Effect of CO2-H2O-Smectite Interactions on Permeability of Clay-Rich Rocks Under CO2 Storage Conditions

CO2 uptake by smectites can cause swelling and self-stressing in shallow clay-rich caprocks under CO2 storage P-T and constrained conditions. However, little data exist to constrain the magnitude of the effects of CO2-H2O-smectite interactions on the sealing properties of clay-rich caprocks and faults. We performed permeability experiments on intact and fractured Opalinus Claystone (OPA) cores (similar to 5% smectite), as well as on a simulated gouge-filled faults consisting of Na-SWy-1 montmorillonite, under radially constrained conditions simulating open transport pathways (dry and variably wet He or CO2; 10 MPa fluid pressure; 40 degrees C). Overall, the flow of dry CO2 through intact OPA samples and simulated smectite fault gouge caused a decrease in permeability by a factor of 4-9 or even by > 1 order, compared to dry He permeability. Subsequent to flow of dry and partially wet fluid, both fractured OPA and simulated gouge showed a permeability reduction of up to 3 orders of magnitude once flow-through with wet CO2 was performed. This permeability change appeared reversible upon re-establishing dry CO2 flow, suggesting fracture permeability was dominated by water uptake or loss from the smectite clay, with CO2-water-smectite interactions play a minor effect. Our results show that whether an increases or decreases in permeability of clayey caprock is expected with continuous flow of CO2-rich fluid depends on the initial water activity in the clay material versus the water activity in the CO2 bearing fluid. This has important implications for assessing the self-sealing potential of fractured and faulted clay-rich caprocks.

Automated summary

CO2 uptake by smectites can cause swelling and self-stressing in shallow clay-rich caprocks under CO2 storage P-T and constrained conditions. However, little data exist to constrain the magnitude of the effects of CO2-H2O-smectite interactions on the sealing properties of clay-rich caprocks and faults. Our experiments on Opalinus Claystone (OPA) cores and simulated fault gouge showed that the permeability of clayey caprock can decrease significantly when exposed to CO2-rich fluid, depending on the initial water activity in the clay material. These findings have important implications for assessing the self-sealing potential of fractured and faulted clay-rich caprocks.