Seismic Signatures of Fractured Reservoirs: Theory Versus Numerical Simulations

Guo, Junxin; Glubokovskikh, Stanislav; Gurevich, Boris; Rubino, J. Germán

doi:10.1071/aseg2018abp070

Cited by 2 publications

(1 citation statement)

References 14 publications

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“…Fractures are modeled by constitutive relationship in terms of fracture-induced anisotropy. Guo et al (2018) used the branch function method to construct finite-thickness fractures and examined the dispersion and attenuation of P-wave propagation perpendicular to the fracture surface. Lissa et al (2019) explored the impact of fractures with varying widths on seismic attenuation and velocity dispersion.…”

Section: Introductionmentioning

confidence: 99%

An improved wave equation of fractured-porous media for predicting reservoir permeability

Zhao,

Sun,

Gao

et al. 2023

Front. Earth Sci.

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The wave characteristics of fractured-porous media can be utilized for permeability identification; however, further research is necessary to enhance the accuracy of this identification. A novel wave equation for fractured-porous media is formulated, and theoretical analysis suggests its effectiveness in accurately identifying reservoir permeability. The proposed methodology establishes a wave equation for fractured-porous media using the volume averaging method and employs finite difference method on staggered grids to calculate wave field dispersion and attenuation, exploring the influence of fracture network structure and confining pressure on the solution of the wave equation. By analyzing the wave equation under various aspect ratios and confining pressure of fractures, it is observed that these factors significantly affect velocity and attenuation, providing valuable insights into seismic response in fractured-porous media. Furthermore, the research findings reveal promising potential in utilizing the new wave equations specific to fractured-porous media for permeability identification purposes. By constructing a three-dimensional fractured-porous network model, the wave equation for permeability identification can examine the correlation between the parameters of the equation and permeability, and establishes an association between fracture parameters and permeability, paving the way for a novel approach to permeability identification.

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Section: Introductionmentioning

confidence: 99%

An improved wave equation of fractured-porous media for predicting reservoir permeability

Zhao,

Sun,

Gao

et al. 2023

Front. Earth Sci.

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Effects of randomly orienting penny-shaped cracks on the elastic properties of transversely isotropic rocks

Han

Liu

et al. 2020

GEOPHYSICS

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Fractured reservoirs, as one kind of unconventional reservoirs, have great potential for oil and gas development, and their accurate characterization requires the development of rock physics models that better simulate real fractured rocks. However, current models focus mainly on the elastic properties of rocks with aligned cracks, while the effects of randomly orienting cracks in transversely isotropic (TI) rocks are poorly studied even though such conditions are frequently encountered in the Earth. To address this problem, we first derive models for the elastic properties of rocks with TI background permeated by three-dimensional (3-D) inclined cracks and randomly orienting cracks. Then, based on the developed models, we study comprehensively the effects of the two inclination angles (i.e., the dip angle between the cracks and the isotropic plane and the rotation angle between the cracks and the plane normal to the isotropic plane, respectively) of 3-D inclined cracks on the elastic properties of TI rocks. It is demonstrated that the two angles have significant influences on the elastic coefficients and hence the elastic velocities, and their influences on the elastic properties are varying in different directions. We further investigate the effects of crack density and aspect ratio of randomly orienting cracks on the elastic properties of the fractured rocks with TI background. The results show that the increasing crack density and crack aspect ratio both reduce the elastic coefficients and velocities for rocks with randomly orienting cracks, in which the relations between P-wave velocities and the crack properties (i.e., crack density and crack aspect ratio) are obtained to aid the interpretation of the acquired acoustic exploration data. The proposed new models can greatly improve the modeling capability for the elastic properties of rocks with TI background permeated by inclined and randomly orienting cracks.

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Seismic Signatures of Fractured Reservoirs: Theory Versus Numerical Simulations

Cited by 2 publications

References 14 publications

An improved wave equation of fractured-porous media for predicting reservoir permeability

An improved wave equation of fractured-porous media for predicting reservoir permeability

Effects of randomly orienting penny-shaped cracks on the elastic properties of transversely isotropic rocks

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