Abstract
Abstract. The knowledge of the crustal strain rate tensor provides a description of geodynamic processes such as fault strain accumulation, which is an important parameter for seismic hazard assessment, as well as anthropogenic deformation. In the past two decades, the number of observations and the accuracy of satellite based geodetic measurements like GPS greatly increased, providing measured values of displacements and velocities of points. Here we present a method to obtain the full continuous strain rate tensor from dense GPS networks. The tensorial analysis provides different aspects of deformation, such as the maximum shear strain rate, including its direction, and the dilatation strain rate. These parameters are suitable to characterize the mechanism of the current deformation. Using the velocity fields provided by SCEC and UNAVCO, we were able to localize major active faults in Southern California and to characterize them in terms of faulting mechanism. We also show that the large seismic events that occurred recently in the study region highly contaminate the measured velocity field that appears to be strongly affected by transient postseismic deformation. Finally, we applied this method to coseismic displacement data of two earthquakes in Iceland, showing that the strain fields derived by these data provide important information on the location and the focal mechanism of the ruptures.
Highlights
The 1994, Mw=6.7 Northridge and the 1995, Mw=6.8 Kobe earthquakes caused unprecedented damage of more than US $ 40 billion and US $ 100 billion, respectively
We chose to apply the method to observations in Southern California, because (1) it is one of the most extensively instrumented areas of the world, (2) it has high density of known active faulting, (3) it is well understood from a geological and geophysical point of view
Tectonics in Southern California are dominated by the right lateral transcurrent plate boundary between the North American (NA) and Pacific plates
Summary
The 1994, Mw=6.7 Northridge and the 1995, Mw=6.8 Kobe earthquakes caused unprecedented damage of more than US $ 40 billion and US $ 100 billion, respectively This was considerably more than could have been expected by earthquakes of comparable moment magnitude in California and. These large damages were explained by the unexpectedly high magnitudes of these events for these particular areas (Smolka, 2007). These two events demonstrated in a dramatic way the shortcomings of traditional seismic hazard assessment, mainly based on probabilistic models derived from catalogs of regional seismicity and supplemented by additional geologic information only for known active faults In Kobe the fault was assumed to be related to low seismic hazard
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