Litcius/Paper detail

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

2021Environmental Engineering Science16 citationsDOI

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.

Topics & Concepts

TobermoriteWollastoniteDissolutionCalcium silicateSolubilityChemical engineeringSupersaturationCalcium silicate hydratePermeability (electromagnetism)PorosityCarbon sequestrationMineralogyMaterials scienceCaprockPorous mediumChemistryGeologyCarbon dioxideMetallurgyPetroleum engineeringMembraneComposite materialOrganic chemistryRaw materialCementBiochemistryEngineeringCO2 Sequestration and Geologic InteractionsRock Mechanics and ModelingConcrete and Cement Materials Research
Sealing Porous Media through Calcium Silicate Reactions with CO <sub>2</sub> to Enhance the Security of Geologic Carbon Sequestration | Litcius