Adsorption Models for Shale Gas: A Mini-Review

Liang, Hongbin; Zhou, Qi; Wang, Shuai; Huang, Xiaoliang; Yan, Wende; Yuan, Yingzhong; Li, Zhiqiang

doi:10.1021/acs.energyfuels.2c02885

Cited by 9 publications

(7 citation statements)

References 137 publications

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“…Real shale reservoirs have temperature and pressure gradient variations with depth, which have a great influence on gas adsorption. − Previous results showed that the gas adsorption capacity decreases with increasing temperature, while the adsorption capacity increases with rising pressure and its growth rate decreases gradually. , Thus, the shale gas displacement by CO 2 -rich industrial waste gas components at shale reservoir depths of 0.25–4.0 km is shown in Figure . In all of the simulations, the concentration of each gas injection was the same as the CH 4 concentration at all reservoir depths.…”

Section: Resultsmentioning

confidence: 95%

Molecular Insights into CO₂-Rich Industrial Waste Gas Enhanced Shale Gas Recovery and Sequestration in Real Shale Gas Reservoirs

Zhang,

Li,

Xin

et al. 2023

Energy Fuels

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In response to the current carbon-neutral policy, the appropriate utilization and sequestration of CO 2 -rich industrial waste gases have become a key concern in greenhouse gas management. In this work, the application of CO 2 -rich industrial waste gas for shale gas displacement and the feasibility of shale gas reservoirs as a site for CO 2rich industrial waste gas sequestration was investigated from the molecular-scale. In order to restore the extensive pore structure and complex composition of shale reservoirs, three shale slit models were developed based on the Longmaxi shale formation in Sichuan, China, with the compositions of quartz-kerogen (QK), illite-kerogen (IK), and calcite-kerogen (CK). The CH 4 displacement effect by each gas component injection in the shale slits under real reservoir conditions were studied. The results show that the gas adsorption capacities in all shale slits are ranked as SO 2 > CO 2 > NO > N 2 ≈ CH 4 > CO in the pressure range of 0.5−30 MPa. Triatomic gas molecules, including SO 2 and CO 2 , have larger molecular diameters and more intense competitive adsorption between molecules, leading to a decrease in the CH 4 displacement effect with reservoir depth. CO 2 -rich industrial waste gas in depleted shale gas reservoirs at varied water contents was investigated. It was found that an increase in water content from 0% to 4 wt % led to a decrease in CO 2 sequestration capacity and relative stability ratio of 0.52 mmol/g and 0.068, respectively, at a depth of 2 km in IK slit. The QK slit is ideal for large quantities of nontoxic exhaust gas sequestration, whereas the CK slit is suitable as a site for sequestering CO 2 -rich industrial waste gas with a relatively high level of hazardous gas. This study provides deep insights into the mechanisms of competitive adsorption and sequestration in shale slits, which is instructive for CO 2 -rich industrial waste gas enhanced recovery of shale gas and sequestration.

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Section: Resultsmentioning

confidence: 95%

Molecular Insights into CO₂-Rich Industrial Waste Gas Enhanced Shale Gas Recovery and Sequestration in Real Shale Gas Reservoirs

Zhang,

Li,

Xin

et al. 2023

Energy Fuels

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“…The pore water of shales has a significant effect on the GIP content. It not only occupies some pore space, affecting the free gas content but also adsorbs on some hydrophilic pore walls, reducing the adsorbed gas content. − In addition, pore water may completely occupy or block some nanopores, such as OM and IM micropores with pore widths less than 0.5 nm, , which is adverse to the accumulation of shale gas. Although deep shales generally have a low C PW , the water-bearing characteristics of the shales remarkably affect their GIP contents.…”

Section: Discussionmentioning

confidence: 99%

Gas-In-Place Content of Deep Shales and Its Main Controlling Factors: A Case Study on the Wufeng-Longmaxi Shales in the Middle Luzhou Block of the Southern Sichuan Basin, China

