are interpreted in the context of coupled crust-mantle dynamics. This research aims to facilitate new 3D modelling strategies to further explain how large-scale plate geodynamics may account for the geological-geophysical fingerprints of destruction at North China Craton. The problem of deformation of the North China Craton will be approached on a much broader aspect including the extensional events that took place in Cretaceous. The overarching goal of this work is to explain the first order geodynamic mechanism that possibly constrain the craton destructions not only under North China but also other areas where such mechanism has been postulated (e.g North America, South Africa). 

 

 

 

How to cite: Ballı, A., Göğüş, O., and van Hunen, J.: 3D Modeling of Crust-Mantle Dynamics on Cratonic Regions: Implications for the Deformation of North China Craton, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-540, https://doi.org/10.5194/egusphere-egu22-540, 2022.

Despite the influence of several extrinsic parameters that inhibits the use of trace element composition of detrital zircon grains in inferring their host rocks, workers had overcome many related problems and particularly constrained zircon/bulk rock partition co-efficient at least for different granitoids, for example. Based on these kind of progress and few other fundamental works, we have tried to apply trace element composition of detrital zircon grains retrieved from some basal quartz pebble conglomerate units and orthoquartzites of Dharwar craton in studying the crustal evolution pattern of this craton, specifically in terms of its changing crustal thickness with time. In this study, after categorising the pristine zircon grains identified by their La>1, Pr>1 and LREE-I<30 values, the values of their LREE/HREE ratio (measured by their Lu/Nd ratio) are used to infer the temporal variation of crustal thickness within this craton. Here, the zircon grains show depressed values of LREE/HREE ratio manifested in their higher Lu/Nd ratio which possibly attests the absence of thicker continental crust in Dharwar craton between 3.4-3.1 Ga. We would also try to establish our observation regarding the secular evolution of crustal thickness of Dharwar craton with the help of other bivariate plots using the other trace elemental proxies. Our result stand in contradiction with the finding of other workers who, with the help of geophysical parameters, inferred the greater thickness of continental crust attested in WDC within the said time frame  

How to cite: Mitra, A. and Dey, S.: Tale of crustal evolution of western Dharwar craton in Paleo-to- Meso Archean time: Insights from trace elemental composition of detrital zircons of some selected quartzite units., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-609, https://doi.org/10.5194/egusphere-egu22-609, 2022.

EGU22-2524 | Presentations | GD7.2

Evidence for a ca 1.86 Ga continental margin in the Baltic Sea region: rock chemistry, U-Pb ages, and Nd and Sr isotopic data 

Grazina Skridlaite, Laurynas Siliauskas, Martin Whitehouse, Åke Johansson, and Andrius Rimsa

The concealed basement of the Mid-Lithuanian domain (MLD) is considered to be part of a larger Precambrian unit within the western East European Craton (EEC), the Mid-Baltic belt (MBB), established by Bogdanova et al. (2015). New data on rock chemistry, U-Pb ages, and the Sm-Nd and Rb-Sr isotopic systems allow to subdivide the MLD into distinct parts, discuss their origin and correlate them with similar units on the Swedish side.

The MLD can be subdivided into two parts: NW and SE. The NW MLD magmatic rocks crystallized from 1.86 to 1.83 Ga and were subsequently intruded by 1.81-1.80 Ga granitoids and charnockitoids. The NW MLD samples have SiO2 contents between 48 and 71 wt.% but have similar initial εNd values at -1 to -2, while their initial Sr isotope ratios scatter. Nd isotope data suggest either an enriched mantle source, or a mantle magma that was mixed with older crustal material.

The SE MLD magmatic rocks originated from a slightly depleted mantle source from 1.87 to 1.82 Ga. At 1792±9 Ma, they were intruded by gabbronorites which in turn were crosscut by thin veinlets of microgabbronorite at 1758±11 Ma. The SE MLD rocks have positive εNd (+1 to +3) and undisturbed Rb/Sr systems suggesting mantle-derivation, with the variation in composition (mafic to felsic) due to fractionation rather than crustal contributions.

The SE MLD magmatic series with oceanic island arc affinity correlate well with the ca 1.85 Ga Fröderyd metavolcanics of the Vetlanda-Oskarshamn belt (Salin et al., 2021) in SE Sweden, while the NW MLD rocks are similar to the TIB-0 (1.86-1.85 Ga) Askersund granitoids (cf. Salin et al., 2021) in the southern Bergslagen area. The younger (1.81-1.79 Ga) intrusives in both areas are time-equivalents of the TIB-1 magmatism on the Swedish side. Thus, the MLD as well as its counterparts on the Swedish side of the Baltic Sea, the TIB-0 magmatism in the southern Bergslagen area and the Vetlanda-Oskarshamn belt, may be assigned to the same Mid-Baltic Belt, representing an active, south-facing continental margin established at ca. 1.86 Ga. The shape and outline of the Belt was affected by the Fennoscandia-Sarmatia collision at ca. 1.82-1.80 Ga, the 1.81-1.76 Ga TIB-1 magmatism, as well as by later Mesoproterozoic intraplate magmatism.

Bogdanova, S. et al., 2015. Precambrian Research 259, 5–33.

Salin, E. et al., 2019. Precambrian Research 328, 287–308.

Salin, E. et al., 2021. Precambrian Research 356, 106134

How to cite: Skridlaite, G., Siliauskas, L., Whitehouse, M., Johansson, Å., and Rimsa, A.: Evidence for a ca 1.86 Ga continental margin in the Baltic Sea region: rock chemistry, U-Pb ages, and Nd and Sr isotopic data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2524, https://doi.org/10.5194/egusphere-egu22-2524, 2022.

Deep-seated upwellings within the Earth’s mantle, also known as mantle plumes, affect the Earth’s surface by inducing (large-scale) volcanism, initiating continental breakup and increasing surface heat flow. Plume-lithosphere interaction may also generate lithospheric erosion at the base of the tectonic plates. It is therefore important to understand the past positions and movements of mantle plumes relative to the surface plates. However, while hotspot tracks beneath thin oceanic lithosphere are visible as volcanic island chains, the plume-lithosphere interaction for thick continental or cratonic lithosphere often remains hidden due to the lack of volcanism.

To identify plume tracks with missing volcanism, we characterize the relationship and timing between plume-lithosphere interaction and associated surface heat flux anomalies by using numerical models of mantle convection. Our results indicate a relation between lithospheric thinning and surface heat flux anomaly, which is independent of geometry and can be approximated analytically. We have confirmed this close link between basal erosion of the lithosphere and surface heat flux anomaly using an analytical expression form the time-dependence of heat transmission through convectively thinned lithosphere. Anomaly amplitudes primarily depend on the viscosity structure of the lower lithosphere and the asthenosphere, with a minor dependence on plume temperature. Lithospheric thinning is strongest around the time the plate is above the plume conduit, while the maximum heat flux anomaly occurs about 40-140 Myr later. Therefore, continental and cratonic plume tracks can be identified by lithospheric thinning, even if they lack extrusive and intrusive magmatism, followed by elevated surface heat flux several 10s of Myr later. This has important implications, especially for arctic settings such as Greenland or Antarctica, as ice melting rates might be affected by elevated heat flow long after the plume passage.

How to cite: Heyn, B. and Conrad, C.: Basal erosion and surface heat flux anomalies associated with plume-lithosphere interaction beneath continents, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2631, https://doi.org/10.5194/egusphere-egu22-2631, 2022.

EGU22-2977 | Presentations | GD7.2

Imaging the full extent of the Australian cratonic lithosphere using waveform tomography with massive datasets. 

