Differentiating frictionally locked asperities from kinematically coupled zones

Seismogenic zones resist slipping before generating earthquakes. Therefore, slip deficit, also called coupling, is a proxy of interseismic seismogenic zones on plate boundaries. However, when a part of a frictional interface sticks together (locked), its sliding surroundings are braked (coupled), so...

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Bibliographic Details
Published in:arXiv.org 2024-09
Main Authors: Sato, Dye SK, Hori, Takane, Fukahata, Yukitoshi
Format: Article
Language:English
Subjects:
Asperity
Coupling
Earthquakes
Locking
Ocean floor
Seismic activity
Slip
Spatial distribution
Subduction (geology)
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Summary:Seismogenic zones resist slipping before generating earthquakes. Therefore, slip deficit, also called coupling, is a proxy of interseismic seismogenic zones on plate boundaries. However, when a part of a frictional interface sticks together (locked), its sliding surroundings are braked (coupled), so the coupled zone is an overestimate of the locked zone. Several indicators collectively termed mechanical coupling have been proposed to capture locked zones, but their relationship with true frictional locking is unclear. This study combines the frictional physics that locked and unlocked zones should observe, pointing out that we can estimate frictionally locked segments, known as asperities in fault mechanics, with remarkable simplicity but with high generality. First, we assemble the definitions of locking in various frictional failures and arrive at its unified expression: in any friction law, locking/unlocking is the pre-/post-yield phase of frictional failure, and their interseismic approximation is static-dynamic friction, which imposes either of the stationary (constant slip) or steady (constant stress) state. We then parametrize locked zones as distributed circular asperities on unlocked interfaces, to develop a trans-dimensional slip deficit inversion that incorporates the physical constraints of locking-unlocking (static-dynamic). We apply our method and detect five asperities in the Nankai subduction zone in southwestern Japan. Their spatial distribution indicates the asperity location correlates with seafloor topography. Estimated locked zones are consistent with slip zones of historical megathrust earthquakes while mostly not overlapping with slow-earthquake occurrence zones at depth, supporting a hypothesis that the nests of slow earthquakes are normally in long-wavelength scales coupled but unlocked.
ISSN:2331-8422