Study on Carbon Fixation Ratio and Properties of Foamed Concrete

Wei, Yuansheng; Cao, Xiaoqiang; Wang, Gang; Zhang, Mingguang; Lv, Zhiwen

doi:10.3390/ma16093441

Materials

2023

DOI: 10.3390/ma16093441

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Study on Carbon Fixation Ratio and Properties of Foamed Concrete

Yuansheng Wei

Xiaoqiang Cao

Gang Wang

et al.

Abstract: Using solid waste to sequester carbon dioxide not only reduces the greenhouse effect but also reuses resources. However, the existing solidified carbon dioxide storage materials are expensive and have poor storage effect. Therefore, in this study, cement, solid waste base material, and 30% hydrogen peroxide were used to make foamed concrete materials through chemical foaming, and XRD, BET, SEM, and thermogravimetric techniques were used to explore the amount of carbon dioxide adsorbed by foamed concrete materi… Show more

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Development of Foam Concrete toward High Strength and CO₂ Sequestration

Fan,

Zhang,

et al. 2024

ACS Sustainable Chem. Eng.

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Excessive CO 2 emissions present major environmental challenges. This study developed carbonation-enhanced high-strength foam concrete (HSFC) to maximize the CO 2 sequestration and utilization. HSFC was produced by incorporating a fine and stable foam into a designed dense paste matrix, followed by carbonation enhancement. Micro and macro tests revealed that HSFC achieved a notable CO 2 uptake capacity of up to 12.6 wt % (∼90 kg of CO 2 per m 3 of concrete). In the low water-to-binder (W/B) ratio system, carbonation curing consumed calcium hydroxide, calcium silicate hydrate (CSH) gel, and unhydrated cement, producing substantial amounts of calcium carbonates (CCs) in three forms: amorphous, calcite (predominant), and aragonite (at higher carbonation levels). Notably, the carbonation process slightly increased the matrix microhardness by filling micropores and reducing porosity by 19.8%. The generation of CCs on foam pore walls refined the pore size, further enhancing HSFC compressive strength to nearly double that of conventional foam concrete at a similar density. Carbonation curing also improved durability, reducing water absorption and increasing electrical resistance. Finally, strategies for fabricating high-performance HSFC with significant environmental benefits were proposed, contributing to sustainable construction practices.

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Development of Foam Concrete toward High Strength and CO₂ Sequestration

Fan,

Zhang,

et al. 2024

ACS Sustainable Chem. Eng.

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Study on Carbon Fixation Ratio and Properties of Foamed Concrete

Cited by 1 publication

References 23 publications

Development of Foam Concrete toward High Strength and CO₂ Sequestration

Development of Foam Concrete toward High Strength and CO₂ Sequestration

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Study on Carbon Fixation Ratio and Properties of Foamed Concrete

Cited by 1 publication

References 23 publications

Development of Foam Concrete toward High Strength and CO2 Sequestration

Development of Foam Concrete toward High Strength and CO2 Sequestration

Contact Info

Product

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Development of Foam Concrete toward High Strength and CO₂ Sequestration

Development of Foam Concrete toward High Strength and CO₂ Sequestration