Janneke de Laat, Sergei Lebedev, Bruna Chagas de Melo, Nicolas Celli, and Raffaele Bonadio

Australia has a long a complex geological history, spanning from the early Archean to the present day. Tomographic models can help us better understand the evolution of Australia by imaging the seismic structure of the crust and underlying mantle. We present a new S-wave tomographic model, Aus22, computed using a very large dataset of 0.9 million seismograms. The dataset includes all publicly available broadband data and yields the densest possible coverage across the hemisphere centred at the Australian continent, with sparser coverage elsewhere. Aus22 is computed using a three-step inversion procedure: 1. waveform inversion, 2. tomographic inversion and 3. outlier analysis. The model is validated by resolution tests and, for particular locations with notable differences with previous models, by independent inter-station measurements of surface-wave phase velocities. The new tomography resolves the structure of the Australian Plate and its boundaries in great detail. Cratonic lithosphere underlies nearly all of western and central Australia and shows substantial lateral heterogeneity. The highest seismic velocities are observed in the central-west portion of the continent, including the West and South Australian Craton. The North Australian Craton can be distinguished by a slightly lower seismic velocity, especially in its southern part. The cratonic lithosphere below the North Australian Craton extends northwards offshore through the Gulf of Carpentaria and the Arufa and Timor Sea and terminates at the southern Banda Arc and the New Guinea Fold-and-Thrust Belt, marking the northern boundary of the Australian Plate. The eastern boundary of the cratonic lithosphere is close, in most places, to the geologically defined Tasman Line and provides a new, deep-lithospheric definition of this line. East of this boundary, the lithosphere transitions to thin, warm lithosphere underlying the volcanically active east of the continent. This transition is sharp in the north, where it is located just west of the Georgetown Inlier, whereas an area of moderately thick, transitional lithosphere is present in the south-central part of the continent.

How to cite: de Laat, J., Lebedev, S., Chagas de Melo, B., Celli, N., and Bonadio, R.: Imaging the full extent of the Australian cratonic lithosphere using waveform tomography with massive datasets., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2977, https://doi.org/10.5194/egusphere-egu22-2977, 2022.

South African lithosphere is a mosaic of the best-preserved and exposed crustal blocks, assembled in the early to late Archean and then modified by a series of major tectono-thermal events, both of Precambrian and Phanerozoic age. Understanding the thermal and compositional structure of the South African lithosphere provides crucial information for the causes and processes of lithospheric stability and modification.

The lithosphere's effective elastic thickness (Te) is a proxy for mechanical strength that can be used to constrain lithospheric rheology and better understand how surface deformation affects deep Earth processes.

In this study, we calculate the admittance and coherence for southern Africa using topography and Bouguer gravity data from the GOCE satellite dataset. The admittance and coherence are then jointly inverted to estimate the spatial variations in southern African elastic thickness, by applying a wavelet transform in a probabilistic Bayesian framework.

Unlike other Cratonic regions, the low effective elastic thickness values and the shallow Curie depth estimated along the Kaapvaal Craton, demonstrate that lithospheric strength is influenced by regional thermo-chemical mantle upwelling dominated by composition, rather than just the continental geothermal state.

The lateral heterogeneity of Te across the Kaapvaal craton indicates that the Kaapvaal may not be a uniformly rigid craton and the modification is related to metasomatism and plume activity.

 

How to cite: Sobh, M., Gerhards, C., and Fadel, I.: Mechanical Strength of Southern African’s Lithosphere from a Joint Inversion of Bouguer Gravity and Topography and its Uncertainty, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3561, https://doi.org/10.5194/egusphere-egu22-3561, 2022.

EGU22-5438 | Presentations | GD7.2

Crustal growth of Archean and early Proterozoic granitoids of the Ivindo region in the Souanké and Bomalinga areas from Congo Craton (North-West Republic of Congo) 

Rodeck Patrick Alan Loemba, Legran Juldit Espoir Plavy Ntsiele, Urbain Fiacre Opo, Carmel Bazebizonza Tchiguina, Hardy Medry Dieu-Veill Nkodia, and Florent Boudzoumou

Most interpretations of the Archean rocks in the Central Congo Craton have only focused on data from Cameroon and Gabon, few of them have included data from the Ivindo region in northwest Republic of Congo. This study presents for the first time a regional interpretation of the Archean rocks of the Congo craton from data on granitoids of the Ivindo region. Modal compositions vary between quartz-rich granitoids or pegmatite, granodiorites, granites and tonalites. These rocks are metaluminous and peraluminous (~0.8≤A/CNK≤~1.3) and define magmatic lineages that are predominantly calc-alkaline, tholeiitic, and rarely highly potassic calc-alkaline. REE diagrams show that these rocks are rich in rare earth elements (LREE) and large ionic lithophile (LILE), while exhibiting significant negative anomalies in Nb-Ta, and in Ti. Such geochemical signatures indicate that these granitoids formed possibly in a subduction tectonic setting. These geochemical signatures are comparable with the Dharwar, North China, and Pilbara cratons, also in similar Archean cratons.

The U-Pb ages based on zircon indicate that tonalites were amplaced at (2891.2 ± 10.6 and 2820.37 ± 6.23 Ma), pegmatite were amplaced at (2878.2 ± 13.6 and 2891.0 ± 12.6 Ma), granodiorite were ampleced at (2828. 98 ± 6.23 Ma) and granite were ampleced at (2430.19 ± 8.11 Ma). Thesse periods of magmatisme describe here revels the magmatic history of the Archean granitoids of the Congo craton in the Ivindo Bassement from 3085 ± 21.6 and 2430.19 ± 8.11 Ma.

Keywords: Archean, Crustal growth, Granitoids, Ivindo region, Congo craton, Republic of Congo.

 

 

How to cite: Loemba, R. P. A., Ntsiele, L. J. E. P., Opo, U. F., Bazebizonza Tchiguina, C., Nkodia, H. M. D.-V., and Boudzoumou, F.: Crustal growth of Archean and early Proterozoic granitoids of the Ivindo region in the Souanké and Bomalinga areas from Congo Craton (North-West Republic of Congo), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5438, https://doi.org/10.5194/egusphere-egu22-5438, 2022.

EGU22-6102 | Presentations | GD7.2 | Highlight

Nature vs. Nurture: Understanding the survival of Archean cratons 

Heather Bedle, Catherine Cooper, and Carol Frost

In a geodynamic, geological and geophysical review of global Archean cratons, we find that the survival of Archean cratons depends on the initial conditions of their formation, as well as the tectonic processes to which they were exposed.  In a sense, we must consider both their nature and how they were nurtured.  In a review of existing literature and models, we use stability regime diagrams to understand the factors that contribute to the intrinsic strength of a craton: buoyancy, viscosity, and relative integrated yield strength. We find that cratons formed in the Archean when thermal conditions enhanced extraction of large melt fractions and early cratonization promoted the formation of stable Archean cratonic lithosphere.  In terms of the cratons' nurturing, processes that may have modified and weaken cratonic lithosphere include subduction and slab rollback, rifting, and mantle plumes, as these processes introduced materials and conditions that warmed and metasomatized the lithosphere.  Examining four Archean cratons that are more stable, and four that are categorized as modified or destroyed, we note that continental lithosphere that was cratonized prior to the end of the Archean has more potential to survive deformation during the last 500 My. Although, the survivability of these cratons is highly dependent on their unique positions relative to larger scale tectonic processes, such as subduction.   We also observe that once an Archean craton begins to undergo even a small amount of modification, it is more likely to continue to be modified, as it loses the preservation advantage that it had upon birth.

How to cite: Bedle, H., Cooper, C., and Frost, C.: Nature vs. Nurture: Understanding the survival of Archean cratons, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6102, https://doi.org/10.5194/egusphere-egu22-6102, 2022.

EGU22-6661 | Presentations | GD7.2

Ocean break-up and related mountain rise controlled by a continentalcrustal root 

Anna Makushkina, Benoit Tauzin, Meghan S. Miller, Hrvoje Tkalčić, and Hans Thybo

Large-scale topography is thought to be mainly controlled by active tectonic processes. Fennoscandia is located far from any active tectonic setting and yet includes a mountain range along its passive North Atlantic margin. Models proposed to explain the origin of these enigmatic mountains are based on glacial isostatic adjustments, delamination, long-term isostatic equilibration, and dynamic support from the mantle, yet no consensus has been reached.

