Anisotropic Permeability Influencing the Performance of Free CH4 and Free CO2 during the Process of CO2 Sequestration and Enhanced Gas Recovery (CS-EGR) from Shale

Zhao, Peng; Xie, Lingzhi; He, Bo; Liu, Jun

doi:10.1021/acssuschemeng.0c08058

Cited by 16 publications

(13 citation statements)

References 39 publications

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“…Anisotropy can trigger the existence of groundwater whirls [19,20] that may have a large influence on reactive transport and dilution processes. Anisotropy can impact the efficiency of greenhouse gases (such as CO 2 ), sequestration in deep geological formations [21], and heat extraction by geothermal boreholes [22].…”

Section: Introductionmentioning

confidence: 99%

Equivalent Permeability Tensor of Heterogeneous Media: Upscaling Methods and Criteria (Review and Analyses)

Renard

Ababou

2022

Geosciences

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When conducting numerical upscaling, either for a fractured or a porous medium, it is important to account for anisotropy because in general, the resulting upscaled conductivity is anisotropic. Measurements made at different scales also demonstrate the existence of anisotropy of hydraulic conductivity. At the “microscopic” scale, the anisotropy results from the preferential flatness of grains, presence of shale, or variation of grain size in successive laminations. At a larger scale, the anisotropy results from preferential orientation of highly conductive geological features (channels, fracture families) or alternations of high and low conductive features (stratification, bedding, crossbedding). Previous surveys of homogenization techniques demonstrate that a wide variety of approaches exists to define and calculate the equivalent conductivity tensor. Consequently, the resulting equivalent conductivities obtained by these different methods are not necessarily equal, and they do not have the same mathematical properties (some are symmetric, others are not, for example). We present an overview of different techniques allowing a quantitative evaluation of the anisotropic equivalent conductivity for heterogeneous porous media, via numerical simulations and, in some cases, analytical approaches. New approaches to equivalent permeability are proposed for heterogeneous media, as well as discontinuous (composite) media, and also some extensions to 2D fractured networks. One of the main focuses of the paper is to explore the relations between these various definitions and the resulting properties of the anisotropic equivalent conductivity, such as tensorial or non-tensorial behavior of the anisotropic conductivity; symmetry and positiveness of the conductivity tensor (or not); dual conductivity/resistivity tensors; continuity and robustness of equivalent conductivity with respect to domain geometry and boundary conditions. In this paper, we emphasize some of the implications of the different approaches for the resulting equivalent permeabilities.

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Section: Introductionmentioning

confidence: 99%

Equivalent Permeability Tensor of Heterogeneous Media: Upscaling Methods and Criteria (Review and Analyses)

Renard

Ababou

2022

Geosciences

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“…143 Zhao et al established a coupled thermo-hydro-mechanical (THM) model to investigate the effect of permeability on gases in fractured shale reservoirs, and confirmed that matrix rocks and natural fractures are highly dependent on stress. 144 3.2.2. Pore Network Modeling.…”

Section: Diffusion and Flowmentioning

confidence: 99%

“…Wei et al established shale double effective stress for organic matter, matrix pores, natural fractures, and discrete artificial fractures, and the influence of rock deformation on shale gas flow between matrix and fracture was analyzed . Zhao et al established a coupled thermo-hydro-mechanical (THM) model to investigate the effect of permeability on gases in fractured shale reservoirs, and confirmed that matrix rocks and natural fractures are highly dependent on stress …”

Section: Multiscale Flow Simulationmentioning

confidence: 99%

Recent Advances in Multiscale Digital Rock Reconstruction, Flow Simulation, and Experiments during Shale Gas Production

Yang

Zhang

et al. 2023

Energy Fuels

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The complex and multiscale nature of shale gas transport imposes new challenges to the already well-developed techniques for conventional reservoirs, especially digital core analysis. Multiscale complicated pore systems and distinctive properties limit most reconstruction methods not applicable. High-precision imaging experiments play a key role in the characterization of pore structures and mineral components. While the exhilarating breakthroughs in physical experimental methods and hybrid superposition methods have made significant achievements in shale digital rock reconstruction, rapidly evolving deep learning methods also present a promising option. Benefiting from the digital rock techniques, the pore-scale flow of shale gas can be directly simulated based on digital rock or indirectly modeled using the pore network model. It is precise and realistic to investigate the shale gas flow at the pore scale considering the desorption, surface diffusion, and slippage in nanopores. In this paper, we reviewed the recent advances in off-mentioned methods and processes and presented a hand for the research in this field.

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“…At present, the type of gas storage in China is vertical, that is, the vertical span of the solution chamber is greater than the horizontal span [15,16]. Compared with the salt mounds in other countries which are particularly thick, the salt rock deposits in China are typically thin in single layers and many in interlayers [17] because in the underground storage of salt rock, the wall of the cavity is often under alternating and cyclic load; that is, the internal pressure of the reservoir uctuates circularly between the minimum and maximum, and the fatigue microcracks can occur in the surrounding rock of cavities [18][19][20]. After that, the micro fractures gradually expanded, evolved, and penetrated with time, and macro fractures are formed nally.…”

Section: Introductionmentioning

confidence: 99%

Creep Fracture Characteristics and the Constitutive Model of Salt Rock under a Coupled Thermo-Mechanical Environment

Wang

Liang

Guangwu

et al. 2022

Mathematical Problems in Engineering

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The fracture extension characteristics of salt rocks under creep play an important role in the long-term safety and stability assessment of underground compressed air storage reservoirs. To study the fracture evolution characteristics of salt rock with time, the present study modified the Charles creep fracture intrinsic model and calibrated the A and n of the fracture extension coefficient parameters by creep fracture experiments with a constant stress rate loading method for salt rock under different temperature conditions. Finally, the modified Charles model was embedded into PFC (particle flow code) to simulate the fracture of salt rock numerically and the results were verified theoretically. The results show that (1) the fracture extension rate is related to the parameters A and n in addition to the stress intensity factor; (2) both n and A gradually decrease with the increase of temperature, and an decrease of n and A represents the decrease of fracture creep extension rate; and (3) the longer the initial fracture length of the specimen, the smaller the fracture time. The results of this study can provide theoretical guidance for evaluating the confinement of underground compressed air storage reservoirs.

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Anisotropic Permeability Influencing the Performance of Free CH₄ and Free CO₂ during the Process of CO₂ Sequestration and Enhanced Gas Recovery (CS-EGR) from Shale

Cited by 16 publications

References 39 publications

Equivalent Permeability Tensor of Heterogeneous Media: Upscaling Methods and Criteria (Review and Analyses)

Equivalent Permeability Tensor of Heterogeneous Media: Upscaling Methods and Criteria (Review and Analyses)

Recent Advances in Multiscale Digital Rock Reconstruction, Flow Simulation, and Experiments during Shale Gas Production

Creep Fracture Characteristics and the Constitutive Model of Salt Rock under a Coupled Thermo-Mechanical Environment

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