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JOURNAL OF GEOPHYSICAL RESEARCH,
VOL. 109,
B10404,
doi:10.1029/2003JB002925,
2004
Controls of shear zone rheology and tectonic loading on postseismic creep
Laurent G. J. Montési
Woods Hole Oceanographic Institution, Woods Hole, Massachusetts, USA
Abstract
Postseismic deformation is well documented in geodetic data collected in the aftermath of large earthquakes. In the postseismic
time interval, GPS is most sensitive to creep in the lower crust or upper mantle activated by earthquake-generated stress
perturbations. In these regions, deformation may be localized on an aseismic frictional surface or on a ductile shear zone.
These two hypotheses imply specific rheologies and therefore time dependence of postseismic creep. Hence postseismic creep
constitutes a potential probe into the rheology of aseismic regions of the lithosphere. I present a simple shear zone model
of postseismic creep in which the rheology of the creeping element can be varied. In the absence of tectonic loading during
the postseismic time interval, the displacement history of the shear zone obeying a power law rheology with stress exponent
n follows an analytical relaxation curve parameterized by 1/n. For a frictional surface, postseismic creep follows the same relaxation law in the limit 1/n → 0. A rough estimate of the apparent stress exponent can be obtained from continuous GPS records. Application to data collected
after the 1994 Sanriku earthquake yields 1/n ∼ 0.1, which is consistent with dislocation creep mechanisms. However, the records of two other subduction zone events, the
2001 Peru event and the 1997 Kronotski earthquake, and a continental strike-slip earthquake, the 1999 İzmit earthquake, require
negative 1/n. Rather than characterizing the shear zone rheology, these negative exponents indicate that reloading of the shear zone by
tectonic forces is important. Numerical simulations of postseismic deformation with nonnegligible reloading produce curves
that are well fit by the generalized relaxation law with 1/n < 0, although the actual stress exponent of the rheology is positive. While this prevents rheology from being tightly constrained
by the studied GPS records, it indicates that reloading is important in the postseismic time interval. In other words, the
stress perturbation induced by an earthquake is comparable to the stress supported by ductile shear zones in the interseismic
period.
Received 2
December
2003;
accepted 22
July
2004;
published 8
October
2004.
Keywords: postseismic;
rheology;
stress.
Index Terms: 1242 Geodesy and Gravity: Seismic deformations (7205); 1236 Geodesy and Gravity: Rheology of the lithosphere and mantle (8160); 8159 Tectonophysics: Rheology—crust and lithosphere; 8164 Tectonophysics: Stresses—crust and lithosphere; 3220 Mathematical Geophysics: Nonlinear dynamics.
Read Full Article (file size: 2263043 bytes) Cited by
Citation: Montési, L. G. J.
(2004),
Controls of shear zone rheology and tectonic loading on postseismic creep,
J. Geophys. Res.,
109,
B10404,
doi:10.1029/2003JB002925.
Copyright 2004 by the American Geophysical Union.
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