Experimental investigation into the self-carbonation mechanism of magnesium oxide carbon sequestration foamed concrete
Xiang Zhang, Songyu Liu, Kai Wu, Zhenyang Yuan
Abstract
A novel technique involves the preparation of foamed concrete utilizing MgO as a substitute for Portland cement (PC) and CO 2 foam in place of air foam. This technique is referred to as “magnesium oxide (MgO) carbon sequestration foamed concrete (MCFC)" that enables self-carbonation of Reactive MgO cement-based concrete under ambient conditions without any accelerated carbonation curing conditions. The developed technology enhances the carbonation efficiency of MgO-based materials by combining a foaming agent with CO 2 curing. The even mixing of CO 2 foam with MgO , referred to the uniform distribution and incorporation of CO 2 throughout the sample, facilitated by the foaming agent, leads to the production of ions within the cement, promoting the carbonation of dissolved Mg 2+ ions and the formation of hydrated magnesium hydroxyl carbonates (HMHCs). Eight sample groups were prepared to explore the potential of MCFC in CO 2 sequestration. XRD , TG-DTA, and SEM techniques were employed to investigate the mineral phase and carbonation products in MCFC. The pore structure , pore-size distribution, and porosity of MCFC under different curing conditions were investigated using X-ray and NMR. The self-carbonation enabled by CO 2 foams improved the microstructure and mechanical performance of MgO-based samples. Notably, the morphology, microstructure, and carbonate content improvements resulted in a significant 100% increase in the 28-day compressive strengths (2 MPa) compared to the control sample cured under ambient conditions.