Effect of stress interactions on anisotropic P‐SV‐wave dispersion and attenuation for closely spaced cracks in saturated porous media

Cao, Chunwei; Chen, Fangyuan; Fu, Li‐Yun; Ba, Jing; Han, Tongcheng

doi:10.1111/1365-2478.13007

Cited by 6 publications

(4 citation statements)

References 40 publications

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“…This kind of difference are also observed in previous studies, (e.g. Guo et al, 2018a;Guo et al, 2018b;Cao et al, 2019;Cao et al, 2020).…”

Section: Discussionsupporting

confidence: 87%

“…The comparisons between the results of FEM simulation (circle) and the Gassmann equation (square) show that the bulk moduli calculated by FEM simulation are less than those from Gassmann equation with a constant value. This kind of difference may be caused by the interaction between the fractures, which is as also observed by Zhao et al (2016); Guo et al (2018a); Guo et al (2018b); Cao et al (2019); Cao et al (2020); Zhao et al (2020) have also used the stress amplification and stress shielding to explain the influence of the interaction.…”

Section: Elastic Moduli Of Samples Saturated With Watermentioning

confidence: 91%

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Roughness Effects of Crack Surfaces on the Elastic Moduli of Cracked Rocks

Han

et al. 2021

Front. Earth Sci.

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Crack surfaces are usually rough on various scales, and are sensitive to loading stresses and hence significantly affecting the mechanical properties of cracked rocks. We design a number of dry- and fluid-saturated numerical cracked samples to investigate the roughness influence of crack surfaces on the elastic stiffness. The fracture surface roughness is characterized by non-uniform fracture radii. We calculate the elastic moduli of cracked samples by finite-element simulation. Comparisons with the theoretical predictions by Gassmann and C&S (Ciz and Shapiro) (Ciz and Shapiro, Geophysics, 2007, 72(6), A75–A79) substitution equations demonstrate that the rough crack surfaces for both dry- and fluid-saturated samples can induce a stress concentration around the crack that reduces the elastic moduli and decreases the stiffness of rocks. For the fluid/solid-saturated cracks under the normal (shear) loading stresses, because the stress-concentration can induce shear (normal) strains around fracture, shear (bulk) modulus of the filling material will have contributions to the effective bulk (shear) modulus of rocks. The extra contribution, however, makes the Gassmann equation and C&S equation invalid.

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“…This kind of difference are also observed in previous studies, (e.g. Guo et al, 2018a;Guo et al, 2018b;Cao et al, 2019;Cao et al, 2020).…”

Section: Discussionsupporting

confidence: 87%

Section: Elastic Moduli Of Samples Saturated With Watermentioning

confidence: 91%

Roughness Effects of Crack Surfaces on the Elastic Moduli of Cracked Rocks

Han

et al. 2021

Front. Earth Sci.

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“…In this part, we apply Rubino's 2D method to a 3D cracked medium [30]. The governing Equations ( 1)- (11) would remain the same.…”

Section: D Oscillatory Relaxation Testsmentioning

confidence: 99%

“…Rubino et al [25,26] employed 2D numerical oscillatory relaxation experiments to study the frequency-dependent effective stiffness matrix using the least-squares optimal approach. The method is used to characterize the frequency-and incidence-angle-dependent attenuation and velocity dispersion in cracked porous media for the P wave [27][28][29] and P-SV wave [30]. Jian et al [31] expanded Rubino's relaxation tests to a three-dimensional (3D) case for computing the equivalent stiffness matrix.…”

Section: Introductionmentioning

confidence: 99%

Anisotropic Effective Elastic Properties for Multi-Dimensional Fractured Models

Jian

Cheng

2022

Applied Sciences

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The size, distribution, and orientation of fractures are generally multiscale and multi-dimensional in nature, leading to complex anisotropic characteristics. Theoretical or semi-analytical methods to determine the effective elastic properties depend on several assumptions, including the absence of the stress interaction and idealized fractures. On the basis of finite-element models, we conduct numerical oscillatory relaxation tests for determining the effective elastic properties of fractured rocks. The numerical approach for calculating equivalent stiffness tensors in two-dimensions is compared to the theoretical models for different fracture densities. Due to fracture interactions at high fracture densities, the suggested model makes a physical prediction. The effective elastic properties obtained from the application to a real fractured model, established from an outcrop, obviously disperse at different frequencies, which can be used to investigate fracture interactions and dynamic stress disturbances. The algorithm is extended to three-dimensional cases and also validated by using conventional effective medium theories. It is found that the fracture density obviously impacts the effective anisotropy properties, and the proposed method gives a reasonable prediction for high-fracture density. This work is significant because it enables the calculation of effective elastic properties of multi-dimensional fractured models and the fracture interaction mechanism.

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