氧化镁基水泥 - 现状与机遇

Q2 Engineering RILEM Technical Letters Pub Date : 2023-11-16 DOI:10.21809/rilemtechlett.2023.177
E. Bernard, Hoang Nguyen, S. Kawashima, B. Lothenbach, Hegoi Manzano, John Provis, Allan Scott, C. Unluer, F. Winnefeld, P. Kinnunen
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引用次数: 0

摘要

水泥行业是人为二氧化碳排放的主要贡献者,其排放量约占总排放量的 8%。全球水泥和混凝土协会制定了到 2050 年实现二氧化碳净零排放的目标,其中 45% 的减排量来自波特兰水泥的替代品、替代物以及碳捕获和利用/储存(CCU/S)方法。菱镁基水泥因其二氧化碳排放量低至负值(CCU/S)的潜力,同时也是波特兰水泥的替代品,为这一问题提供了一个可行的解决方案。镁的来源可以是硅酸镁或海水淡化盐水,它们不含与原材料相关的碳排放(参见碳化岩)。这为实现低碳排放甚至净负碳排放提供了可能。然而,有关菱镁基水泥的研究仍处于早期阶段。 在本文中,我们总结了目前对不同氧化镁基水泥及其化学成分的理解:氧化镁硫酸盐水泥、氧化镁氯酸盐水泥、碳酸镁水泥和硅酸镁水泥。我们还讨论了氧化镁基水泥和混凝土所需的相关研究,包括与这些水泥的低 pH 值和钢筋的适用性有关的问题。氧化镁基混凝土的进一步发展最需要的是替代钢筋、合适的外加剂和耐久性研究,以实现该行业二氧化碳的彻底减排。此外,还需要进行技术经济和生命周期评估,以评估原材料和生产的粘结剂或混凝土与其他解决方案的竞争情况。总之,氧化镁基水泥是一种前景广阔的新兴技术,需要进一步研究和开发,以实现其在减少建筑业二氧化碳排放方面的潜力。
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MgO-based cements – Current status and opportunities
The cement industry is a major contributor to the anthropogenic CO2 emissions, with about 8% of all emissions coming from this sector. The global cement and concrete association has set a goal to achieve net-zero CO2 concrete by 2050, with 45% of the reduction coming from alternatives to Portland cement, substitution, and carbon capture and utilization/storage (CCU/S) approaches. Magnesia-based cements offer a conceivable solution to this problem due to their potential for low-to-negative CO2 emissions (CCU/S) but also being alternatives to Portland cement. The sources of magnesia can come from magnesium silicates or desalination brines which are carbon free for raw-material-related emissions (cf. carbonated rocks). This opens up possibilities for low or even net-negative carbon emissions. However, research on magnesia-based cements is still in its early stages. In this paper, we summarize the current understanding of different MgO-based cements and their chemistries: magnesia oxysulfate cement, magnesia oxychloride cement, magnesia carbonate cement, and magnesia silicate cement. We also discuss relevant research needed for MgO-based cements and concretes including the issues relating to the low pH of these cements and suitability of steel reinforcement. Alternatives reinforcements, suitable admixtures, and durability studies are the most needed for the further development of MgO-based concretes to achieve a radical CO2 reduction in this industry. Additionally, techno-economic and life cycle assessments are also needed to assess the competition of raw materials and the produced binder or concrete with other solutions. Overall, magnesia-based cements are a promising emerging technology that requires further research and development to realize their potential in reducing CO2 emissions in the construction industry.
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来源期刊
RILEM Technical Letters
RILEM Technical Letters Materials Science-Materials Science (all)
CiteScore
5.00
自引率
0.00%
发文量
13
审稿时长
10 weeks
期刊最新文献
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