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Time-evolution of ScCO2-weakened coal integrity: Chemo-hydromechanical coupling and geological sequestration implications

Peng Liu, Jingtao Yang, Baisheng Nie, Ang Liu, Wei Zhao, Hao Xu, Hengyi He

2025International Journal of Mining Science and Technology7 citationsDOIOpen Access PDF

Abstract

Geological sequestration of CO 2 is critical for deep decarbonization, but the geomechanical stability of coal reservoirs remains a major challenge. This study integrates nanoindentation, XRD/SEM-EDS chemo physical characterization and 4D CT visualization to investigate the time-evolving mechanical degradation of bituminous coals with ScCO 2 injection. The main results show that 4 d of ScCO 2 treatment caused 50.47%–80.99% increase in load–displacement deformation and 26.92%–76.17% increase in creep depth at peak load, accompanied by 55.01%–63.38% loss in elastic modulus and 52.83%–74.81% reduction in hardness. The degradation exhibited biphasic kinetics, characterized by rapid surface-driven weakening (0–2 d), followed by stabilized matrix-scale pore homogenization (2–4 d). ScCO 2 preferentially dissolved carbonate minerals (dolomite), driving pore network expansion and interfacial debonding, while silicate minerals resisted dissolution but promoted structural homogenization. These coupled geochemical-mechanical processes reduced the mechanical heterogeneity of the coal and altered its failure modes. The results establish a predictive framework for reservoir stability assessment and provide actionable insights for optimizing CO 2 enhanced coalbed methane recovery.

Topics & Concepts

CoalMining engineeringCoal miningCoupling (piping)GeologyCarbon sequestrationPetroleum engineeringEnvironmental scienceWaste managementEngineeringChemistryMechanical engineeringCarbon dioxideOrganic chemistryCoal Properties and UtilizationRock Mechanics and ModelingMineral Processing and Grinding
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