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Microstructural characteristics and CO2 uptake of calcium sulfoaluminate cement by carbonation curing at different water-to-cement ratios

The present study investigates the effect of carbonation curing and the water-cement ratio on the microstructural characteristics and CO2 uptake of calcium sulfoaluminate (CSA) cement. Low-pH carbonic acid promoted ettringite participation in CaCO3 formation. Different CaCO3 polymorphs, Al(OH)3, and...

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Published in:	Cement and concrete research 2023-01, Vol.163, p.107012, Article 107012
Main Authors:	Sharma, Raju, Kim, Hyeju, Lee, Nam Kon, Park, Jung-Jun, Jang, Jeong Gook
Format:	Article
Language:	English
Subjects:	Calcium sulfoaluminate cement Carbonation curing CO2 uptake Compressive strength Physicochemical property
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creator	Sharma, Raju Kim, Hyeju Lee, Nam Kon Park, Jung-Jun Jang, Jeong Gook
description	The present study investigates the effect of carbonation curing and the water-cement ratio on the microstructural characteristics and CO2 uptake of calcium sulfoaluminate (CSA) cement. Low-pH carbonic acid promoted ettringite participation in CaCO3 formation. Different CaCO3 polymorphs, Al(OH)3, and unreacted ye'elimite occupied the higher proportion of the phase assemblage of carbonation-cured sample. Ettringite and strätlingite were the major phases of the water-cured sample. A maximum fourfold increase in the CO2 uptake capacity per gram of the carbonation-cured paste at the highest water-cement ratio was observed. 27Al NMR demonstrates the strätlingite formation after 1 day of water curing, while unreacted ye'elimite was observed in the carbonation-cured sample. The dissolution of hydrated phases leading to the formation of CaCO3, moderately affects the strength. The maximum proportion of weight was reached within 1 day of water curing due to the reaction of ye'elimite and belite to the formation of ettringite and strätlingite, respectively.
doi_str_mv	10.1016/j.cemconres.2022.107012
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Low-pH carbonic acid promoted ettringite participation in CaCO3 formation. Different CaCO3 polymorphs, Al(OH)3, and unreacted ye'elimite occupied the higher proportion of the phase assemblage of carbonation-cured sample. Ettringite and strätlingite were the major phases of the water-cured sample. A maximum fourfold increase in the CO2 uptake capacity per gram of the carbonation-cured paste at the highest water-cement ratio was observed. 27Al NMR demonstrates the strätlingite formation after 1 day of water curing, while unreacted ye'elimite was observed in the carbonation-cured sample. The dissolution of hydrated phases leading to the formation of CaCO3, moderately affects the strength. 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subjects	Calcium sulfoaluminate cement Carbonation curing CO2 uptake Compressive strength Physicochemical property
title	Microstructural characteristics and CO2 uptake of calcium sulfoaluminate cement by carbonation curing at different water-to-cement ratios
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