Shallow Slow Slip Events in the Imperial Valley With Along‐Strike Propagation

Author:

Materna Kathryn1ORCID,Bürgmann Roland2ORCID,Lindsay Danielle2ORCID,Bilham Roger1,Herring Thomas3ORCID,Crowell Brendan4ORCID,Szeliga Walter5ORCID

Affiliation:

1. CIRES and Geological Sciences, University of Colorado Boulder Boulder CO USA

2. University of California Berkeley Berkeley CA USA

3. MIT Cambridge MA USA

4. University of Washington Seattle WA USA

5. Central Washington University Ellensburg WA USA

Abstract

AbstractShallow creep events provide opportunities to understand the mechanical properties and behavior of faults. However, due to physical limitations observing creep events, the precise spatio‐temporal evolution of slip during creep events is not well understood. In 2023, the Superstition Hills and Imperial faults in California each experienced centimeter‐scale slip events that were captured in unprecedented detail by satellite radar, sub‐daily Global Navigation Satellite Systems, and creepmeters. In both cases, the slip propagated along the fault over 2–3 weeks. The Superstition Hills event propagated bilaterally away from its initiation point at average velocities of ∼9 km/day, but propagation velocities were locally much higher. The ruptures were consistent with slip from tens of meters to ∼2 km depths. These slowly propagating events reveal that the shallow crust of the Imperial Valley does not obey purely velocity‐strengthening or velocity‐weakening rate‐and‐state friction, but instead requires the consideration of fault heterogeneity or fault‐frictional behaviors such as dilatant strengthening.

Funder

National Science Foundation

National Aeronautics and Space Administration

Publisher

American Geophysical Union (AGU)

Reference61 articles.

1. Space-time correlation of slip and tremor during the 2009 Cascadia slow slip event

2. Self-healing slip pulses in dynamic rupture models due to velocity-dependent strength

3. A two-layer model for aseismic slip on the Superstition Hills fault, California

4. Surface slip subsequent to the 24 November 1987 Superstition Hills, California, earthquake monitored with digital creepmeters;Bilham R.;Bulletin of the Seismological Society of America,1989

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