Assessing Subsurface Gas Storage Security for Climate Change Mitigation and Energy Transition

Abstract Subsurface gas storage is crucial for achieving a sustainable energy future, as it helps to reduce CO 2 emissions and facilitates the provision of renewable energy sources. The confinement effect of the nanopores in caprock induces distinctive thermophysical properties and fluid dynamics. In this paper, we present a multi‐scale study to characterize the subsurface transport of CO 2 , CH 4 , and H 2 . A nanoscale‐extended volume‐translated Cubic‐Plus‐Association equation of state was developed and incorporated in a field‐scale numerical simulation, based on a full reservoir‐caprock suite model. Results suggest that in the transition from nanoscale to bulk‐scale, gas solubility in water decreases while phase density and interfacial tension increase. For the first time, a power law relationship was identified between the capillary pressure within nanopores and the pore size. Controlled by buoyancy, viscous force and capillary pressure, gases transport vertically and horizontally in reservoir and caprock. H 2 has the maximum potential to move upward and the lowest areal sweep efficiency; in short term, CH 4 is more prone to upward migration compared to CO 2 , while in long term, CH 4 and CO 2 perform comparably. Thicker caprock and larger caprock pore size generally bring greater upward inclination. Gases penetrate the caprock when CH 4 is stored with a caprock thickness smaller than 28 m or H 2 is stored with a caprock pore size of 2–10 nm or larger than 100 nm. This study sheds light on the fluid properties and dynamics in nanoconfined environment and is expected to contribute to the safe implementation of gigatonne scale subsurface gas storage.