Seismic Imaging Of The Mw 7.1 Ridgecrest Earthquake Rupture Zone From Data Recorded By Dense Linear Arrays

We analyze seismograms recorded by four arrays (B1-B4) with 100 m station spacing and apertures of 4-8 km that cross the surface rupture of the 2019 Mw 7.1 Ridgecrest earthquake. The arrays extend from B1 in the northwest to B4 in the southeast of the surface rupture. Delay times between P wave arrivals associated with similar to 1,200 local earthquakes and four teleseismic events are used to estimate local velocity variations beneath the arrays. Both teleseismic and local P waves travel faster on the northeast than the southwest side of the fault beneath arrays B1 and B4, but the velocity contrast is less reliably resolved at arrays B2 and B3. We identify several 1-2 km wide low-velocity zones with much slower inner cores that amplify S waveforms, inferred as damage zones, beneath each array. The damage zones at arrays B2 and B4 also generate fault-zone head and trapped waves. An automated detector, based on peak ground velocities and durations of high-amplitude waves, identifies candidate fault-zone trapped waves (FZTWs) in a localized zone for similar to 600 earthquakes at array B4. Synthetic waveform modeling of averaged FZTWs, generated by similar to 30 events with high-quality signals, indicates that the trapping structure at array B4 has a width of similar to 300 m, depth of 3-5 km, S wave velocity reduction of similar to 20% with respect to the surrounding rock, Q-value of similar to 30, and S wave velocity contrast of similar to 4% across the fault (faster on the northeast side). The results show complex fault-zone internal structures (velocity contrasts and low-velocity zones) that vary along fault strike.