Abstract
Although the study of spatiotemporal variation of a subsurface velocity structure is a challenging task, it can provide a description of the fault geometry as well as important information on the rheological changes caused by fault rupture. Our main objective is to investigate whether rheological changes of faults can be associated with the seismogenic process before a strong earthquake. For this purpose, a 3D tomographic technique is applied to obtain P- and S-wave velocity structures in central Taiwan using travel time data. The results show that temporal variations in the Vs structure in the source area demonstrate significant spatiotemporal variation before and after the Chi-Chi earthquake. We infer that, before the mainshock, Vs began to decrease (and Vp/Vs increased) at the hanging wall of the Chelungpu fault, which may be induced by the increasing density of microcracks and fluid. However, in the vicinity of the Chi-Chi earthquake’s source area, Vs increased (and Vp/Vs decreased), which may be attributed to the closing of cracks or migration of fluid. The different physical characteristics at the junctional zone may easily generate strong earthquakes. Therefore, seismic velocity changes are found to be associated with a subsurface evolution around the source area in Taiwan. Our findings suggest that monitoring the Vp and Vs (or Vp/Vs) structures in high seismic potential zones is an important ongoing task, which may minimize the damage caused by future large earthquakes.
Highlights
Changes in the physical properties of a fault zone before an earthquake rupture have become an important issue that scientists attempt to explore
This study aims to determine the impact of the Chi-Chi earthquake in central Taiwan before and after the event in order to understand the behavior of subsurface velocity structures
This research used travel time data for earthquake events compiled by the Central
Summary
Changes in the physical properties of a fault zone before an earthquake rupture have become an important issue that scientists attempt to explore. The most popular methods for the topic of earthquake precursors are ionospheric anomalies [1,2,3] and seismic activity [4,5]. They can include variations in rock properties or pore pressures during the inter-seismic period, but these characteristics still cannot be directly observed around the seismogenic zone. For the velocity structures of Vp and Vs, the Vp/Vs ratio is correlated to Poisson’s ratio; they are regarded as important parameters in research into crustal rock characteristics [6,7]. Poisson’s ratio reflects the porosity, degree of crushing, and hydraulic pressure of rock formation
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