30 / 2025-11-19 00:14:56
Hydrogen Adsorption-induced strain in shale: Implications for Underground Hydrogen Storage
Key words: underground hydrogen storage, adsorption, hydrogen, shale, strain
Abstract Pending
彭毅凡 / 重庆大学
周军平 / 重庆大学
徐程浩 / 重庆大学
旷年杰 / 重庆大学
Underground hydrogen storage (UHS) has been proposed as a promising option for large-scale hydrogen storage, and depleted shale gas reservoirs are considered as candidate sites because of their wide distribution, large capacity, and sealing integrity. Although recent research has reported hydrogen adsorption capacities in shale, systematic experimental data on adsorption-induced strain remains lacking. In this study, hydrogen adsorption and adsorption-induced strain in shale were systematically investigated under high-pressure conditions at 313.15, 333.15, and 353.15 K. Results show that hydrogen adsorption capacity increases with pressure but decreases with temperature, reaching 0.156 mmol g⁻¹ at 313.15 K and 16 MPa. The corresponding volumetric strain exhibits three stages with pressure—rapid increase, gradual growth, and final stabilization—with a maximum magnitude of 0.21‰, confirming that adsorption-induced deformation is extremely limited. Strain shows a stronger correlation with the adsorbed amount than with external pressure , and the relationship is well described by a Freundlich-type strain–adsorption model (R²= 0.978–0.989). Directional differences between axial and radial strains are small (R≈0.9–1.0 at 313.15 K), indicating that hydrogen adsorption causes only weakly anisotropic and nearly reversible deformation . In comparison, CH₄ and CO₂ adsorption in shale generally induces much larger swelling and permeability reduction, whereas hydrogen produces deformation one to two orders of magnitude smaller. It can therefore be inferred that hydrogen adsorption is unlikely to affect the injectivity or withdrawal capacity of shale reservoirs. These findings demonstrate that hydrogen adsorption in shale provides substantial storage potential without compromising reservoir efficiency, offering a scientific basis for evaluating the feasibility of depleted shale gas reservoirs for underground hydrogen storage.
 

 


Important Date
  • Conference Date

    Nov 27

    2025

    to

    Nov 29

    2025

  • Nov 29 2025

    Draft paper submission deadline

  • Nov 29 2025

    Registration deadline

Sponsored By
重庆大学
Organized By
煤矿灾害动力学与控制全国重点实验室
重庆大学资源与安全学院
《Earth Energy Science》/地球能源科学(英文)
中煤科工集团重庆研究院有限公司
Supported By
自然资源部复杂构造区非常规天然气评价与开发重点实验室
重庆市地质矿产勘查开发集团有限公司
InterPore China (国际多孔介质学会中国分会)
贵州大学
西南石油大学