4.7 Article

Chemical-mechanical coupling effects on the permeability of shale subjected to supercritical CO2-water exposure

期刊

ENERGY
卷 248, 期 -, 页码 -

出版社

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.energy.2022.123591

关键词

Carbon dioxide sequestration; Shale gas; CO2 -Water-shale interaction; Permeability; Chemical-mechanical coupling effects

资金

  1. National Natural Science Foundation of China [51774060, 52174107, U19B2009]
  2. Basic Research and Frontier Exploration Projects in Chongqing [cstc2019yszx-jcyjX00 07]
  3. National Basic Research Program of China [2014CB239204]
  4. Program for Changjiang Scholars and Innovative Research Team in University [IRT_17R112]

向作者/读者索取更多资源

This study investigates the impact of ScCO2-water exposure on shale properties and reveals the changes in mineral composition, pore structure, and mechanical properties due to the chemical-mechanical interaction. The results indicate that the interaction leads to changes in shale porosity and permeability, with chemical reactions increasing the porosity in unstressed conditions and the chemical-mechanical coupling effects decreasing the permeability in stressed conditions. The findings highlight the importance of understanding the chemical-mechanical processes in shale for optimizing gas recovery and CO2 sequestration.
The permeability of shale reservoir rock and caprock is the key parameters influencing the shale gas production and the storage security of CO2. During the CO2 enhanced shale gas recovery, the issue of how the coupled chemical-mechanical process control the evolution of porosity and permeability in shale remains undetermined. In this study, multiple tests were conducted to obtained the shale properties alteration induced by ScCO2-water exposure, including the mineral compositions measured by XRD, XRF and ICP-OES, the mechanical properties measured by uniaxial compression test, the pore structure and permeability of shale measured using nuclear magnetic resonance (NMR) at different confining stresses over a range of injection pressures. After ScCO2-water exposure, the contents of carbonate and clay minerals decreased, while the contents of quartz and feldspar increased. The geochemical reaction altered the pore structure and mechanical properties of shale, resulting in the enlargement of pore, the decrease in uniaxial compressive strength and elastic modulus of shale, which in turn impact the porosity and permeability evolution in shale. At the unstressed state, the pore in shale was enlarged by the pure chemical reaction, leading to the increase in porosity and the initial permeability of shale. At the stressed condition, the porosity and permeability of shale is controlled by the chemical-mechanical coupling effects, the permeability of CO2-water treated shale sample is lower than that of the untreated shale sample, which can be explained by the increase in stress sensitivity of shale permeability induced by the mechanical weakening, as the compressibility Cf and permeability change rate Dkc were increased after ScCO2-water exposure. In addition, the stress sensitivity of permeability in shale is stress dependent, for both untreated and ScCO2-water treated shale samples, the C-f and delta k(c) of shale shown a negative relation with effective stress. At a higher effective stress condition, the change in the permeability of ScCO2-water treated shale is more significantly enhanced. The results demonstrated that the ScCO2-water-shale interaction induced chemical-mechanical effect may decrease the permeability of shale at in-situ stress condition, and hence adversely affecting the efficiency of gas recovery and CO2 sequestration in shale formation. (C)& nbsp;2022 Published by Elsevier Ltd.

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