Here we demonstrate that Precambrian lithospheric structure of Fennoscandia controlled both Cenozoic oceanic breakup and recent mountain rise in the North Atlantic region. Fennoscandia formed by amalgamation of Proterozoic and Archean continental blocks; using both S- and P-receiver functions, we discovered that the Fennoscandian lithosphere still retains the original structural heterogeneity and its western margin is composed of three distinct blocks. The southern and northern blocks have relatively thin crust (~40-45 km), while the central block has thick crust (~60 km) that most likely was formed by crustal stacking during the Proterozoic amalgamation. The boundaries of the blocks continue into the oceanic crust as two major structural zones of the North-East Atlantic, suggesting that the Fennoscandian amalgamation structures determined the geometry of the ocean opening. We found no evidence for mountain root support or delamination in the areas of high topography that could be related to the mountain formation. Instead, our results suggest that the geometry of the observed features creates conditions favorable for edge-driven convection at the adjacent narrow margins that provides dynamic support for the mountains in Scandinavia.

How to cite: Makushkina, A., Tauzin, B., Miller, M. S., Tkalčić, H., and Thybo, H.: Ocean break-up and related mountain rise controlled by a continentalcrustal root, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6661, https://doi.org/10.5194/egusphere-egu22-6661, 2022.

EGU22-6819 | Presentations | GD7.2 | Highlight

What are cratons? 

Graham Pearson

The term craton has a complex and confused etymology. Despite originally specifying only strength and stability – of the crust – the term craton has seen widespread use as referring to a region characterised by crustal basement older than 2.5 Ga, despite the fact that some such “cratons” no longer possess their deep lithospheric root and have geological histories that contnue well beyond the Archean/Proterozoic boundary.  Viscous, buoyant lithospheric mantle roots are key to the survival and stability of continental crust. Here we use a revised craton definition (Pearson et al., 2021, Nature), that includes the requirement of a deep (~150 km or greater) and intact lithospheric root, to re-examine extent and character of regions defined as crtons. The revised definition has a nominal requirement for tectonic stability since ~ 1 Ga and recognises that some regions are “modified cratons” – having lost their deep roots, i.e., they may have behaved like cratons for an extended period but subsequently lost much of their stabilising mantle roots during major tectono-thermal events. In other words, despite being long-lived features, cratons are not all permanent. The 150 km lithospheric thickness cut-off provides an optimal match to crustal terranes with 1 Ga timescale stability.

We examine the processes involved in craton ormation and growth. Seismology can help to define the lateral extent of today’s cratons, but a detailed understanding of the regional geological history, kimberlite eruption ages and geothermal conditions is required to evaluate periods of past diamond potential, no-longer evident today. 

How to cite: Pearson, G.: What are cratons?, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6819, https://doi.org/10.5194/egusphere-egu22-6819, 2022.

EGU22-6975 | Presentations | GD7.2

Geochronology of the unexposed crust within the Finnish Archean – insights from the Koillismaa Deep Hole in Kuusamo, northeastern Finland 

Matti Kurhila, Teemu Anttilainen, Tuomo Karinen, and Perttu Mikkola

A 3000 m deep hole is being drilled in the Archean Karelian Craton in northeastern Finland in an area where the granitoids dominating the surface have yielded Neoarchean ages (2.8–2.7 Ga). Archean greenstones and Paleoproterozoic dolerites are exposed within the domain as well. The drilling site lies between ca. 2.44 Ga Koillismaa and Näränkävaara mafic layered intrusions. This site was chosen based on gravimetric, magnetic, magnetotelluric and reflection seismic studies, which have revealed a deep anomaly that seems to connect the two mafic layered intrusions. Based on modelling of the geophysical data, the upper boundary of this ca. 60 km long, roughly E-W oriented anomaly lies at approximately 1.5 km depth.

We sampled various rock types from depths of ~40–1600 m for zircon U-Pb dating. The lithologies include leucogranites, tonalite gneiss, hornblende diabase, quartz diorite and granodiorite. Based on observations from the drill core extracted so far, the source of the anomaly is likely to be ultramafic cumulates. Also, presence of Paleoproterozoic granitoids is likely. We will perform the U-Pb analyses during the winter of 2022. The results are expected to confirm the interconnection of the two layered intrusions, clarify the age distribution of the granitoids in the region, and help to decipher the detailed tectonic evolution of the Archean Koillismaa area. 

How to cite: Kurhila, M., Anttilainen, T., Karinen, T., and Mikkola, P.: Geochronology of the unexposed crust within the Finnish Archean – insights from the Koillismaa Deep Hole in Kuusamo, northeastern Finland, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6975, https://doi.org/10.5194/egusphere-egu22-6975, 2022.

EGU22-7310 | Presentations | GD7.2

Lithospheric domains of the West and Central African rift system based on Terracing and Cluster analysis 

Estelle Eric Fosso Teguia M, Jörg Ebbing, and Peter Haas

We present results of cluster analysis and geophysical modelling of the West and Central African rift system, where we integrate seismological and satellite data. For a description of lithospheric domains, two different methods based on seismic tomography and satellite gravity data have been used. First, the terracing method using the shape index, has been applied to the gravity field in order to enhance the signal of the large-scale tectonic units. In addition, the K-means cluster method (which is an unsupervised machine learning algorithm) has been applied to a seismic tomography model over the area.

Both models are compared and interpreted towards similarities and differences. The preliminary analysis based on K-means clustering of seismic tomography shows that the West and Central African rift system and its surroundings can be divided into at least three clearly distinct tectonic domains: The Northern part of the Congo craton, the Eastern part of the West African craton and an area in between. In addition, the preliminary analysis of the terracing of satellite gravity data, confirms the location of both the Congo and the West African craton, but also splits the area in between into two known tectonic units, the Southern part of the Saharan meta-craton and the West and Central African rift system in the center.

The cluster analysis is also pointing to differences at crustal and upper mantle level and is the first step towards the evolution of a lithospheric scale model. In the model, we integrate our tectonic domain analysis with the existing seismic Moho depths estimate and other information.

How to cite: Fosso Teguia M, E. E., Ebbing, J., and Haas, P.: Lithospheric domains of the West and Central African rift system based on Terracing and Cluster analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7310, https://doi.org/10.5194/egusphere-egu22-7310, 2022.

EGU22-8441 | Presentations | GD7.2

Detailed Structure of the South American Cratons Using Waveform Tomography 

Bruna Chagas de Melo, Sergei Lebedev, Nicolas Celli, and Marcelo Assumpção

South America presents a diverse tectonic set-up, with an active subduction margin on the western border and a stable continental interior to the east. In the ancient stable part, two main cratonic domains can be separated. The Amazonian, consolidated in Archean-Paleoproterozoic times, and the Brasiliano, marked by Neoproterozoic events related to the West Gondwana assembly. In each domain, geology and geophysical methods separate different cratonic nuclei. However, some nuclei's detailed lateral and vertical extent and even existence are debated.

In seismic tomography, we can define regions of cratonic lithosphere due to the shear wave sensitivity to temperature and composition. However, until recently, seismic data sampling in South America was highly scarce and uneven. Here, we assembled all freely available seismic data globally, with the addition of the FAPESP "3-Basins Thematic Project" temporary network. After selecting all paths crossing the hemisphere centred at South America and performing an automatic outlier rejection, we obtain a massive dataset of ~1 million waveform fits, constraining our final model.

