Evidence for a scale‐limited low‐frequency earthquake source process

Abstract

AbstractWe calculate the seismic moments for 34,264 low‐frequency earthquakes (LFEs) beneath the Olympic Peninsula, Washington. LFE moments range from 1.4 × 1010 to 1.9 × 1012 N m (Mw = 0.7–2.1). While regular earthquakes follow a power law moment‐frequency distribution with a b value near 1 (the number of events increases by a factor of 10 for each unit increase in Mw), we find that while for large LFEs the b value is ~6, for small LFEs it is <1. The magnitude‐frequency distribution for all LFEs is best fit by an exponential distribution with a mean seismic moment (characteristic moment) of 2.0 × 1011 N m. The moment‐frequency distributions for each of the 43 LFE families, or spots on the plate interface where LFEs repeat, can also be fit by exponential distributions. An exponential moment‐frequency distribution implies a scale‐limited source process. We consider two end‐member models where LFE moment is limited by (1) the amount of slip or (2) slip area. We favor the area‐limited model. Based on the observed exponential distribution of LFE moment and geodetically observed total slip, we estimate that the total area that slips within an LFE family has a diameter of 300 m. Assuming an area‐limited model, we estimate the slips, subpatch diameters, stress drops, and slip rates for LFEs during episodic tremor and slip events. We allow for LFEs to rupture smaller subpatches within the LFE family patch. Models with 1–10 subpatches produce slips of 0.1–1 mm, subpatch diameters of 80–275 m, and stress drops of 30–1000 kPa. While one subpatch is often assumed, we believe 3–10 subpatches are more likely.