Hsu, Ya-Ju and Simons, Mark and Williams, Charles and Casarotti, Emanuele (2011) Three-dimensional FEM derived elastic Green's functions for the coseismic deformation of the 2005 M_w 8.7 Nias-Simeulue, Sumatra earthquake. Geochemistry Geophysics Geosystems, 12 (7). Art. No. Q07013. ISSN 1525‐2027. http://resolver.caltech.edu/CaltechAUTHORS:20110805-140619974
- Published Version
See Usage Policy.
Use this Persistent URL to link to this item: http://resolver.caltech.edu/CaltechAUTHORS:20110805-140619974
Using finite element models (FEMs), we examine the sensitivity of surface displacements to the location of fault slip, topography, and three-dimensional variations in elastic moduli in the context of a 2-D infinite thrust fault. We then evaluate the impact of these factors and fault geometry on surface displacements and estimates of the distribution of coseismic slip associated with the 2005 M_w 8.7 Nias-Simeulue, Sumatra earthquake. Topographic effects can be significant near the trench, where bathymetric gradients are highest and the fault is closest to the free surface. Variations in Young's modulus can significantly alter predicted deformation. Surface displacements are relatively insensitive to perturbations in Poisson's ratio for shear sources, but may play a stronger role when the source has a dilatational component. If we generate synthetic displacements using a heterogeneous elastic model and then use an elastic half-space or layered earth model to estimate the slip distribution and fault geometry, we find systematic residuals of surface displacements and different slip patterns compared to the input fault slip model. The coseismic slip distributions of the 2005 earthquake derived from the same fault geometry and different material models show that the rupture areas are narrower in all tested heterogeneous elastic models compared to that obtained using half-space models. This difference can be understood by the tendency to infer additional sources in elastic half-space models to account for effects that are intrinsically due to the presence of rheological gradients. Although the fit to surface observations in our preferred 3-D FEM model is similar to that from a simple half-space model, the resulting slip distribution may be a more accurate reflection the true fault slip behavior.
|Additional Information:||© 2011 by the American Geophysical Union. Received 7 February 2011; Revised 31 May 2011; Accepted 31 May 2011; Published 20 July 2011. We thank the Editor, Thorsten Becker, and two reviewers, Tim Masterlark and an anonymous reviewer, for their thoughtful reviews and valuable comments that helped to improve the manuscript. This study was supported by the Institute of Earth Sciences, Academia Sinica, the National Science Council of the Republic of China grant NSC 98‐2119‐M‐001‐033‐MY3. This is a contribution of the Institute of Earth Sciences, Academia Sinica, IESAS1590, Caltech Seismological Laboratory contribution number 10061, and Caltech Tectonics Observatory contribution number 175.|
|Group:||Caltech Tectonics Observatory|
|Subject Keywords:||Green’s functions; coseismic deformation; finite element model|
|Other Numbering System:|
|Classification Code:||1242 Geodesy and Gravity: Seismic cycle related deformations (6924, 7209, 7223, 7230); 8159 Tectonophysics: Rheology: crust and lithosphere (8031); 8170 Tectonophysics: Subduction zone processes (1031, 3060, 3613, 8413).|
|Official Citation:||Hsu, Y.-J., M. Simons, C. Williams, and E. Casarotti (2011), Three‐dimensional FEM derived elastic Green’s functions for the coseismic deformation of the 2005 Mw 8.7 Nias‐Simeulue, Sumatra earthquake, Geochem. Geophys. Geosyst., 12, Q07013, doi:10.1029/2011GC003553|
|Usage Policy:||No commercial reproduction, distribution, display or performance rights in this work are provided.|
|Deposited By:||Tony Diaz|
|Deposited On:||06 Oct 2011 21:13|
|Last Modified:||23 Aug 2016 00:03|
Repository Staff Only: item control page