Effects of the traction-free surface with a rugged topography on seismic wave propagation: Numerical modelling

Xiuming Wang; Yi Zeng; Li-Yun Fu; Kevin Dodds

doi:10.1071/ASEG2001ab145

ISSN: 2202-0586
E-ISSN:

oa Effects of the traction-free surface with a rugged topography on seismic wave propagation: Numerical modelling
Authors Xiuming Wang^a, Yi Zeng^b, Li-Yun Fu^c and Kevin Dodds^d
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^a CSIRO Petroleum Po BOX 1130, Technology Park Bentley, WA6102 Australia Email: [email protected] ^b CSIRO Petroleum Po BOX 1130, Technology Park Bentley, WA6102 Australia Email: [email protected] ^c CSIRO Petroleum Po BOX 1130, Technology Park Bentley, WA6102 Australia Email: [email protected] ^d CSIRO Petroleum Po BOX 1130, Technology Park Bentley, WA6102 Australia Email: [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2001, Issue ASEG2001 - 15th Geophysical Conference, Dec 2001, p. 1 - 4
DOI: https://doi.org/10.1071/ASEG2001ab145
- Published online: 01 Dec 2001

Abstract

Understanding the impact of rugged topography on seismic data provides a means to design strategy to reduce or eliminate these effects from the seismic data. In this paper, the effect of rugged topography on synthetic seismic data is studied by using a finite-difference method with a velocity-stress staggered algorithm. Based on the FD algorithm, the imaging and vacuum methods are used to simulate the elastic wave propagation in flat and rugged traction-free interfaces for both acoustic and elastic models. Seismic waves in heterogeneous media with a rugged topography are numerically simulated, and the properties of the P- wave, S- wave, and Rayleigh wave along the topography are discussed. Shear waves, surface waves and their scattered events along the topographic surface are major contributions to the scattered energy propagating with slow velocities. Furthermore, effects of the topography on the synthetic seismic data are eliminated effectively by employing our proposed method based on full elastic wave theory. For removing the scattered waves from a near surface topography, the numerical simulation demonstrated that our method, taking into account shear and surface waves such as Rayleigh and Love waves, as well as P-waves, is very effective for synthetic data, provided the properties of the near surface with a rugged topography are known.

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References

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Wang, X. M., 2001, Seismic wave simulation in anisotropic media with heterogeneity using a high-order finite-difference method: The 5th SEGJ International Symposium of Imaging Technology, Tokyo, Japan.
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Article Type: Research Article

Keyword(s): finite difference; Rugged topography; scattered noises

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oa Effects of the traction-free surface with a rugged topography on seismic wave propagation: Numerical modelling

Abstract

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