We compute a new S-velocity tomographic model of the upper mantle of South America and surrounding oceans using the Automated Multimode Inversion of surface, S- and multiple S-waves. The increase in the data coverage of the model combined with the optimized tuning of the inversion parameters on the continent allows us to identify for the first time the fine details present in the cratonic structure. We observe that regions of thinner lithosphere inside cratons correspond to areas of rifting in previous tectonic cycles. Inside the boundaries of the Amazon craton, we image two cratonic blocks, separated by the Amazon basin. In this area, an aborted rift system preceded the formation of the Amazon basin in the Neoproterozoic, and rift reactivation occurred with the break-up of Pangea in the Mesozoic. Similarly, in the São Francisco Craton, we image a significantly thinner lithosphere in the Paramirim Aulacogen area, a Paleoproterozoic intracontinental rift system. These observations show that the continental lithospheric topography is closely related to upper mantle dynamic processes. We also image high-velocity lithospheric blocks under sedimentary basins. East of the Amazon craton, we image a high-velocity anomaly beneath the Parnaíba block, and under the Paraná basin the fragmented Paranapanema block lithosphere. Finally, by imaging the boundary of the cratonic units in detail, we can observe that magmatic events and large igneous provinces are distributed around the thick roots of the cratons, where the lithosphere is thinner.

How to cite: Chagas de Melo, B., Lebedev, S., Celli, N., and Assumpção, M.: Detailed Structure of the South American Cratons Using Waveform Tomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8441, https://doi.org/10.5194/egusphere-egu22-8441, 2022.

EGU22-9048 | Presentations | GD7.2

Modelling petrogenesis of Meso- and Neoarchean andesitic rocks: an example from Singhbhum craton, India 

Avishek Adhikari, Ankita Nandi, Shreya Mukherjee, and Ravikant Vadlamani

Petrogenetic processes of the Archean (>2500 Ma) andesitic rocks are strongly debated because of their distinct geochemical similarities to the modern subduction zone andesites contrast with sparse evidence for Archean lithospheric subduction. Therefore, processes responsible for generation of the andesitic rocks preserved in an Archean craton would potentially place constraints on the Archean geodynamic process. The Western Iron Ore Group (W-IOG) volcano-sedimentary succession in Singhbhum craton is overlain by unmetamorphosed Jagannathpur amygdular volcanics (basaltic andesite – andesite). The W-IOG preserves deformed lower greenschist-facies tholeiitic basalt and calc-alkaline basaltic andesite interlayered with BIF and Fe-Mn-rich phyllite and shale. Previously, petrogenesis of the basaltic andesite in W-IOG was interpreted as having formed in a subduction zone whereas the origin of Jagannathpur volcanics has remained unclear. Therefore, geochemical modelling using trace elements and Sm–Nd geochronology of these basaltic-andesitic rocks were performed to constrain the petrogenetic process and timing of volcanic eruption of these metavolcanic rocks.

Primitive mantle-normalized trace element patterns, chondrite-normalized REE patterns and Nb/Th, Zr/Th ratios of the W-IOG and Jagannathpur basaltic andesite – andesite show enrichment in large ion lithophile elements (LILE), light rare earth elements (LREE), Zr and Th indicating incompatible trace element enrichment in their petrogenesis. The W-IOG tholeiitic basalt is depleted in LILE, LREE, Zr and Th and an absence of Nb-Ta-Ti anomalies that imply a depleted mantle source. The W-IOG basaltic andesite yield an isochron age of 3041±94 Ma (2SD) with Ndi = 0.50875±0.00009, MSWD = 0.62 (n=10) and εNd(T) = +1.1±1.6; whereas the tholeiitic basalt yielded an isochron age of 3050±71 Ma (2SD) with Ndi = 0.50885±0.00010, MSWD = 0.17 (n=10) and εNd(T) = +3.3±1.6. Geochemical modelling indicates that the W-IOG basaltic andesite could have been generated by 20-40% assimilation-fractional crystallization (AFC) (r=0.2, ratio of rate of assimilation to the rate of fractional crystallization) of primitive tholeiitic magma that is derived by 14% partial melting of depleted MORB-type mantle (DMM) under spinel lherzolite depth in an extensional setting. The Jagannathpur basaltic andesite – andesite yielded an Sm-Nd isochron age of 2799±67 Ma (2SD) with Ndi = 0.50895±0.00006, MSWD = 0.36 (n=16) and εNd(T) = -1.1±0.5 and represents one of the oldest Neoarchean intracratonic flood basaltic volcanism. These basaltic andesite – andesite could have been produced by 20-60% AFC (r=0.2) of hybrid magma during lithospheric extension. Generation of the hybrid magma has been modelled by two end member components involving ~18% partial melt of enriched-DMM that interacted with low degree (~5%) partial melt of metasomatised subcontinental lithospheric mantle (SCLM). In addition, our geochemical model results suggest that Meso- to Neoarchean basaltic andesite – andesite rocks in Singhbhum craton were not generated by 1) assimilation of crustal material with primitive tholeiitic magma without fractional crystallization, 2) direct partial melting of different enriched mantle reservoirs (enriched-DMM, EM I, EM II) and mantle wedge peridotite in a subduction environment and 3) partial melting of solely metasomatised SCLM.

How to cite: Adhikari, A., Nandi, A., Mukherjee, S., and Vadlamani, R.: Modelling petrogenesis of Meso- and Neoarchean andesitic rocks: an example from Singhbhum craton, India, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9048, https://doi.org/10.5194/egusphere-egu22-9048, 2022.

EGU22-10000 | Presentations | GD7.2

Effects of multi-extensional tectonics in a cratonic area: 3D numerical modeling and implications for the Congo Basin 

Magdala Tesauro, Francesca Maddaloni, Taras Gerya, Alberto Pastorutti, Carla Braitenberg, and Damien Delvaux

The Congo basin (CB), also named Cuvette Centrale for its bowl shape, occupies a large part of the Congo Craton, which is composed of several amalgamated Archean cratonic blocks, surrounded by Paleo- and Meso- Proterozoic mobile belts. It started to form from a rift phase, during the late Mesoproterozoic (about 1100 Myr). This age, obtained from the interpretation of the almost 3000 km of seismic reflection profiles, is older than that assumed in previous studies and corresponds to a time prior to that of Rodinia assembly. In this tectonic scenario, the CB formation can be related to one of the final phases of the supercontinent Columbia break-up, resulted in several-failed rift. The extensional phase that produced the formation of a very heterogeneous basement, characterized by several basins and highs, NW-SE aligned, could have been likely the effect of the action of a slow multi-divergent velocity (i.e., multi-directional extension) on a cratonic lithosphere, which have induced the initial subsidence of the CB in a weaker part of the craton. The amalgamation of the cratons, composing the basement of the CB, likely left a weak zone in the suture areas, corresponding to the central part of the CB, which could have been more easily deformed, under the influence of tectonic stresses.

We implemented 3D geodynamic models, using the thermomechanical I3ELVIS code to test the hypothesis that the complex structures of the CB basement are the product of a slow multi-divergent velocity, acting on a cratonic area. The results of the numerical models are used to implement forward gravity models to estimate the temporal variations of the gravity effect of the tectonic structures formed during the simulations. Finally, we compared the forward gravity models with the present-day gravity field, in order to demonstrate the consistency between the modelled and observed main structures of the CB. The main results, in terms of topography variations, well reproduce the first-order basement depth variations of the CB. In particular, they produce the formation of an almost circular depressed area in the central part of the model, intersected by two strongly subsided elongated structures, orthogonal each other, whose topography tend to increase with time. The comparison between the forward gravity models and the observed gravity anomalies (gravity disturbance variations), shows that two fields are characterized by a similar alternation of weak positive and strong negative gravity anomalies. However, the modelled anomalies show a smoother trend and higher amplitude, being related to the density and topography variations induced by the upwelling of the asthenosphere, while the observed gravity field is strongly influenced by the sedimentation not simulated in our model.

How to cite: Tesauro, M., Maddaloni, F., Gerya, T., Pastorutti, A., Braitenberg, C., and Delvaux, D.: Effects of multi-extensional tectonics in a cratonic area: 3D numerical modeling and implications for the Congo Basin, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10000, https://doi.org/10.5194/egusphere-egu22-10000, 2022.

