Durability of slag-based alkali-activated materials: A critical review

IF 1.8 4区 材料科学 Q2 MATERIALS SCIENCE, CERAMICS
H. S. Gökçe
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引用次数: 0

Abstract

As the world becomes increasingly aware of the devastating effects of climate change, the need for sustainable building materials that are both durable and environmentally friendly increases. Geopolymer and alkali-activated materials formed by a chemical reaction between an alkaline activator solution and an aluminosilicate source have gained popularity in recent years. The alkaline activator solution dissolves the aluminosilicate source, which then undergoes a polycondensation reaction to form a three-dimensional geopolymeric gel network. The development of this network ensures the strength and durability of the material. Today, this phenomenon of durability has been studied in detail to enable the development of superior construction materials, taking into account degradation mechanisms such as carbonation, leaching, shrinkage, fire, freezing and thawing, and exposure to aggressive environments (chlorides, acids, and sulphates). Although there are many unsolved problems in their engineering applications, slag-based alkali-activated materials appear to be more advantageous and are promising as alternative materials to ordinary Portland cement. First of all, it should not be ignored that the cure sensitivity is high in these systems due to compressive strength losses of up to 69%. Loss of strength of alkali-activated materials is considered an important indicator of degradation. In binary precursors, the presence of fly ash in slag can result in an improvement of over 10% in compressive strength of the binary-based alkali-activated materials after undergoing carbonation. The binary systems can provide superior resistance to many degradation mechanisms, especially exposure to high-temperature. The partial presence of class F fly ash in the slag-based precursor can overcome the poor ability of alkali-activated materials to withstand high temperatures. Due to the desired pore structure, alkali-activated materials may not be damaged even after 300 freeze–thaw cycles. Their superior permeability compared to cementitious counterparts can extend service life against chloride corrosion by more than 20 times. While traditional (ordinary Portland cement-based) concrete remains the most widely used material in construction, geopolymer concrete’s superior performance makes it an increasingly emerging option for sustainable and long-lasting infrastructure.

矿渣碱活性材料的耐久性:严格审查
随着全球日益意识到气候变化的破坏性影响,人们对既耐用又环保的可持续建筑材料的需求与日俱增。近年来,由碱性活化剂溶液和硅酸铝源发生化学反应而形成的土工聚合物和碱活化材料越来越受欢迎。碱性活化剂溶液溶解硅酸铝源,然后硅酸铝源发生缩聚反应,形成三维土工聚合物凝胶网络。这种网络的形成确保了材料的强度和耐久性。如今,人们已经对这种耐久性现象进行了详细研究,以便开发出性能更优越的建筑材料,同时考虑到碳化、浸出、收缩、火灾、冻融和暴露于侵蚀性环境(氯化物、酸和硫酸盐)等降解机制。尽管矿渣碱活性材料在工程应用中还存在许多尚未解决的问题,但作为普通硅酸盐水泥的替代材料,矿渣碱活性材料似乎更具优势,前景广阔。首先,不容忽视的是,这些体系的固化敏感性很高,抗压强度损失高达 69%。碱激活材料的强度损失被认为是降解的一个重要指标。在二元前驱体中,炉渣中粉煤灰的存在可使二元碱活性材料在经历碳化后的抗压强度提高 10%以上。二元系统对许多降解机制,尤其是暴露于高温下的降解机制具有卓越的抵抗能力。炉渣基前驱体中含有部分 F 级粉煤灰,可以克服碱活性材料耐高温能力差的问题。由于具有理想的孔隙结构,碱活性材料即使经过 300 次冻融循环也不会损坏。与水泥基材料相比,碱活性材料的渗透性更强,可将抗氯化物腐蚀的使用寿命延长 20 倍以上。尽管传统(普通波特兰水泥基)混凝土仍是建筑中使用最广泛的材料,但土工聚合物混凝土的优越性能使其日益成为可持续和长寿命基础设施的新兴选择。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of the Australian Ceramic Society
Journal of the Australian Ceramic Society Materials Science-Materials Chemistry
CiteScore
3.70
自引率
5.30%
发文量
123
期刊介绍: Publishes high quality research and technical papers in all areas of ceramic and related materials Spans the broad and growing fields of ceramic technology, material science and bioceramics Chronicles new advances in ceramic materials, manufacturing processes and applications Journal of the Australian Ceramic Society since 1965 Professional language editing service is available through our affiliates Nature Research Editing Service and American Journal Experts at the author''s cost and does not guarantee that the manuscript will be reviewed or accepted
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