1887
ASEG2001 - 15th Geophysical Conference
  • ISSN: 2202-0586
  • E-ISSN:

Abstract

I study the attenuation of an elastic wave propagating in a macroscopic heterogeneous poroelastic medium due to the scattering (conversion) of the passing wave’s energy into the highly attenuative Biot’s slow wave. This is done by studying two particular geometrical configurations: (1) a thinly-layered porous medium and (2) porous saturated medium with ellipsoidal inclusions. The frequency dependence of the so-called mode-conversion attenuation has the form of a relaxation peak, with the maximum of the dimensionless attenuation (inverse quality factor) at a frequency at which the wavelength of the Biot’s slow wave is approximately equal to the characteristic length of the medium (layer thickness or size of the inclusion). The width and the precise shape of this relaxation peak depend on the particular geometrical configuration. Physically, the mode-conversion attenuation is associated with wave-induced flow of the pore fluid across the interfaces between the host medium and the inclusions. The results of our study demonstrate how the local flow (or squirt) attenuation can be effectively modeled within the context of Biot’s theory of poroelasticity.

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2001-12-01
2026-01-13

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References

  1. Berryman, J. G., 1985, Scattering by a spherical inhomogeneity in a fluid-saturated porous medium. Journal of Mathematical Physics 26: 1408-1419.
  2. Biot, M.A., 1962, Mechanics of deformation and acoustic propagation in porous media. Journal of Applied Physics 33: 1482-1498.
  3. Bourbie, T., Coussy, O., and Zinszner 1987, Acoustics of Porous Media. Paris: Technip.
  4. Gelinsky, S., Shapiro, S.A. , Mueller, T, and Gurevich, B., 1997, Dynamic poroelasticity of thinly layered structures: International Journal of Solids and Structures, 35, 4739-4751.
  5. Gurevich, B., Sadovnichaja, A.P., Lopatnikov, S.L., and Shapiro, S.A. 1998, Scattering of a compressional wave in a poroelastic medium by an ellipsoidal inclusion: Geophysical Journal International, 133, 91-103.
  6. Gurevich, B. and Lopatnikov, S.L. 1995. Velocity and attenuation of elastic waves in finely layered porous rocks: Geophysical Journal International, 121, 933-947.
  7. Gubernatis, J.E., Domany, E., and Krumhansl, J.A., 1977a, Formal aspects of the theory of the scattering of ultrasound by flaws in elastic materials: Journal of Applied Physics, 48: 2804-2811.
  8. Gubernatis, J.E., Domany, E., Krumhansl, J.A., and Huberman, M. 1977b, The Born approximation of the theory of the scattering of ultrasound by flaws in elastic materials: Journal of Applied Physics, 48: 2812-2819.
  9. Lopatnikov, S.L. and Gurevich B. 1986, Attenuation of elastic waves in a randomly inhomogenous saturated porous medium: Doklady Earth Science Sections, 291, 19-22.
  10. Norris, A.N. 1985, Radiation from a point source and scattering theory in a fluid-saturated porous solid: Journal of the Acoustical Society of America, 77, 2012-2023.
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  • Article Type: Research Article
Keyword(s): attenuation; heterogeneity; permeability; porous media; scattering

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