Lithosphere of cratons and orogens generally reacts differently to tectonic events. Although these differences are mostly clear during the orogenic phases, understanding how they respond to tectonic reactivation is still challenging. Here, we report the first detailed apatite fission-track (AFT) study pinpointing the gradual transition between cratonic and orogenic lithosphere, using the case study of the São Francisco craton (SFC) and the adjacent Araçuaí-West Congo Orogen (AWCO), eastern Brazil. The collision that built the AWCO partially affected the inherited rift structures of the Paramirim Aulacogen, embedded in the São Francisco-Congo paleocontinent. Our data reveal a differential Phanerozoic exhumation between closely interspaced areas affected and not affected by the AWCO deformation. Samples from the SFC present slow and protracted basement cooling during the Phanerozoic, while samples from the orogen display rapid exhumation since the Eocene. An intermediate ~N-S zone of c.40 km shows lower magnitude basement cooling during the Cenozoic, possibly because the propagation of AWCO deformation decreases towards the craton interior. Within the orogen, the Rio Pardo salient is the main reactive structure and probably results from the deformation of a master fault, inherited from its precursor rift. Here, we show how the magnitude of Phanerozoic denudation may be deeply associated with previous events of lithosphere weakening.

How to cite: Fonseca, A. C., Cruz, S., Novo, T., He, Z., and De Grave, J.: Differential exhumation of cratonic and non-cratonic lithosphere revealed by apatite fission-track thermochronology along the edge of the São Francisco craton, eastern Brazil, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13111, https://doi.org/10.5194/egusphere-egu22-13111, 2022.

EGU22-1232 | Presentations | GD7.1

Preliminary airborne geophysical surveys over the Bou Azzer-El Graara inlier (Central Anti-Atlas, Morocco): implications for geodynamic model of the Anti-Atlas Pan-African belt 

Saïd Ilmen, Fouzia Anzar, Abderrahmane Soulaimani, Mohamed Jaffal, Amine Bajddi, Lhou Maacha, and Bouchra Baidada

The Anti-Atlas orogenic belt, located at the northwestern edge of West African Craton, hosts several Proterozoic antiformal inliers (Boutonnières) which crops out under a thick Paleozoic Cover. In its central part, along the Anti-Atlas Major Fault, the Siroua and Bou Azzer-El Graara inliers exhibit Neoproterozoic ophiolitic suture which subduction settings is still under debate. In the last two decades, huge scientific publications were done in this area, mainly focused on the structural, petrological and geochronological issues. Three broad tectonothermal events were recognized in the Pan-African cycle. The Tonian–Cryogenian period ends with the obduction of supra-subduction ophiolite and oceanic arc material at ca. 640 Ma. The Early Ediacaran period was marked by the development and subsequent closure of a wide marginal basin next to a likely Andean-type arc (Saghro Group). The Late Ediacaran period is recorded by subaerial molasse deposits associated with post-collisional high-K calc-alkaline to shoshonitic magmatism (Ouarzazate Group).This project aims to use the magnetic and electromagnetic data of the Bou Azzer-El Graara inlier, and to integrate their interpretations in the geodynamic model of the Anti-Atlas Pan-African belt. The preliminary interpretations of the available aeromagnetic data show high-level magnetic signature at the western part of the Bou Azzer inlier, while it is missing in the east of the CAMP Foum Zguid dyke. From the Bou Ofroukh at the western tip of the inlier to the Ait Abdellah village, the strength of the magnetic signal is related to the wide exposure of the ultramafic rocks along the Anti-Atlas Major Fault. A weakness of the magnetic signal is observed in the area situated between Bou Azzer and Aghbar mines. This weakness was interpreted as being due to the deeply buried serpentinites under the Ediacaran volcano-sedimentary sequence. However, filed maps and magnetic signature indicate the absence of magnetic signal and the ultramafic rocks at the eastern domain of the Bou Azzer-El Graara inlier from the Foum Zguid dyke eastward. Several pending questions should be emphasized on the structural framework and continuity of the Anti-Atlas Major Fault and the role played by this inherited NE-SW Fracture infilled by Lower Liassic dolerite during the Pangea breakup.

How to cite: Ilmen, S., Anzar, F., Soulaimani, A., Jaffal, M., Bajddi, A., Maacha, L., and Baidada, B.: Preliminary airborne geophysical surveys over the Bou Azzer-El Graara inlier (Central Anti-Atlas, Morocco): implications for geodynamic model of the Anti-Atlas Pan-African belt, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1232, https://doi.org/10.5194/egusphere-egu22-1232, 2022.

There are a large number of different collision zones on Earth, formed in different geodynamic settings as a result of the collision of continental plates of different shapes and sizes. Researchers often use one or a combination of methods to study one region. In this study, we propose to compare the models of P and S anomalies of several regions. In this study, vertical sections were built under the collision zones of the Caucasus, Eastern Anatolia, NW Himalayas and Tien Shan using the method of local seismic tomography. 3D models of crustal inhomogeneities down to ~ 60-150 km were constructed using the LOTOS algorithm [Koulakov, 2009].

The main characteristic feature of all crustal models of collisional zones is a clear differentiation of the velocity anomalies of the orogen, formed due to shortening, and the continental plates, participating in the collision. Thus, the Arabian, East European, Indian, Tarim plates are associated with high velocity anomalies, and mountain structures, for example, the Greater and Lesser Caucasus, the Himalayas, are characterized by low velocities.

Volcanism is another geological feature that shows up well in seismic tomographic models. Young volcanism (up to ~ 2.5Ma) characterized by low-velocity anomalies in the models, while the older one characterized by high-velocity anomalies. Thus, the volcanic area of Kazbegi province including a group of Quaternary volcanoes (455-30 Ka) in Great Caucasus match to the locations of low-velocities in the P- and S-seismic models. But the Eastern Anatolia younger magmatism (6–4 Ma) occurred in the south around Lake Van, stands out as high velocity anomalies.

It is known that there is the lithospheric window under Tien Shan and Anatolia which is filled with overheated asthenospheric material that reaches the bottom of the crust, thereby weakening and heating the lower crust. It is most likely that the upper crustal high-velocity anomaly corresponds to the strong upper crust which is compacted by solidified material from Neogene-Quaternary volcanism, while the low-velocity anomaly is associated with the weak heated lower crust.

Thus, comparison of seismic tomography models of different collision zones can be the key to better understanding the processes in the crust and lithosphere.

The reported study was funded by Russian Foundation for Basic Research, project number 19-35-60002.

How to cite: Medved, I.: Common features of lithosphere structures in various collision zones of Eurasia based on seismic tomography studies, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-1399, https://doi.org/10.5194/egusphere-egu22-1399, 2022.

Εpithermal and porphyry-type mineralization is genetically associated with acidic dyke rocks in a part of the supra-detachment Western Thrace Basin. 40Ar/39Ar ages on biotite of an andesitic lava dome and on K-feldspar of quartz-feldspar porphyritic dykes were determined and thus, new temporal constraints on the age of volcanism and mineralization were obtained.           

Biotite of an andesitic lava dome yields a 40Ar/39Ar plateau age of 33.05 ± 0.07 Ma (P=0.12). The dated andesite is considered as representative of the andesitic-dacitic rocks of large volcanic and subvolcanic bodies in the Western Thrace basin (Mavropetra Formation, Kirki area). Andesitic rocks indicate affinities of calc-alkaline to high-K calc-alkaline series magmatism. They are coeval to the high-K calc-alkaline magmatic suite of Leptokarya – Kirki, which forms an ENE-WSW 30 km long magmatic dome, developed between the Rhodope metamorphics extending northwards and the overlying detached Melia non-metamorphic formations and Middle-Upper Eocene molassic clastics, extending southwards.

