3D Linked Subduction, Dynamic Rupture, Tsunami, and Inundation Modeling: Dynamic Effects of Supershear and Tsunami Earthquakes, Hypocenter Location, and Shallow Fault Slip

Abstract: Physics-based dynamic rupture models capture the variability of earthquake slip in space and time and can account for the structural complexity inherent to subduction zones. Here we link tsunami generation, propagation, and coastal inundation with 3D earthquake dynamic rupture (DR) models initialized using a 2D seismo-thermo-mechanical geodynamic (SC) model simulating both subduction dynamics and seismic cycles. We analyze a total of 15 subduction-initialized 3D dynamic rupture-tsunami scenarios in which the t… Show more

“…Slip on the megathrust propagating onto splays through dynamic or static stress changes has been inferred for past and recent tsunamigenic earthquakes (e.g., Cummins & Kaneda, 2000; Fan et al., 2017; Obana et al., 2017). Our results highlight that studying compound rupture of megathrusts and multiple or segmented splay faults is important for the assessment of future hazardous events and to better understand the details of near‐trench rupture processes that control seafloor uplift and hence tsunami generation (Madden et al., 2020; Saito et al., 2019; Satake, 2015; Tanioka & Satake, 1996; Ulrich et al., 2022; Wirp et al., 2021). Future efforts could aim to include region‐specific observations, such as high‐resolution seismic imaging and geological data in modeling workflows that link earthquake source models to tsunami models to improve our understanding of tsunamigenesis.…”

“…To relate our findings directly to tsunami data, the here found splay fault effects should be analyzed with more complex bathymetry and 3‐D complexity in future studies (Bletery et al., 2015; Matsuyama et al., 1999; Tonini et al., 2020; Ulrich et al., 2019). Recent studies using a similar methodology to the one presented here have already attempted this for megathrust‐only events (Madden et al., 2020; Wirp et al., 2021). However, one of the major limitations in these 3‐D studies is the uncertainties in how to accurately account for any lateral variation in the initial stresses and strengths on the megathrust since the considered geodynamic seismic cycle model is two‐dimensional.…”

“…(2020) and Wirp et al. (2021) for a subduction zone setting, where the stresses and strengths are adapted to avoid unilateral nucleation along the 2D fault and thereby reduce fault slip. The 3D megathrust dynamic rupture models in Wirp et al.…”

Earthquake Rupture on Multiple Splay Faults and Its Effect on Tsunamis

“…Slip on the megathrust propagating onto splays through dynamic or static stress changes has been inferred for past and recent tsunamigenic earthquakes (e.g., Cummins & Kaneda, 2000; Fan et al., 2017; Obana et al., 2017). Our results highlight that studying compound rupture of megathrusts and multiple or segmented splay faults is important for the assessment of future hazardous events and to better understand the details of near‐trench rupture processes that control seafloor uplift and hence tsunami generation (Madden et al., 2020; Saito et al., 2019; Satake, 2015; Tanioka & Satake, 1996; Ulrich et al., 2022; Wirp et al., 2021). Future efforts could aim to include region‐specific observations, such as high‐resolution seismic imaging and geological data in modeling workflows that link earthquake source models to tsunami models to improve our understanding of tsunamigenesis.…”

“…To relate our findings directly to tsunami data, the here found splay fault effects should be analyzed with more complex bathymetry and 3‐D complexity in future studies (Bletery et al., 2015; Matsuyama et al., 1999; Tonini et al., 2020; Ulrich et al., 2019). Recent studies using a similar methodology to the one presented here have already attempted this for megathrust‐only events (Madden et al., 2020; Wirp et al., 2021). However, one of the major limitations in these 3‐D studies is the uncertainties in how to accurately account for any lateral variation in the initial stresses and strengths on the megathrust since the considered geodynamic seismic cycle model is two‐dimensional.…”

“…(2020) and Wirp et al. (2021) for a subduction zone setting, where the stresses and strengths are adapted to avoid unilateral nucleation along the 2D fault and thereby reduce fault slip. The 3D megathrust dynamic rupture models in Wirp et al.…”

Earthquake Rupture on Multiple Splay Faults and Its Effect on Tsunamis

“…SeisSol solves the seismic wave equation in velocitystress formulation using an Arbitrary high-order DERivate Discontinuous Galerkin (ADER-DG) scheme (Dumbser & Käser, 2006). Computational optimizations target supercomputers with many-core CPUs (Breuer et al, 2014;Heinecke et al, 2014;Rettenberger et al, 2016;Krenz et al, 2021). SeisSol uses local time stepping, which increases runtime efficiency by decreasing dependence of the time-step on the element with the small- Yellow surface is the megathrust, which intersects the seafloor to left and reaches 50 km depth to right.…”

“…Others initialize dynamic rupture models with conditions, including initial P f , from geodynamic and seismic cycling modeling that captures long term subduction zone deformation and fluid flow (I. Zelst et al, 2019;Wirp et al, 2021;Madden et al, 2021). Rice (1992) shows that fluid at elevated pressures within a fault zone may follow the same gradient with depth as the lithostatic stress, causing constant effective normal stress with depth.…”

The state of pore fluid pressure and 3D megathrust earthquake dynamics

The State of Pore Fluid Pressure and 3‐D Megathrust Earthquake Dynamics