Integrated CO2 capture and mineralization approach based on KOH and cement-based wastes

Abstract

To extend current Carbon Capture, Utilization, and Storage (CCUS) strategies and explore a circular carbon economy, an integrated CO2 capture and mineralization approach was developed in this work. KOH was used as CO2 absorption agent to simulate post-combustion carbon capture from flue gas, and then cement-based wastes were used as CO2 mineralization feedstock to convert the sequestered carbonate/bicarbonate ions in the solvent to carbonate minerals and thereby recover and regenerate KOH. The features of the integrated CO2 capture and mineralization process were characterized through ICP-OES analysis, TGA, SEM, quantitative XRD analysis, and particle size analysis. In this study, the carbon capture from the simulated flue gas with CO2 concentration of 10 % using 2.0 M KOH was examined, and the real CO2 capture capacity of 2.0 M KOH was determined at around 1.5 M. After CO2 capture, ground mortar wastes were added into the CO2-loaded KOH solvent, which enables CO2 mineralization and thereby decarbonizes the CO2 liquid absorbent. In CO2 mineralization process, the carbonation characteristics of mortar waste at different pH levels were analysed in-depth. The optimum pH interval for the CO2 mineralization of mortar waste was between 10 and 11, and correspondingly, the highest CO2 sequestration capacity was measured at around 164 g CO2/kg. Apart from CO2 capture and mineral sequestration, another two valuable by-products – silica gels and carbonated mortar waste were also collected and analysed. To increase the applicability of the integrated CO2 capture and mineralization process on a commercial scale, future research was also identified and discussed.