Smaller bodies of acidic dyke rocks (rhyolite and quartz-feldspar porphyry), crosscut the overall dome structure with the andesitic-dacitic volcanics, the Middle-Upper Eocene clastic sediments, the mafic rocks of the Melia unit, the metamorphics of the Kechros Unit of Rhodope and the Leptokarya - Kirki granitoids. They appear with planar subvertical boundaries following a general NNW-SSE trend, perpendicular to the main ENE-WSW dome structure. They are concentrated along a major fault zone  (Ag. Filippos fault), with high- to intermediate sulfidation epithermal polymetallic sulfide mineralization, as well as in a roughly 8 km long and 1 km wide fracture zone to the east and northeast of Aisymi village with porphyry-type mineralization. Structural observations document the mega-tension gashes nature of the dykes with pronounced sinistral strike-slip kinematic indicators of the Kirki mineralized tectonic zone. K-feldspars from quartz-feldspar porphyritic dykes at Kirki yield a 40Ar/39Ar plateau age of a 31.89 ± 0.12 Ma (P=0.08).  The acidic dyke rocks contain calc-alkaline to high-K calc-alkaline differentiation trends. They exhibit marked enrichment of LREE relative to the HREE, flat HREE pattern, negative Eu anomaly and Eu/Eu* values ranging between 0.32 and 0.82.

In conclusion, the ENE-SSW Leptokarya - Kirki granitic dome was developed contemporaneously with the andesitic-dacitic volcanics at the contact between the Rhodope metamorphics and the detached Melia formations and Middle-Upper Eocene clastics at about 33 Ma, followed by the NNW-SSE transverse faults and acidic dykes with epithermal and porphyry-type mineralization at about 32 Ma.

 

How to cite: Skarpelis, N., Jourdan, F., and Papanikolaou, D.: New time constraints from 40Ar/39Ar geochronology on andesitic-dacitic lavas and acidic dyke rocks: An attempt to date the associated mineralization in the Western Thrace supra-detachment basin (Kirki, NE Greece), EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2159, https://doi.org/10.5194/egusphere-egu22-2159, 2022.

This study focusses on the vein-hosted copper sulphide deposits in the Upper Palaeozoic Munster and South Munster Basins of southwest Ireland. Detailed mapping of the Allihies mine area (Beara Peninsula), have led to a new interpretation of the timing and development of mineralised quartz veins. Macro- and microstructural investigations reveal that the copper sulphide-bearing, mainly E-W striking quartz veins are directly related to early extensional, basinal normal faults. Molybdenite Re-Os dating of the main-stage Cu lode yield ages from 367.3 ± 5.5 to 366.4 ± 1.9 Ma. Bi-phase (LV) aqueous fluid inclusions associated with the mineralised quartz veins range from moderate salinity with high homogenisation temperatures (>3.2 wt% NaClequiv, Th < 314°C) to high salinities with very low homogenisation temperatures (<28.5 wt% NaClequiv, Th >74°C) The extensional faults and associated quartz veins experienced subsequent late Carboniferous Variscan deformation, including cleavage development, sinistral SW-NE strike slip faulting, cataclastic deformation and recrystallization of vein fills. Later fluids with low to moderate salinities and Th values of about 200°C were trapped in syn-Variscan quartz-chlorite saddle reefs and en echelon tension gash arrays in semi brittle shear zones. The new timing of Cu mineralisation in SW Ireland has major implications for its relationship to the base metal deposits of the Irish Midlands.

How to cite: Meere, P., Lang, J., and Unitt, R.: The Upper Palaeozoic Vein Hosted Copper Deposits of the Allihies Mining Area, Southwest Ireland – A New Structural and Chronological Evaluation, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-2811, https://doi.org/10.5194/egusphere-egu22-2811, 2022.

EGU22-3139 | Presentations | GD7.1

Crustal Structure across Central Scandinavia along the Silver-Road refraction profile 

Metin Kahraman, Hans Thybo, Irina Artemieva, Alexey Shulgin, Peter Hedin, and Rolf Mjelde

The Baltic Shield is located in the northern part of Europe. It formed by amalgamation of a series of terranes and microcontinents during the Archean to the Paleoproterozoic, followed by significant modification in Neoproterozoic to Paleozoic time by the Sveconorwegian (Grenvillian) and the Caledonian orogenies. The Baltic Shield includes an up to 2500 m high northeast-southwest oriented mountain range, the Scandes, which mainly coincides with the Caledonian and Sveconorwegian deformed parts along the western North Atlantic coast, despite being located far from any active plate boundary.

We present a crustal scale seismic model along the WNW to ESE directed Silver Road profile in northern Scandinavia between 8oE and 20oE. This profile extends south of Lofoten for ~300km across the Norwegian shelf in the Atlantic Ocean and for ~300km across the onshore Caledonides and Baltic Shield proper. The seismic data were acquired with 5 onshore explosive sources and offshore air gun shots from the vessel Hakon Mosby along the whole offshore profile. Data was acquired by 270 onshore stations at nominally 1.5 km distance and 16 ocean bottom seismometers on the shelf, slope and into the oceanic environment. The results of this experiment will provide information on the origin of the anomalous onshore topography and offshore bathymetry at the edge of the North Atlantic Ocean.

We present results from ray tracing modeling and tomographic inversion of the seismic velocity structure along the profile. The crustal structure is uniform with a thickness of 45 km along the whole onshore profile including both the Caledonides and the shield part. The crust thins abruptly to ~25 km thickness towards the shelf around the coastline. Pn velocity is only ~7.6-7.8 km/s below the high topography areas with Caledonian nappes, and extending into the offshore part, whereas it is 8.4 km/s below the shield proper. By gravity modelling we find that the low Pn zone has a low density of 3.20 g/cm3, which we interpret as partially eclogitizised lower crust. The Svecofennian unit has a very high density of 3.48 g/cm3 in the shield with low topography. Isostasy to 60 km depth, as suggested by Receiver Functions, indicates a ~2 km topography which is ~1 km higher than observed. However, recent results from high-resolution seismic tomography shows a velocity change between the two onshore zones down to 120 km depth. Including this observations into the calculations allows us to explain the observed topography by isostasy in the crust and lithospheric mantle.

How to cite: Kahraman, M., Thybo, H., Artemieva, I., Shulgin, A., Hedin, P., and Mjelde, R.: Crustal Structure across Central Scandinavia along the Silver-Road refraction profile, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-3139, https://doi.org/10.5194/egusphere-egu22-3139, 2022.

EGU22-5722 | Presentations | GD7.1

Antarctica ice sheet basal melting enhanced by high mantle heat 

Irina M. Artemieva

Antarctica is losing ice mass by basal melting associated with processes in deep Earth and reflected in geothermal heat flux. The latter is poorly known and existing models based on disputed assumptions are controversial. Here I demonstrate that the rate of Antarctica ice basal melting is significantly underestimated: the area with high heat flux is double in size and the amplitude of the high heat flux anomalies is 20-30% higher than in previous results. Extremely high heat flux (>100 mW/m2) in almost all of West Antarctica, continuing to the South Pole region, and beneath the Lake Vostok region in East Antarctica requires a thin (<70 km) lithosphere and shallow mantle melting, caused by recent geodynamic activity. This high heat flux may promote sliding lubrication and result in dramatic reduction of ice mass. The results form basis for re-evaluation of the Antarctica ice-sheet dynamics models with consequences for global environmental changes. [Artemieva, I.M., 2022, Earth-Science Reviews]

How to cite: Artemieva, I. M.: Antarctica ice sheet basal melting enhanced by high mantle heat, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5722, https://doi.org/10.5194/egusphere-egu22-5722, 2022.

EGU22-5771 | Presentations | GD7.1

Lithospheric thermo-chemical heterogeneity and density structure of the Siberian craton 

Alexey Shulgin and Irina Artemieva

We present a new model for the density structure of the lithospheric upper mantle beneath the Siberian craton, based on a 3D tesseroid gravity modeling. Our model is based on a detailed crustal structural database SibCrust (Cherepanova et al., 2013) constrained by regional seismic data. The residual lithospheric mantle gravity anomalies are derived by removing the 3D gravitational effect of the crust. We next convert these anomalies to lithosphere mantle in situ densities. To evaluate chemical heterogeneities of the lithospheric mantle, thermal effects are removed based on the global continental thermal model TC1 (Artemieva, 2006). The resulting density model at SPT conditions shows a highly heterogeneous structure of the cratonic lithospheric mantle. Density heterogeneities reflect a complex geodynamic evolution of the craton, which still preserves parts of the pristine cratonic lithosphere in areas where the lithosphere has not been modified by metasomatism associated with the Siberian LIP, several pulses of kimberlite-type magmatism, and rifting at the peripheral parts.

