Sealing Porous Media through Calcium Silicate Reactions with CO <sub>2</sub> to Enhance the Security of Geologic Carbon Sequestration
Florence T. Ling, Dan A. Plattenberger, Catherine A. Peters, Andrés F. Clarens
Abstract
The injection of CO 2 deep underground, i.e., geologic carbon sequestration, has attracted considerable attention for climate change mitigation. A reliable caprock for secure containment is essential, alongside strategies for sealing flow paths to prevent leaks. In this study, we explore ways in which reactions of CO 2 with CaSiO 3 can be used for targeted mineral precipitation and permeability control in situ . Previous work has suggested that certain CaSiO 3 polymorphs can produce pore-filling precipitates that successfully inhibit flow, whereas others produce precipitates with little impact. In this work, a one-dimensional reactive transport model was developed for a centimeter-scale system to explore connections between the pore and continuum scale. The model considers four reactions involving CaSiO 3 , CaCO 3 , SiO 2(am) , and the crystalline calcium silicate hydrate (CCSH) tobermorite. A key feature is incorporation of microporosity, with an attempt to represent favorable volume expanding changes from CCSH precipitation in porous media. At 150°C and 1.1 MPa CO 2 , representing typical laboratory conditions, the model predicts significant permeability drop when reacting the pseudowollastonite CaSiO 3 polymorph at elevated pH to produce CaCO 3 , SiO 2(am) , and tobermorite. The effect of increasing pH via by NaOH addition, which increases CO 2 solubility, increases CaSiO 3 dissolution, and supports tobermorite supersaturation. In contrast, reaction of the wollastonite polymorph results in CaCO 3 and SiO 2(am) formation, with limited permeability impact. Wollastonite's lower solubility and slower dissolution rate inhibits tobermorite formation. Simulation at the high pressures representative of deep subsurface field conditions (40°C and 7.5 MPa CO 2 ) suggests that reaction of CaSiO 3 with CO 2 could reduce permeability and seal unwanted leakage pathways.