Poroelastic effects on rupture propagation across fault stepovers
The role of poroelasticity in influencing the frequency of ruptures jumping through strike-slip stepovers remains unclear. To understand how poroelastic effects govern long-term rupture behavior in strike-slip fault systems with stepovers, we conduct earthquake sequence simulations incorporating und...
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sg-ntu-dr.10356-1819852025-01-05T04:26:43Z Poroelastic effects on rupture propagation across fault stepovers Huang, Luyuan Heimisson, Elías Rafn Dal Zilio, Luca Asian School of the Environment Earth Observatory of Singapore Earth and Environmental Sciences Poroelasticity Strike-slip stepover The role of poroelasticity in influencing the frequency of ruptures jumping through strike-slip stepovers remains unclear. To understand how poroelastic effects govern long-term rupture behavior in strike-slip fault systems with stepovers, we conduct earthquake sequence simulations incorporating undrained pore pressure responses across the full spectrum of Skempton's coefficient. Our findings reveal that Skempton's coefficient significantly affects the effective normal stress, which can either cause fault clamping or unclamping, and ultimately influences rupture propagation across fault stepovers. The likelihood of rupture jumping is predominantly determined by Skempton's coefficient and the width of the stepover, with Skempton's coefficient showing an approximately linear relationship to the critical jumpable step size. Specifically, a higher Skempton's coefficient facilitates rupture jumping across fault segments, even over larger stepover distances. Analytical solutions involving dislocation and Skempton's coefficient provide practical methods for evaluating pore pressure changes and associated seismic hazards near fault stepovers. Our statistical analysis identifies a critical jumpable width of 4.4–5.1 km due to static stress transfer, assuming a typical range of Skempton's coefficient for compressional stepovers, beyond which ruptures are unlikely to propagate. This study underscores the potential of using physics-based earthquake sequence models to reflect statistical fault rupture behaviors. Given that multi-segment earthquake ruptures present challenges in assessing maximum rupture lengths, our findings offer crucial insights into the role of poroelastic effects and the conditions that facilitate or limit rupture propagation across fault stepovers. Ministry of Education (MOE) Luyuan Huang was financially supported by the National Natural Science Foundation of China (No: 42074111, 42174120) and the China Scholarship Council (No: 202004190042). Luca Dal Zilio was supported by the European Research Council (ERC) Synergy Grant “Fault Activation and Earthquake Rupture” (FEAR) (No: 856559), the Earth Observatory of Singapore (EOS), and the Singapore Ministry of Education Tier 3b project “Investigating Volcano and Earthquake Science and Technology (InVEST)” (No: MOE-MOET32021-0002). Elías Rafn Heimisson thanks the Swiss National Science Foundation for partially supporting this research through the Ambizione grant number PZ00P2 208993. 2025-01-05T04:26:43Z 2025-01-05T04:26:43Z 2025 Journal Article Huang, L., Heimisson, E. R. & Dal Zilio, L. (2025). Poroelastic effects on rupture propagation across fault stepovers. Earth and Planetary Science Letters, 649, 119103-. https://dx.doi.org/10.1016/j.epsl.2024.119103 0012-821X https://hdl.handle.net/10356/181985 10.1016/j.epsl.2024.119103 2-s2.0-85209243466 649 119103 en MOE-MOET32021-0002 Earth and Planetary Science Letters © 2024 Elsevier B.V. All rights reserved. |
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Earth and Environmental Sciences Poroelasticity Strike-slip stepover |
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Earth and Environmental Sciences Poroelasticity Strike-slip stepover Huang, Luyuan Heimisson, Elías Rafn Dal Zilio, Luca Poroelastic effects on rupture propagation across fault stepovers |
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The role of poroelasticity in influencing the frequency of ruptures jumping through strike-slip stepovers remains unclear. To understand how poroelastic effects govern long-term rupture behavior in strike-slip fault systems with stepovers, we conduct earthquake sequence simulations incorporating undrained pore pressure responses across the full spectrum of Skempton's coefficient. Our findings reveal that Skempton's coefficient significantly affects the effective normal stress, which can either cause fault clamping or unclamping, and ultimately influences rupture propagation across fault stepovers. The likelihood of rupture jumping is predominantly determined by Skempton's coefficient and the width of the stepover, with Skempton's coefficient showing an approximately linear relationship to the critical jumpable step size. Specifically, a higher Skempton's coefficient facilitates rupture jumping across fault segments, even over larger stepover distances. Analytical solutions involving dislocation and Skempton's coefficient provide practical methods for evaluating pore pressure changes and associated seismic hazards near fault stepovers. Our statistical analysis identifies a critical jumpable width of 4.4–5.1 km due to static stress transfer, assuming a typical range of Skempton's coefficient for compressional stepovers, beyond which ruptures are unlikely to propagate. This study underscores the potential of using physics-based earthquake sequence models to reflect statistical fault rupture behaviors. Given that multi-segment earthquake ruptures present challenges in assessing maximum rupture lengths, our findings offer crucial insights into the role of poroelastic effects and the conditions that facilitate or limit rupture propagation across fault stepovers. |
| author2 |
Asian School of the Environment |
| author_facet |
Asian School of the Environment Huang, Luyuan Heimisson, Elías Rafn Dal Zilio, Luca |
| format |
Article |
| author |
Huang, Luyuan Heimisson, Elías Rafn Dal Zilio, Luca |
| author_sort |
Huang, Luyuan |
| title |
Poroelastic effects on rupture propagation across fault stepovers |
| title_short |
Poroelastic effects on rupture propagation across fault stepovers |
| title_full |
Poroelastic effects on rupture propagation across fault stepovers |
| title_fullStr |
Poroelastic effects on rupture propagation across fault stepovers |
| title_full_unstemmed |
Poroelastic effects on rupture propagation across fault stepovers |
| title_sort |
poroelastic effects on rupture propagation across fault stepovers |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/181985 |
| _version_ |
1821237179215511552 |