How to cite: Shulgin, A. and Artemieva, I.: Lithospheric thermo-chemical heterogeneity and density structure of the Siberian craton, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-5771, https://doi.org/10.5194/egusphere-egu22-5771, 2022.

EGU22-6210 | Presentations | GD7.1

Crustal structure in the central Tethys realm 

Vahid Teknik, Hans Thybo, Irina Artemieva, and Abdolreza Ghods

The central Tethys realm including Anatolia, Caucasus and Iran is one of the most
complex geodynamic settings within the Alpine-Himalayan belt. To investigate the
tectonics of this region, we estimate the depth to magnetic basement (DMB) as a
proxy for the shape of sedimentary basins, and average crustal magnetic
susceptibility (ACMS) by applying the fractal spectral method to aeromagnetic data.
Magnetic data is sensitive to the presence of iron-rich minerals in oceanic fragments
and mafic intrusions hidden beneath sedimentary sequences or overprinted by
younger tectono-magmatic events. Furthermore, a seismically constrained 2D
density-susceptibility model along Zagros is developed to study the depth extent of
the tectonic structure.
Comparison of DMB and ACMS demonstrates that the structural complexity
increases from the Iranian plateau into Anatolia.
Strong ACMS show lineaments coincides with known occurrences of Magmatic-
Ophiolite Arcs (MOA) and weak ACMS zones coincide with known sedimentary
basins in the study region, including Zagros. Based on strong ACMS anomalies, we
identify hitherto unknown MOAs below the sedimentary cover in eastern Iran and in
the SE part of Urima-Dokhtar Magmatic Arc (UDMA). Our results allow for
estimation of the dip of the related paleo-subduction zones. Known magmatic arcs
(Pontides and Urima-Dokhtar) have high-intensity heterogeneous ACMS. We
identify a 450 km-long buried (DMB &gt;6 km) magmatic arc or trapped oceanic crust
along the western margin of the Kirşehır massif in Anatolia from a strong ACMS
anomaly. We identify large, partially buried magmatic bodies in the Caucasus LIP at
the Transcaucasus and Lesser Caucasus and in NW Iran. Strong ACMS anomalies
coincides with tectonic boundaries and major faults within the Iranian plateau while
the ACMA signal is generally weak in Anatolia. The Cyprus subduction zone has a

strong magnetic signature which extends ca. 500 km into the Arabian plate to the
south of the Bitlis suture.
We derive a 2D crustal-scale density-susceptibility model of the NW Iranian plateau
along a 500 km long seismic profile across major tectonic provinces of Iran from the
Arabian plate to the South Caspian Basin (SCB). A seismic P-wave receiver function
section is used to constrain major crustal boundaries in the density model. We
demonstrate that the Main Zagros Reverse Fault (MZRF), between the Arabian and
the overriding Central Iran crust, dips at ~13° angle to the NE and extends to a depth
of ~40 km. The trace of MZRF suggests ~150 km underthrusting of the Arabian plate
beneath Central Iran. We identify a new crustal-scale suture beneath the Tarom
valley separating the South Caspian Basin crust from Central Iran. High density lower
crust beneath Alborz and Zagros may be related to partial eclogitization of crustal
roots at depths deeper than ~40 km.

How to cite: Teknik, V., Thybo, H., Artemieva, I., and Ghods, A.: Crustal structure in the central Tethys realm, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6210, https://doi.org/10.5194/egusphere-egu22-6210, 2022.

EGU22-6563 | Presentations | GD7.1

New global constraints on transition-zone topography from normal-mode tomography 

Rûna van Tent and Arwen Deuss

Lateral variations in the depths of the transition-zone discontinuities are generally attributed to variations in temperature, causing local changes in the depth of the dominant phase transition. At moderate temperatures the dominant phase transitions are those of olivine, characterized by a positive Clapeyron slope (dP/dT) at 410 km depth and a negative Clapeyron slope at 660 km depth. An anticorrelation between topography on the 410 and 660-km discontinuities is therefore expected in the absence of variations in chemical composition, as an increase in temperature would lower the 410-km discontinuity and elevate the 660-km discontinuity. Simultaneously, this temperature increase would result in a decrease in seismic velocity and density of the mantle material. Comparing models of transition-zone topography, seismic velocity and density therefore gives valuable insight into the nature of transition-zone discontinuities. Existing global models of transition-zone topography have been created using SS and PP precursor measurements, which need to be corrected for mantle velocity structure using an independent velocity model before the discontinuity depths can be calculated. Here, we present new global models of transition-zone topography and whole-mantle S-wave velocity, P-wave velocity and density that have been simultaneously inferred from a different type of seismic data: Earth’s normal modes. Normal modes are whole-Earth oscillations induced by large earthquakes (Mw≥7.5). We use our models, which can be readily compared to one another, to analyze the nature of the transition-zone discontinuities. We also discuss the trade-offs between the different model parameters and the model uncertainties, the latter of which is additional information provided by the Hamiltonian Monte Carlo method used for our inversion. Finally, we compare our models to transition-zone topography obtained from SS precursor data.

How to cite: van Tent, R. and Deuss, A.: New global constraints on transition-zone topography from normal-mode tomography, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-6563, https://doi.org/10.5194/egusphere-egu22-6563, 2022.

EGU22-7161 | Presentations | GD7.1 | Highlight

Regional variability in the thermal structure of Tibetan Lithosphere 

Bing Xia, Irina Artemieva, Hans Thybo, and Simon Klemperer

We present a thermal model- of lithospheric thickness and surface heat flow in Tibet and adjacent regions (74-110o E, 26-42o N) based on topography and seismic Moho. We interpret strong heterogeneity in lithospheric thermal structure to be caused by longitudinal variations in the northern extent of the subducting Indian plate, southward subduction of the Asian plate beneath central Tibet, and possible preservation of fragmented Tethyan paleo-slabs. Cratonic-type cold and thick lithosphere (200-240 km) with a predicted surface heat flow of 40-50 mW/m2 typifies the Tarim Craton, the northwest Yangtze Craton, and most of the Lhasa Block that is likely refrigerated by underthrusting Indian lithosphere. We identify a ‘North Tibet anomaly’ (at 84-92o E, 33-38o N) with thin (<80 km) lithosphere and high surface heat flow (>80-100 mW/m2) in a region with anomalous seismic Sn and Pn propagation. We interpret this anomaly as the result of removal of lithospheric mantle and asthenospheric upwelling at the junction of the Indian and Asian slabs with opposite subduction polarities. Other parts of Tibet typically have intermediate lithosphere thickness of 120-160 km and a surface heat flow of 45-60 mW/m2, with patchy anomalies in eastern Tibet.

How to cite: Xia, B., Artemieva, I., Thybo, H., and Klemperer, S.: Regional variability in the thermal structure of Tibetan Lithosphere, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-7161, https://doi.org/10.5194/egusphere-egu22-7161, 2022.

EGU22-9483 | Presentations | GD7.1

Upper mantle structure beneath Bulgaria obtained by receiver function analysis 

Gergana Georgieva, Lev Vinnik, Sergey Oreshin, Larissa Makeyeva, Dragomir Dragomirov, Valentin Buchakchiev, and Liliya Dimitrova

Deep structure beneath the central part of the Balkan Peninsula was studied using P and S receiver function technique. Data from seismic stations from the Bulgarian National Seismological Network and several stations from neighbouring countries were used. Depth of Mohorovicic discontinuity has been estimated between 28–30 km in northern and central Bulgaria to 50 km in southwestern of Bulgaria. The 410 km mantle boundary is uplifted by 10 km relative to nominal depth in the area of Rhodopean Massif. In northern Bulgaria, the boundary is lowered by 10 km. Indications of a low-velocity layer are present at a depth exceeding 410 km. The thickness of the asthenosphere is estimated as 50 km and the depth of lithosphere-asthenosphere (LAB) boundary varies between 40 and 60 km.

