Abstract
Geologic carbon storage in deep saline aquifers has emerged as a promising technique to mitigate climate change. CO2 is buoyant at the storage conditions and tends to float over the resident brine jeopardizing long-term containment goals. Therefore, the caprock sealing capacity is of great importance and requires detailed assessment. We perform supercritical CO2 injection experiments on shaly caprock samples (intact caprock and fault zone) under representative subsurface conditions. We numerically simulate the experiments, satisfactorily reproducing the observed evolution trends. Simulation results highlight the dynamics of CO2 flow through the specimens with implications to CO2 leakage risk assessment in field practices. The large injection-induced overpressure drives CO2 in free phase into the caprock specimens. However, the relative permeability increase following the drainage path is insufficient to provoke an effective advancement of the free-phase CO2. As a result, the bulk CO2 front becomes almost immobile. This implies that the caprock sealing capacity is unlikely to be compromised by a rapid capillary breakthrough and the injected CO2 does not penetrate deep into the caprock. In the long term, the intrinsically slow molecular diffusion appears to dominate the migration of CO2 dissolved into brine. Nonetheless, the inherently tortuous nature of shaly caprock further holds back the diffusive flow, favoring safe underground storage of CO2 over geological time scales.
Highlights
The emission of huge amounts of anthropogenic C O2 into the atmosphere has given rise to global warming and subsequently climate change
It is suggested that large-scale carbon capture and storage (CCS) in deep geological media should be part of the solution to diminish C O2 emissions and the associated harmful consequences (IPCC 2005; Iglauer et al 2015; Celia 2017)
The residual pressure testing procedure is utilized in this study, where the subsurface storage conditions are reproduced with supercritical CO2 injection experiments conducted in a high-pressure oedometric cell
Summary
The emission of huge amounts of anthropogenic C O2 into the atmosphere has given rise to global warming and subsequently climate change. It is suggested that large-scale carbon capture and storage (CCS) in deep geological media should be part of the solution to diminish C O2 emissions and the associated harmful consequences (IPCC 2005; Iglauer et al 2015; Celia 2017). Injection into reservoirs deep enough to bring CO2 to high pressure (> 7.38 MPa) and temperature (> 31.04 °C) ensures that CO2 will remain in its supercritical state (Bachu 2003). The advantages of doing that are the high storativity and injectivity owing to the liquid-like density and gas-like viscosity of supercritical CO2. CO2 remains lighter than the reservoir brine and is buoyant, tending to flow upward.
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