Influence of CO2 Curing and Autoclaved Aerated Concrete Powder on Sulfate Attack of Cement Paste at Low Temperature: Fid-Bau Portal

Influence of CO2 Curing and Autoclaved Aerated Concrete Powder on Sulfate Attack of Cement Paste at Low Temperature

Qin, Ling / Mao, Xingtai / Gao, Xiaojian / Zhang, Peng / Li, Qiyan / Chen, Tiefeng / Cui, Yifei

This paper studied the influence of CO2 curing and autoclaved aerated concrete powder on the sulfate attack of a cement sample at low temperature. The basic performance including compressive strength, mass and volume changes, and microstructure tests were analyzed by X-ray diffraction (QXRD/Rietveld), mercury intrusion porosimeter (MIP) and scanning electron microscope-energy dispersive spectrometer (SEM-EDS) analysis. Results proved that the strength of PC (Portland cement)-WAAC (waste autoclaved aerated concrete) pastes decreased after low-temperature sulfate attack; however, carbonation curing could mitigate the decrease. Compared with the strength of the uncarbonated specimens without sulfate immersion, the strengths of the CO2-cured specimens added with 0%, 10%, and 20% of WAAC after 6 months of sulfate immersion were still 3.93%, 11.90%, and 18.31% higher. The compressive strength reduction of the carbonated samples after 6 months of low-temperature sulfate immersion (9.31%–46.15%) was much lower than that of the uncarbonated specimens (15.55%–61.97%). In addition, CO2 curing decreased the porosity and improved the pore structure of the samples, thereby inhibiting sample volume expansion resulting from sulfate immersion. Carbonation curing improved the resistance of PC-WAAC specimens to low-temperature sulfate attack. After low-temperature sulfate immersion, thaumasite did not form in the carbonation curing samples. Therefore, WAAC recycling combined with carbonation curing can produce cementitious materials with good environmental sustainability and better long-term durability in sulfate erosion areas.