The results of this study have been published in Vinnik et. al., Izvestiya, Physics of the Solid Earth, 2021, Vol. 57, No. 6, pp. 849–863. This research has been carried out as part of a joint project supported by the National Science Foundation of Bulgaria (grant no. KP-06-RUSIA/27.09.2019) and the Russian Foundation for Basic Research (RFBR, grant no. 19-55-18008 Bolg_a).

How to cite: Georgieva, G., Vinnik, L., Oreshin, S., Makeyeva, L., Dragomirov, D., Buchakchiev, V., and Dimitrova, L.: Upper mantle structure beneath Bulgaria obtained by receiver function analysis, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-9483, https://doi.org/10.5194/egusphere-egu22-9483, 2022.

EGU22-10022 | Presentations | GD7.1

Finite-Frequency Body-Wave Tomography in Scandinavia 

Nevra Bulut and Hans Thybo

We present a P-wave velocity model of the upper mantle, obtained from finite-frequency body wave tomography, to analyze the relationship between deep and surface structures in Fennoscandia, one of the most studied cratons on Earth. The large array aperture of 2000 km by 800 km allows us to image the velocity structure to 800 km depth at very high resolution. The velocity structure provides background for understanding the mechanisms responsible for the enigmatic and debated high topography in the Scandinavian mountain range far from any plate boundary. Our model shows exceptionally strong velocity anomalies with changes by up to 6% on a 200 km scale. We propose that a strong negative velocity anomaly down to 200 km depth along all of Norway provides isostatic support to the enigmatic topography, as we observe a linear correlation between hypsometry and uppermost mantle velocity anomalies to 150 km depth in central Fennoscandia. The model reveals low velocity anomaly below the mountains underlain by positive velocity anomalies, which we explain by preserved original Svecofennian and Archaean mantle below the Caledonian/Sveconorwegian deformed parts of Fennoscandia. Strong positive velocity anomalies to around 200 km depth around the southern Bothnian Bay and the Baltic Sea may be associated with pristine lithosphere of the present central and southern Fennoscandian craton that has been protected from modification since its formation. However, the Archaean domain in the north and the marginal parts of the Svecofennian domains appear to have experienced strong modification of the upper mantle. A pronounced north-dipping positive velocity anomaly in the southern Baltic Sea extends below Moho. It coincides in location and dip with a similar north-dipping structure in the crust and uppermost mantle to 80 km depth observed from high resolution, controlled source seismic data. We interpret this feature as the image of a Paleoproterozoic boundary which has been preserved for 1.8 Gy in the lithosphere.

How to cite: Bulut, N. and Thybo, H.: Finite-Frequency Body-Wave Tomography in Scandinavia, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10022, https://doi.org/10.5194/egusphere-egu22-10022, 2022.

EGU22-10848 | Presentations | GD7.1

New constraints on the thermochemical properties of Earth’s upper and mid-mantle from ScS reverberation data 

Rashni Anandawansha, Lauren Waszek, and Benoit Tauzin

Seismic topography models reveal that both upwelling plumes and downgoing slabs are deflected or stagnate at various depths in Earth’s mantle transition zone (MTZ) and mid-mantle (MM). Deflection within the MTZ is associated with the mineral physics phase changes at 410 and 660-km depth, however the cause of deflection in the MM remains debated. There are no candidate mineral transformations to explain the varied MM reflectors that have been detected [Waszek et al., 2018], instead indicating widespread compositional heterogeneities. Furthermore, our recent thermal model [Waszek et al., 2021] reveals a link between high temperatures in the MTZ and surface activity, indicating that some plumes are able to traverse this region unimpeded. Illuminating the detailed seismic structures of the upper and mid-mantle is key to determine the link between reflectors, temperature, composition, and dynamics.

Here, we present a new large global dataset of ScS reverberations, compiled using an automatic waveform identification code based on Convolutional Neural Networks [Garcia et al., 2021]. Mantle discontinuities and reflectors generate precursors to ScSn phases, and postcursors to sScSn. Here, we present a new method to correct for 3D mantle structure in which we remove the symmetry problem suffered by most of these phases. The data are stacked to reveal the small amplitude reverberation signals, and our correction method allows us to stack for five ScSn and sScSn phases simultaneously to obtain the highest possible data coverage. For the global MTZ discontinuities, we use “adaptive stacking”. Based on Voronoi tessellation, the method automatically adjusts for topography, noise, and data coverage. Regional-scale fixed bin parameterisations of varying sizes are used to search for the intermittent MM reflectors.

We incorporate our seismic observations with mineral physics modelling, inverting for a realistic range of potential temperatures and basalt-harzburgite mixtures to obtain the best-matching thermochemical model for the MTZ. We first compare our new ScS MTZ model with its counterpart generated from SS and PP precursors [Waszek et al., 2021], to benchmark observational differences between data types. We next investigate the link or lack thereof between our MTZ model and detections of MM signals, to place improved constraints on variations in properties with depth. The final step is interpretation of our observations and modelling in the context of geodynamical simulations of mantle convection. Our outputs will contribute to greater understanding of the complex relationship between MTZ discontinuities and MM reflectors, with implications for global mantle circulation, compositional layering beneath the MTZ, and even surface activity. 

 

 

References:

Waszek, Schmerr, Ballmer. 2018.

Garcia, Waszek, Tauzin, Schmerr. 2021.

How to cite: Anandawansha, R., Waszek, L., and Tauzin, B.: New constraints on the thermochemical properties of Earth’s upper and mid-mantle from ScS reverberation data, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-10848, https://doi.org/10.5194/egusphere-egu22-10848, 2022.

EGU22-13229 | Presentations | GD7.1

Seismic evidence for a 1000-km mantle discontinuity under the Pacific 

Zhendong Zhang, Jessica Irving, Frederik Simons, and Tariq Alkhalifah

Seismic discontinuities in the mantle are indicators of its thermo-chemical state and offer clues
to its dynamics. Ray-based imaging methods, though limited by the approximations made, have
mapped mantle transition zone (MTZ) discontinuities in detail, but have yet to offer definitive
conclusions on the presence and nature of mid-mantle discontinuities. We use a waveequation-
based imaging method to image both MTZ and mid-mantle discontinuities, and
interpret their physical nature. We focus on precursors to the surface-reflected seismic phases
PP, SS, PS, and SP to produce images of deep reflectors using reverse-time migration (RTM),
employing the full-waveform tomographic model GLAD-M25 for wavefield extrapolation. Our
adjoint-based inverse modeling accounts for more of the physics of wave propagation than raybased
stacking methods, which leads to improved accuracy and realistic precision of the
obtained images. The relative amplitude and location of the imaged reflectors are indeed well
resolved, but an interpretation of absolute amplitudes in terms of reflection coefficients
remains elusive. We observe a thinned mantle transition zone southeast of Mauna Loa, Hawaii,
and a reduction in impedance contrast around 410 km depth in the same area. These
observations coincide with anomalously low S-wavespeeds in the background tomographic
model, suggesting a hotter-than-average mantle in the region. Our new images furthermore
reveal a 4000—5000 km-wide reflector in the mid mantle below the central Pacific, at 950—
1050 km depth. This discontinuity displays strong topography and is marked by a polarity
opposite to that of the 660-km discontinuity, implying an impedance reversal near 1000 km.
We speculate that this mid-mantle discontinuity is linked to the mantle plumes rising from the
large low shear-velocity province (LLSVP) at the base of the mantle below this region. Some
seismic tomography models are in support of this interpretation, while others remain at odds---
a discrepancy that our observations may help resolve.

How to cite: Zhang, Z., Irving, J., Simons, F., and Alkhalifah, T.: Seismic evidence for a 1000-km mantle discontinuity under the Pacific, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13229, https://doi.org/10.5194/egusphere-egu22-13229, 2022.

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