Abstract
SUMMARYLarge earthquakes can diminish and redistribute stress, which can change the stress field in the Earth’s crust. Seismic anisotropy, measured through shear wave splitting (SWS), is often considered to be an indicator of stress in the crust because the closure of cracks due to differential stress leads to waves polarized parallel to the cracks travelling faster than in the orthogonal direction. We examine spatial and temporal variations in SWS measurements and the Vp/Vs ratio associated with the 2013 Cook Strait (Seddon, Grassmere) and 2016 Kaikōura earthquakes in New Zealand. These earthquake sequences provide a unique data set, where clusters of closely spaced earthquakes occurred. We use an automatic, objective splitting analysis algorithm and automatic local S-phase pickers to expedite the processing and to minimize observer bias. We present SWS and Vp/Vs measurements for over 40 000 crustal earthquakes across 36 stations spanning close to $5\frac{1}{2}$ yr between 2013 and 2018. We obtain a total of 102 260 (out of 398 169) high-quality measurements. We observe significant spatial variations in the fast polarization orientation, ϕ. The orientation of gravitational stresses are consistent with most of the observed anisotropy. However, multiple mechanisms (such as structural, tectonic stresses and gravitational stresses) may control some of the observed crustal anisotropy in the study area. Systematic analysis of SWS parameters and Vp/Vs ratios revealed that apparent temporal variations are caused by variation in earthquake path through spatially varying media.
Highlights
Stress in the Earth is an important factor in earthquake genesis
We have presented the largest number of measurements of high-quality shear-wave splitting (SWS) parameters (∼102,000) around the Marlborough and Wellington region with a detailed systematic analysis of crustal anisotropy using over 40,000 crustal earthquakes recorded on at least one of the 36 stations
We conclude that the crustal anisotropy around the study region is confined to the upper few kilomemanuscript to be submitted to Geophysical Journal International ters of the crust and can be controlled by either one mechanism or a combination of more than one
Summary
Stress in the Earth is an important factor in earthquake genesis. Earthquakes are caused by the sudden rupture of rocks along faults exposed to differential stress in the Earth’s crust. Drilling boreholes to seismogenic depths is a difficult and expensive enterprise (Townend & Zoback, 2000; Zoback & Zoback, 2002) Another well-established method is the inversion of earthquake focal mechanisms to determine the stress orientations in the region where the earthquake occurred (Michael, 1984; Hardebeck & Michael, 2006; Arnold & Townend, 2007). Geodetic techniques such as using GNSS (Global Navigation Satellite System) and InSAR (Interferometric Synthetic Aperture Radar) measurements, which can be used to infer strain rates, can be interpreted as changes in stress (Hardebeck & Michael, 2006; Hardebeck & Okada, 2018). Stress orientations can be inferred from measuring crustal seismic anisotropy through SWS (Crampin, 1984; Savage et al, 2016; Cochran & Kroll, 2015) and changes in SWS parameters can be interpreted as changes in the state of stress
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