Velocity changes around the Kaikōura earthquake ruptures from ambient noise cross-correlations

Abstract

Summary Seismic velocity changes before and after large magnitude earthquakes carry information about damage present in the surrounding region. This study presents temporal velocity changes detected prior to and following the 2016 November Mw 7.8 Kaikōura earthquake in Canterbury, New Zealand. We use continuous waveform data from eleven short period seismometers within the Kaikōura region with an average interstation distance of 83 km. Nine-component day-long empirical Green’s functions were computed for frequencies between 0.1 Hz and 0.9 Hz for continuous seismic records from the 1th of January 2012 to the 28th of February 2018, which also includes the 2013 Cook Strait and Lake Grassmere earthquakes. Using the moving-window cross-spectral method, seismic velocity changes were calculated. Immediately following the 2016 Kaikōura earthquake, a decrease in seismic velocity averaged across all component-pairs of approximately 0.2 per cent was observed. An increase in seismic velocity of approximately 0.1 per cent after the earthquake was visible over a 1.5 year period averaged across all component-pairs. A depth sensitivity analysis suggests that observed velocity changes were confined to the uppermost 0-5 km of the subsurface. We consider strong ground motions a likely candidate for the seismic velocity decrease, followed by postseismic relaxation via crack healing of the faults that ruptured in the Kaikōura region. Fault-zone damage may also have contributed to observed decreases in the vicinity of ruptured faults.