Implications of a reverse polarity earthquake pair on fault friction and stress heterogeneity near Ridgecrest, California

Peter M. Shearer, Nader Senobari, & Yuri Fialko

Published November 9, 2024, SCEC Contribution #13473

We apply the Matrix Profile algorithm to 100 days of continuous data starting 10 days before the 2019 M 6.4 and M 7.1 Ridgecrest earthquakes from borehole seismic station B921 near the Ridgecrest aftershock sequence. We identify many examples of reversely polarized waveforms, but focus on one particularly striking earthquake pair with strongly negatively correlated P and S waveforms at B921 and several other nearby stations. Waveform-cross-correlation-based relocation of these events indicates they are at about 10 km depth and separated by only 115 m. Individual focal mechanisms are poorly resolved for these events because of the limited number of recording stations with unambiguous P polarities. However, relative P and S polarity and amplitude information can be used to constrain the likely difference in fault plane orientation between the two events to be 10 to 20 degrees. We explore possible models to explain these observations, including low effective coefficients of fault friction and short-wavelength stress heterogeneity caused by prior earthquakes. Although definitive conclusions are lacking, we favor local stress heterogeneity as being more consistent with other observations for the Ridgecrest region.

Key Words
Reverse polarity earthquake pair

Citation
Shearer, P. M., Senobari, N., & Fialko, Y. (2024). Implications of a reverse polarity earthquake pair on fault friction and stress heterogeneity near Ridgecrest, California. Journal of Geophysical Research, 129. doi: 10.1029/2024JB029562.