TS3.1

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.

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.

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.

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.

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.

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.

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 (M_L 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.

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.