Quasi-spherical approach for seismic wave modeling in a 2-D slice of a global Earth model with lateral heterogeneity

Genti Toyokuni; Hiroshi Takenaka; Yanbin Wang; Brian L.N. Kennett

doi:10.1029/2004GL022180

Quasi-spherical approach for seismic wave modeling in a 2-D slice of a global Earth model with lateral heterogeneity

Genti Toyokuni, Hiroshi Takenaka, Yanbin Wang, Brian L.N. Kennett

Research output: Contribution to journal › Article › peer-review

19 Citations (Scopus)

Abstract

For iterative calculations of synthetic seismograms with limited computer resources, a fast and accurate modeling method is needed. Axisymmetric modeling has often been used in global seismology to restrict computational time and storage. This approach can correctly model 3-D geometrical spreading effects with computational times comparable to 2-D methods, but cannot treat asymmetric structures about the source axis. To overcome this problem, a new approach is proposed for seismic wave propagation in a 2-D slice through a global Earth model with lateral heterogeneity. The elastodynamic equation for spherical coordinates is not solved in the conventional spherical domain but instead in the "quasi-spherical domain" using the finite-difference method. The validity and efficiency of this technique is illustrated with numerical examples including subduction zone structures.

Original language	English
Pages (from-to)	1-4
Number of pages	4
Journal	Geophysical Research Letters
Volume	32
Issue number	9
DOIs	https://doi.org/10.1029/2004GL022180
Publication status	Published - 2005 May 16
Externally published	Yes

ASJC Scopus subject areas

Geophysics
Earth and Planetary Sciences(all)

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AU - Toyokuni, Genti

AU - Takenaka, Hiroshi

AU - Wang, Yanbin

AU - Kennett, Brian L.N.

PY - 2005/5/16

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N2 - For iterative calculations of synthetic seismograms with limited computer resources, a fast and accurate modeling method is needed. Axisymmetric modeling has often been used in global seismology to restrict computational time and storage. This approach can correctly model 3-D geometrical spreading effects with computational times comparable to 2-D methods, but cannot treat asymmetric structures about the source axis. To overcome this problem, a new approach is proposed for seismic wave propagation in a 2-D slice through a global Earth model with lateral heterogeneity. The elastodynamic equation for spherical coordinates is not solved in the conventional spherical domain but instead in the "quasi-spherical domain" using the finite-difference method. The validity and efficiency of this technique is illustrated with numerical examples including subduction zone structures.

AB - For iterative calculations of synthetic seismograms with limited computer resources, a fast and accurate modeling method is needed. Axisymmetric modeling has often been used in global seismology to restrict computational time and storage. This approach can correctly model 3-D geometrical spreading effects with computational times comparable to 2-D methods, but cannot treat asymmetric structures about the source axis. To overcome this problem, a new approach is proposed for seismic wave propagation in a 2-D slice through a global Earth model with lateral heterogeneity. The elastodynamic equation for spherical coordinates is not solved in the conventional spherical domain but instead in the "quasi-spherical domain" using the finite-difference method. The validity and efficiency of this technique is illustrated with numerical examples including subduction zone structures.

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Quasi-spherical approach for seismic wave modeling in a 2-D slice of a global Earth model with lateral heterogeneity

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