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Seismological evidence for a multifault network at the subduction interface

Caroline Chalumeau, Hans Agurto-Detzel, Andreas Rietbrock (), Michael Frietsch, Onno Oncken, Monica Segovia and Audrey Galve
Additional contact information
Caroline Chalumeau: Karlsruhe Institute of Technology
Hans Agurto-Detzel: Karlsruhe Institute of Technology
Andreas Rietbrock: Karlsruhe Institute of Technology
Michael Frietsch: Karlsruhe Institute of Technology
Onno Oncken: GeoForschungsZentrum (GFZ)
Monica Segovia: Escuela Politecnica Nacional
Audrey Galve: CNRS, Observatoire de la Côte d’Azur, IRD, Géoazur

Nature, 2024, vol. 628, issue 8008, 558-562

Abstract: Abstract Subduction zones generate the largest earthquakes on Earth, yet their detailed structure, and its influence on seismic and aseismic slip, remains poorly understood. Geological studies of fossil subduction zones characterize the seismogenic interface as a 100 m–1 km thick zone1–3 in which deformation occurs mostly on metres-thick faults1,3–6. Conversely, seismological studies, with their larger spatial coverage and temporal resolution but lower spatial resolution, often image the seismogenic interface as a kilometres-wide band of seismicity7. Thus, how and when these metre-scale structures are active at the seismic-cycle timescale, and what influence they have on deformation is not known. Here we detect these metres-thick faults with seismicity and show their influence on afterslip propagation. Using a local three-dimensional velocity model and dense observations of more than 1,500 double-difference relocated earthquakes in Ecuador, we obtain an exceptionally detailed image of seismicity, showing that earthquakes occur sometimes on a single plane and sometimes on several metres-thick simultaneously active subparallel planes within the plate interface zone. This geometrical complexity affects afterslip propagation, demonstrating the influence of fault continuity and structure on slip at the seismogenic interface. Our findings can therefore help to create more realistic models of earthquake rupture, aseismic slip and earthquake hazard in subduction zones.

Date: 2024
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DOI: 10.1038/s41586-024-07245-y

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