Numerical investigation of implementation of air-earth boundary by acoustic-elastic boundary approach

The need for incorporating the traction-free condition at the air-earth boundary for finite-difference modeling of seismic wave propagation has been discussed widely. A new implementation has been developed for simulating elastic wave propagation in which the free-surface condition is replaced by an explicit acoustic-elastic boundary. Detailed comparisons of seismograms with different implementations for the air-earth boundary were undertaken using the (2,2) (the finite-difference operators are second order in time and space) and the (2,6) (second order in time and sixth order in space) standard staggered-grid (SSG) schemes. Methods used in these comparisons to define the air-earth boundary included the stress image method (SIM), the heterogeneous approach, the scheme of modifying material properties based on transversely isotropic medium approach, the acoustic-elastic boundary approach, and an analytical approach. The method proposed achieves the same or higher accuracy of modeled body waves relative to the SIM. Rayleigh waves calculated using the explicit acoustic-elastic boundary approach differ slightly from those calculated using the SIM. Numerical results indicate that when using the (2,2) SSG scheme for SIM and our new method, a spatial step of 16 points per minimum wavelength is sufficient to achieve 90% accuracy; 32 points per minimum wavelength achieves 95% accuracy in modeled Rayleigh waves. When using the (2,6) SSG scheme for the two methods, a spatial step of eight points per minimum wavelength achieves 95% accuracy in modeled Rayleigh waves. Our proposed method is physically reasonable and, based on dispersive analysis of simulated seismographs from a layered half-space model, is highly accurate. As a bonus, our proposed method is easy to program and slightly faster than the SIM.

[1]  J. Kristek,et al.  3D Heterogeneous Staggered-grid Finite-difference Modeling of Seismic Motion with Volume Harmonic and Arithmetic Averaging of Elastic Moduli and Densities , 2002 .

[2]  R. W. Knapp Observations of the air-coupled wave as a function of depth , 1986 .

[3]  Jianghai Xia,et al.  Generating an Image of Dispersive Energy by Frequency Decomposition and Slant Stacking , 2007 .

[4]  J. Zahradník,et al.  Heterogeneous formulations of elastodynamic equations and finite-difference schemes , 1995 .

[5]  Rune Mittet,et al.  Free-surface boundary conditions for elastic staggered-grid modeling schemes , 2002 .

[6]  Erik H. Saenger,et al.  Accuracy of heterogeneous staggered-grid finite-difference modeling of Rayleigh waves , 2006 .

[7]  L. Knopoff,et al.  Fast Surface Wave and Free Mode Computations , 1972 .

[8]  J. Carcione,et al.  Long-wave anisotropy in stratified media: A numerical test , 1991 .

[9]  J. Virieux P-SV wave propagation in heterogeneous media: Velocity‐stress finite‐difference method , 1986 .

[10]  K. Holliger,et al.  The non-geometric ̄P S wave in high-resolution seismic data: observations and modelling , 2000 .

[11]  Robert W. Graves,et al.  Simulating seismic wave propagation in 3D elastic media using staggered-grid finite differences , 1996, Bulletin of the Seismological Society of America.

[12]  G. W. Postma Wave propagation in a stratified medium , 1955 .

[13]  L. Thomsen,et al.  75-plus years of anisotropy in exploration and reservoir seismics: A historical review of concepts and methods , 2005 .

[14]  J. B. Harris,et al.  Comparing Shear-Wave Velocity Profiles from MASW with Borehole Measurements in Unconsolidated Sediments, Fraser River Delta, B.C., Canada , 2000 .

[15]  Maurice Ewing,et al.  Ground roll coupling to atmospheric compressional waves , 1951 .

[16]  G. Backus Long-Wave Elastic Anisotropy Produced by Horizontal Layering , 1962 .

[17]  Johan O. A. Robertsson,et al.  A numerical free-surface condition for elastic/viscoelastic finite-difference modeling in the presence of topography , 1996 .

[18]  S. Shapiro,et al.  Modeling the propagation of elastic waves using a modified finite-difference grid , 2000 .

[19]  Peter Moczo,et al.  Efficient Methods to Simulate Planar Free Surface in the 3D 4th-Order Staggered-Grid Finite-Difference Schemes , 2002 .

[20]  A. Levander Fourth-order finite-difference P-SV seismograms , 1988 .