Wu¹,

Cheng

Luo³

et al. 2023

Energy Fuels

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Deep shale gas (>3500 m) is a promising fossil energy resource in the context of global efforts to achieve carbon neutrality. However, the accumulation, enrichment, and distribution of deep shale gas are complicated, which makes the gas-inplace (GIP) content and its main controlling factors of deep shales unclear. In this study, a group of deep shale samples with burial depths of 4200−4350 m were collected from the Wufeng-Longmaxi (WF-LMX) formations from the middle Luzhou block, southern Sichuan Basin, and the TOC contents, mineralogical compositions, porosities, pore water contents, water saturations, and GIP contents of the shales were systematically investigated. The results indicate that the TOC and brittle mineral contents, water-bearing characteristics, and effective porosities are the main factors controlling the GIP contents of deep shales. The deep WF-LMX shales in the middle Luzhou block have high TOC and brittle mineral contents, low pore water content (C PW ), and water saturation (S W ), and great effective porosity, which benefits the generation, storage, and development of shale gas. The GIP contents of the deep WF-LMX shales are in the range of 1.36−7.17 cm 3 /g and are higher for the shales located in the lower sublayer of the first member of the Longmaxi formation (LMX1 1−3 ). In general, the deep WF-LMX shales in the middle Luzhou block have advantageous reservoir properties and GIP contents, which indicate great shale gas potential, and the LMX1 1−3 shales are the most promising exploration and development targets.

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“…Porous matrixes can be further divided into organic matter and inorganic matter. As nanopores inside the organic matter have extremely large internal surface area with strong affinity to methane, up to 20–85% of total shale gas initially in place could be adsorbed gas. − The production of this gas in place is strongly influenced by shale permeability. During the gas extraction process, reservoir pressure gradually declines, leading to an effective stress increase, rock compaction, and intrinsic permeability change.…”

Section: Introductionmentioning

confidence: 99%

A Review of Swelling Effect on Shale Permeability: Assessments and Perspectives

et al. 2023

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The significant effect of gas sorption induced swelling on shale permeability has been observed through laboratory measurements and explained through permeability models over the past decades. However, there are lab observations that cannot be explained by these models. This knowledge gap prompts this review. Our goal is to form perspectives on how to resolve this gap through assessing the role of swelling on shale permeability. This goal is achieved through the following three steps: (1) collection of experimental shale permeability data measured under both constant effective stress and constant confining pressure conditions; (2) collection and classification of shale permeability models under the influence of gas sorption induced swelling strains; (3) assessments of co-relations between shale permeability data and permeability models. On the basis of all assessments, we conclude that the discrepancies between model predictions and laboratory measurements depend on the relation between bulk and pore swelling strains, pore size scales, and consistencies of strain treatments in the experiments and models. Models assuming that bulk swelling strain is different from pore swelling strain can better explain lab observations than those assuming that they are the same. When the pore size transitions from the micron-scale to the nano-scale, the effect of swelling on shale permeability gradually diminishes. The inconsistencies between how swelling strains are measured in the lab and treated in the models are common in the literatures and affect the discrepancies between model predictions and lab observations. On the basis of these assessments, we form our perspectives: (1) transformation between bulk and pore swelling strains should be characterized and incorporated both for experiments and in permeability models; (2) shale multiscale pore structural characteristics should be characterized when assessing the swelling effect on shale permeability; (3) the time-dependent nature of swelling strain and permeability evolution should be incorporated into future experiments and permeability models.

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Adsorption Models for Shale Gas: A Mini-Review

Cited by 9 publications

References 137 publications

Molecular Insights into CO₂-Rich Industrial Waste Gas Enhanced Shale Gas Recovery and Sequestration in Real Shale Gas Reservoirs

Molecular Insights into CO₂-Rich Industrial Waste Gas Enhanced Shale Gas Recovery and Sequestration in Real Shale Gas Reservoirs

Gas-In-Place Content of Deep Shales and Its Main Controlling Factors: A Case Study on the Wufeng-Longmaxi Shales in the Middle Luzhou Block of the Southern Sichuan Basin, China

A Review of Swelling Effect on Shale Permeability: Assessments and Perspectives

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Adsorption Models for Shale Gas: A Mini-Review

Cited by 9 publications

References 137 publications

Molecular Insights into CO2-Rich Industrial Waste Gas Enhanced Shale Gas Recovery and Sequestration in Real Shale Gas Reservoirs

Molecular Insights into CO2-Rich Industrial Waste Gas Enhanced Shale Gas Recovery and Sequestration in Real Shale Gas Reservoirs

Gas-In-Place Content of Deep Shales and Its Main Controlling Factors: A Case Study on the Wufeng-Longmaxi Shales in the Middle Luzhou Block of the Southern Sichuan Basin, China

A Review of Swelling Effect on Shale Permeability: Assessments and Perspectives

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Molecular Insights into CO₂-Rich Industrial Waste Gas Enhanced Shale Gas Recovery and Sequestration in Real Shale Gas Reservoirs

Molecular Insights into CO₂-Rich Industrial Waste Gas Enhanced Shale Gas Recovery and Sequestration in Real Shale Gas Reservoirs