On the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle
Viscoelastic processes in the upper mantle redistribute seismically generated stresses and modulate crustal deformation throughout the earthquake cycle. Geodetic observations of these motions at the surface of the crust-mantle system offer the possibility of constraining the rheology of the upper ma...
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sg-ntu-dr.10356-1709522023-10-24T15:36:39Z On the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle Mallick, Rishav Lambert, Valere Meade, Brendan Earth Observatory of Singapore Science::Geology Deformation Forward Modeling Viscoelastic processes in the upper mantle redistribute seismically generated stresses and modulate crustal deformation throughout the earthquake cycle. Geodetic observations of these motions at the surface of the crust-mantle system offer the possibility of constraining the rheology of the upper mantle. Parsimonious representations of viscoelastically modulated deformation through the aseismic phase of the earthquake cycle should simultaneously explain geodetic observations of (a) rapid postseismic deformation, (b) late in the earthquake cycle near-fault strain localization. To understand how rheological formulations affect kinematics, we compare predictions from time-dependent forward models of deformation over the entire earthquake cycle for an idealized vertical strike-slip fault in a homogeneous elastic crust underlain by a homogeneous viscoelastic upper-mantle. We explore three different rheologies as inferred from laboratory experiments: (a) linear Maxwell, (b) linear Burgers, (c) power-law. The linear Burgers and power-law rheologies are consistent with fast and slow deformation phenomenology over the entire earthquake cycle, while the single-layer linear Maxwell model is not. The kinematic similarity of linear Burgers and power-law models suggests that geodetic observations alone may be insufficient to distinguish between them, but indicate that one may serve as an effective proxy for the other. However, the power-law rheology model displays a postseismic response that is non-linearly dependent on earthquake magnitude, which may offer a partial explanation for observations of limited postseismic deformation near some magnitude 6.5–7.0 earthquakes. We discuss the role of mechanical coupling between frictional slip and viscous creep in controlling the time-dependence of regional stress transfer following large earthquakes and how this may affect the seismic hazard and risk to communities living close to fault networks. Published version This research was supported by a Texaco Postdoctoral Fellowship awarded to Rishav Mallick. Valere Lambert is supported by a National Science Foundation EAR Postdoctoral Fellowship. 2023-10-20T04:53:40Z 2023-10-20T04:53:40Z 2022 Journal Article Mallick, R., Lambert, V. & Meade, B. (2022). On the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle. Journal of Geophysical Research: Solid Earth, 127(9). https://dx.doi.org/10.1029/2022JB024683 2169-9356 https://hdl.handle.net/10356/170952 10.1029/2022JB024683 2-s2.0-85139086724 9 127 en Journal of Geophysical Research: Solid Earth © 2022 American Geophysical Union. All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the copyright holder. The Version of Record is available online at http://doi.org/ application/pdf |
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Science::Geology Deformation Forward Modeling Mallick, Rishav Lambert, Valere Meade, Brendan On the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle |
| description |
Viscoelastic processes in the upper mantle redistribute seismically generated stresses and modulate crustal deformation throughout the earthquake cycle. Geodetic observations of these motions at the surface of the crust-mantle system offer the possibility of constraining the rheology of the upper mantle. Parsimonious representations of viscoelastically modulated deformation through the aseismic phase of the earthquake cycle should simultaneously explain geodetic observations of (a) rapid postseismic deformation, (b) late in the earthquake cycle near-fault strain localization. To understand how rheological formulations affect kinematics, we compare predictions from time-dependent forward models of deformation over the entire earthquake cycle for an idealized vertical strike-slip fault in a homogeneous elastic crust underlain by a homogeneous viscoelastic upper-mantle. We explore three different rheologies as inferred from laboratory experiments: (a) linear Maxwell, (b) linear Burgers, (c) power-law. The linear Burgers and power-law rheologies are consistent with fast and slow deformation phenomenology over the entire earthquake cycle, while the single-layer linear Maxwell model is not. The kinematic similarity of linear Burgers and power-law models suggests that geodetic observations alone may be insufficient to distinguish between them, but indicate that one may serve as an effective proxy for the other. However, the power-law rheology model displays a postseismic response that is non-linearly dependent on earthquake magnitude, which may offer a partial explanation for observations of limited postseismic deformation near some magnitude 6.5–7.0 earthquakes. We discuss the role of mechanical coupling between frictional slip and viscous creep in controlling the time-dependence of regional stress transfer following large earthquakes and how this may affect the seismic hazard and risk to communities living close to fault networks. |
| author2 |
Earth Observatory of Singapore |
| author_facet |
Earth Observatory of Singapore Mallick, Rishav Lambert, Valere Meade, Brendan |
| format |
Article |
| author |
Mallick, Rishav Lambert, Valere Meade, Brendan |
| author_sort |
Mallick, Rishav |
| title |
On the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle |
| title_short |
On the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle |
| title_full |
On the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle |
| title_fullStr |
On the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle |
| title_full_unstemmed |
On the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle |
| title_sort |
on the choice and implications of rheologies that maintain kinematic and dynamic consistency over the entire earthquake cycle |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/170952 |
| _version_ |
1781793841393696768 |