Numerical modeling of poro-viscoelastic wave propagation in effective Biot media using a mixed grid finite difference frequency-space domain approach

Xu Liu; Stewart Greenhalgh

doi:10.1190/segam2018-2993286.1

Numerical modeling of poro-viscoelastic wave propagation in effective Biot media using a mixed grid finite difference frequency-space domain approach

Xu Liu^*
, Stewart Greenhalgh

^*Corresponding author for this work

Research output: Contribution to journal › Conference article › peer-review

Abstract

To approximate seismic wave propagation in double porosity media, the effective Biot governing equations with complex frequency dispersion characteristics are numerically solved using an upscaled poro-visoelastic approach. We compute the wavefields for solid particle velocity and fluid flux in the frequency domain using a mixed grid finite difference method. A homogeneous full space model with a single Cole-Cole relaxation function representing the attenuation mechanism is used to show that the numerical solutions match well the analytical solutions for source centre frequencies of 102 Hz to 104 Hz. The computed pore pressure wavefield for a two-layer porous model is used to further validate our numerical method.

Original language	English
Pages (from-to)	3813-3817
Number of pages	5
Journal	SEG Technical Program Expanded Abstracts
DOIs	https://doi.org/10.1190/segam2018-2993286.1
State	Published - 27 Aug 2018

Bibliographical note

Publisher Copyright:
© 2018 SEG

ASJC Scopus subject areas

Geotechnical Engineering and Engineering Geology
Geophysics

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10.1190/segam2018-2993286.1

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title = "Numerical modeling of poro-viscoelastic wave propagation in effective Biot media using a mixed grid finite difference frequency-space domain approach",

abstract = "To approximate seismic wave propagation in double porosity media, the effective Biot governing equations with complex frequency dispersion characteristics are numerically solved using an upscaled poro-visoelastic approach. We compute the wavefields for solid particle velocity and fluid flux in the frequency domain using a mixed grid finite difference method. A homogeneous full space model with a single Cole-Cole relaxation function representing the attenuation mechanism is used to show that the numerical solutions match well the analytical solutions for source centre frequencies of 102 Hz to 104 Hz. The computed pore pressure wavefield for a two-layer porous model is used to further validate our numerical method.",

author = "Xu Liu and Stewart Greenhalgh",

note = "Publisher Copyright: {\textcopyright} 2018 SEG",

year = "2018",

month = aug,

day = "27",

doi = "10.1190/segam2018-2993286.1",

language = "English",

pages = "3813--3817",

journal = "SEG Technical Program Expanded Abstracts",

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T1 - Numerical modeling of poro-viscoelastic wave propagation in effective Biot media using a mixed grid finite difference frequency-space domain approach

AU - Liu, Xu

AU - Greenhalgh, Stewart

PY - 2018/8/27

Y1 - 2018/8/27

N2 - To approximate seismic wave propagation in double porosity media, the effective Biot governing equations with complex frequency dispersion characteristics are numerically solved using an upscaled poro-visoelastic approach. We compute the wavefields for solid particle velocity and fluid flux in the frequency domain using a mixed grid finite difference method. A homogeneous full space model with a single Cole-Cole relaxation function representing the attenuation mechanism is used to show that the numerical solutions match well the analytical solutions for source centre frequencies of 102 Hz to 104 Hz. The computed pore pressure wavefield for a two-layer porous model is used to further validate our numerical method.

AB - To approximate seismic wave propagation in double porosity media, the effective Biot governing equations with complex frequency dispersion characteristics are numerically solved using an upscaled poro-visoelastic approach. We compute the wavefields for solid particle velocity and fluid flux in the frequency domain using a mixed grid finite difference method. A homogeneous full space model with a single Cole-Cole relaxation function representing the attenuation mechanism is used to show that the numerical solutions match well the analytical solutions for source centre frequencies of 102 Hz to 104 Hz. The computed pore pressure wavefield for a two-layer porous model is used to further validate our numerical method.

UR - https://www.scopus.com/pages/publications/85121809194

U2 - 10.1190/segam2018-2993286.1

DO - 10.1190/segam2018-2993286.1

M3 - Conference article

AN - SCOPUS:85121809194

SN - 1052-3812

SP - 3813

EP - 3817

JO - SEG Technical Program Expanded Abstracts

JF - SEG Technical Program Expanded Abstracts

ER -

Numerical modeling of poro-viscoelastic wave propagation in effective Biot media using a mixed grid finite difference frequency-space domain approach

Abstract

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