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Incorporating Full Elastodynamic Effects and Dipping Fault Geometries in Community Code Verification Exercises for Simulations of Earthquake Sequences and Aseismic Slip (SEAS)

Authors :
Erickson, Brittany A.
Jiang, Junle
Lambert, Valère
Barbot, Sylvain D.
Abdelmeguid, Mohamed
Almquist, Martin
Ampuero, Jean‐Paul
Ando, Ryosuke
Cattania, Camilla
Chen, Alexandre
Dal Zilio, Luca
Deng, Shuai
Dunham, Eric M.
Elbanna, Ahmed E.
Gabriel, Alice‐Agnes
Harvey, Tobias W.
Huang, Yihe
Kaneko, Yoshihiro
Kozdon, Jeremy E.
Lapusta, Nadia
Li, Duo
Li, Meng
Liang, Chao
Liu, Yajing
Ozawa, So
Perez‐Silva, Andrea
Pranger, Casper
Segall, Paul
Sun, Yudong
Thakur, Prithvi
Uphoff, Carsten
van Dinther, Ylona
Yang, Yuyun
Erickson, Brittany A.
Jiang, Junle
Lambert, Valère
Barbot, Sylvain D.
Abdelmeguid, Mohamed
Almquist, Martin
Ampuero, Jean‐Paul
Ando, Ryosuke
Cattania, Camilla
Chen, Alexandre
Dal Zilio, Luca
Deng, Shuai
Dunham, Eric M.
Elbanna, Ahmed E.
Gabriel, Alice‐Agnes
Harvey, Tobias W.
Huang, Yihe
Kaneko, Yoshihiro
Kozdon, Jeremy E.
Lapusta, Nadia
Li, Duo
Li, Meng
Liang, Chao
Liu, Yajing
Ozawa, So
Perez‐Silva, Andrea
Pranger, Casper
Segall, Paul
Sun, Yudong
Thakur, Prithvi
Uphoff, Carsten
van Dinther, Ylona
Yang, Yuyun
Source :
Bulletin of the Seismological Society of America vol.113 (2023) nr.2 p.499-523 [ISSN 0037-1106]
Publication Year :
2023

Abstract

Numerical modeling of earthquake dynamics and derived insight for seismic hazard relies on credible, reproducible model results. The sequences of earthquakes and aseismic slip (SEAS) initiative has set out to facilitate community code comparisons, and verify and advance the next generation of physics‐based earthquake models that reproduce all phases of the seismic cycle. With the goal of advancing SEAS models to robustly incorporate physical and geometrical complexities, here we present code comparison results from two new benchmark problems: BP1‐FD considers full elastodynamic effects, and BP3‐QD considers dipping fault geometries. Seven and eight modeling groups participated in BP1‐FD and BP3‐QD, respectively, allowing us to explore these physical ingredients across multiple codes and better understand associated numerical considerations. With new comparison metrics, we find that numerical resolution and computational domain size are critical parameters to obtain matching results. Codes for BP1‐FD implement different criteria for switching between quasi‐static and dynamic solvers, which require tuning to obtain matching results. In BP3‐QD, proper remote boundary conditions consistent with specified rigid body translation are required to obtain matching surface displacements. With these numerical and mathematical issues resolved, we obtain excellent quantitative agreements among codes in earthquake interevent times, event moments, and coseismic slip, with reasonable agreements made in peak slip rates and rupture arrival time. We find that including full inertial effects generates events with larger slip rates and rupture speeds compared to the quasi‐dynamic counterpart. For BP3‐QD, both dip angle and sense of motion (thrust versus normal faulting) alter ground motion on the hanging and foot walls, and influence event patterns, with some sequences exhibiting similar‐size characteristic earthquakes, and others exhibiting different‐size events. These findings undersco

Details

Database :
OAIster
Journal :
Bulletin of the Seismological Society of America vol.113 (2023) nr.2 p.499-523 [ISSN 0037-1106]
Notes :
DOI: 10.1785/0120220066, English
Publication Type :
Electronic Resource
Accession number :
edsoai.on1445828278
Document Type :
Electronic Resource