TY - GEN
T1 - 3d acoustic-elastic coupling with gravity
T2 - 33rd International Conference for High Performance Computing, Networking, Storage and Analysis: Science and Beyond, SC 2021
AU - Krenz, Lukas
AU - Uphoff, Carsten
AU - Ulrich, Thomas
AU - Gabriel, Alice Agnes
AU - Abrahams, Lauren S.
AU - Dunham, Eric M.
AU - Bader, Michael
N1 - Publisher Copyright:
© 2021 IEEE Computer Society. All rights reserved.
PY - 2021/11/14
Y1 - 2021/11/14
N2 - We present a highly scalable 3D fully-coupled Earth & ocean model of earthquake rupture and tsunami generation and perform the first fully coupled simulation of an actual earthquake-Tsunami event and a 3D benchmark problem of tsunami generation by a megathrust dynamic earthquake rupture. Multi-petascale simulations, with excellent performance demonstrated on three different platforms, allow high-resolution forward modeling. Our largest mesh has ?261 billion degrees of freedom, resolving at least 15 Hz of the acoustic wave field.We self-consistently model seismic, acoustic and surface gravity wave propagation in elastic (Earth) and acoustic (ocean) materials sourced by physics-based non-linear earthquake dynamic rupture, thereby gaining insight into the tsunami generation process without relying on approximations that have previously been applied to permit solution of this challenging problem. Complicated geometries, including high-resolution bathymetry, coastlines and segmented earthquake faults are discretized by adaptive unstructured tetrahedral meshes. This inevitably leads to large differences in element sizes and wave speeds which can be mitigated by ADER local time-stepping and a Discontinuous Galerkin discretization yielding high-order accuracy in time and space.
AB - We present a highly scalable 3D fully-coupled Earth & ocean model of earthquake rupture and tsunami generation and perform the first fully coupled simulation of an actual earthquake-Tsunami event and a 3D benchmark problem of tsunami generation by a megathrust dynamic earthquake rupture. Multi-petascale simulations, with excellent performance demonstrated on three different platforms, allow high-resolution forward modeling. Our largest mesh has ?261 billion degrees of freedom, resolving at least 15 Hz of the acoustic wave field.We self-consistently model seismic, acoustic and surface gravity wave propagation in elastic (Earth) and acoustic (ocean) materials sourced by physics-based non-linear earthquake dynamic rupture, thereby gaining insight into the tsunami generation process without relying on approximations that have previously been applied to permit solution of this challenging problem. Complicated geometries, including high-resolution bathymetry, coastlines and segmented earthquake faults are discretized by adaptive unstructured tetrahedral meshes. This inevitably leads to large differences in element sizes and wave speeds which can be mitigated by ADER local time-stepping and a Discontinuous Galerkin discretization yielding high-order accuracy in time and space.
KW - ADER-DG
KW - Computational Seismology
KW - Earthquake Simulation
KW - Elastic-Acoustic-Coupling
KW - SeisSol
KW - Tsunami Generation
UR - http://www.scopus.com/inward/record.url?scp=85119986588&partnerID=8YFLogxK
U2 - 10.1145/3458817.3476173
DO - 10.1145/3458817.3476173
M3 - Conference contribution
AN - SCOPUS:85119986588
T3 - International Conference for High Performance Computing, Networking, Storage and Analysis, SC
BT - Proceedings of SC 2021
PB - IEEE Computer Society
Y2 - 14 November 2021 through 19 November 2021
ER -