Investigation of supercritical CO2 mass transfer in porous media using X-ray micro-computed tomography

Understanding the mass transfer of CO2 into formation brine both qualitatively and quantitatively is important for improving the security of geologic carbon sequestration. In this study, quasi-dynamic X-ray micro-computed tomographic (MCT) imaging was used to track the time-evolution of supercritical CO2 (scCO2) clusters in a sandstone throughout brine injection. A cluster-matching workflow enabled the identification of depletion, merging, and snap-off of the scCO2 clusters, and subsequently the mass transfer coefficient of individual scCO2 clusters was found to range between 3.0x10-5 and 3.5x10-4 mm/s. The macroscopic average mass transfer coefficient was estimated as 1.4x10-4 mm/s. For application to geologic carbon sequestration, these values give an indication of the range of mass transfer coefficients that may be expected for similar state and flow conditions. With the macroscopic average mass transfer coefficient evaluated, we back-calculated the in-situ CO2 concentration field for brine, which provides quantitative insight of the distribution of dissolved CO2 in the sample. Despite slow injection rate (Ca = 10-7), mobilization of small scCO2 clusters was also observed, and was attributed to the combined effect of incomplete dissolution of snapped-off clusters and the reduction in the fluid-fluid interfacial tension (IFT) due to the high local CO2 concentration in brine accompanying scCO2 dissolution. This highlights the coupling of dissolution and mobilization processes and demonstrates the need to understand these interlinked dynamics to improve CO2 storage in geological formations.

Automated summary

Understanding the mass transfer of CO2 into formation brine is crucial for the safety of geologic carbon sequestration. This study used quasi-dynamic X-ray micro-computed tomographic imaging to track the evolution of scCO2 clusters in sandstone during brine injection. The mass transfer coefficient of individual scCO2 clusters was found to range between 3.0x10-5 and 3.5x10-4 mm/s, with a macroscopic average of 1.4x10-4 mm/s. These values provide insight into the range of mass transfer coefficients expected for similar conditions. The study also highlighted the coupling of dissolution and mobilization processes, emphasizing the need to understand these dynamics for effective CO2 storage.