Abstract
Inelastic deformation due to seismic activity is an important signal that reflects fault evolution. In particular, aftershock sequences indicate the evolution of damage in a medium that has experienced a large earthquake. Herein, we discuss the inelastic strain rate surrounding the fault that produced the M 7.3 Western Tottori earthquake in 2000 using long-term aftershock analysis. To obtain high-resolution focal mechanisms 18 years after the earthquake occurrence, we conducted dense seismic observations in the focal area. The inelastic strain rate estimated from the aftershock seismic moment tensor data showed spatial variations within a range of 10−7–10−11 per year, 18 years after the main shock. By comparing the inelastic strain rates from immediately after the earthquake and 18 years later, we detected the increase in the spatial variations in the inelastic strain rate; the variations are as small as 102 (= 10−5/10−7) for the early stage but as large as 104 (= 10−7/10−11) for the later period. In addition, the decay of the rate during these two periods varied spatially from spatial bin to bin. Certain bins in the northern segment of the earthquake fault, southern edge of the fault, and surrounding the location of the preceding swarm activity to the M 7.3 event showed slower decay rates than the inverse of the lapse time since the occurrence of the M 7.3 earthquake. We modeled this decay rate change as the relaxation response of a power-law fluid to an elastic strain input from the large earthquake. Most parts of the fault can be explained by this model. However, the areas with low decay rates suggest the presence of a dragging mechanism, such as aseismic slip, at or around these locations.
Highlights
Crustal strength is the key to understanding the development of the crust, including large earthquakes, because it controls the medium behavior under tectonic stress loading in the crust
In this study, we investigated the inelastic strain rate surrounding the fault associated with the W-Tottori EQ by performing dense seismic observations
The inelastic strain rate estimated from the aftershock seismic moment tensor data shows spatial variations ranging from 10−7 to 10−11 per year 18 years after the main shock
Summary
Introduction Crustal strength is the key to understanding the development of the crust, including large earthquakes, because it controls the medium behavior under tectonic stress loading in the crust. Data and observations In this study, we attempted to estimate the inelastic deformation due to aftershocks because aftershock activity is an inelastic response to step-like stress loading in the Yukutake and Iio 2017 surrounding the fault caused by the main shock To evaluate this response, we required temporal changes in the inelastic strain rate. The procedure for obtaining the inelastic strain rate and its change in a spatial bin from the real data is as follows: 1) Determine the focal mechanisms of events that occurred in the bin from the polarities of the first P-wave arrival onsets. The average strain rate was estimated using the tensor magnitude of the CMT data divided by the lapsed time and volume size of the entire region (30 km along the earthquake fault × 10 km wide × 10 km deep).
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