Preparation of glass–ceramics from blast furnace slag and its heavy metal curing properties

IF 2.7 4区 环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES Journal of Material Cycles and Waste Management Pub Date : 2023-06-30 DOI:10.1007/s10163-023-01744-2
Yongsheng Du, Yuhang Guo, Guangyu Wang, Hongxia Zhang, Leibo Deng, Hua Chen, Ming Zhao
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引用次数: 1

Abstract

High-performance slag glass–ceramics were prepared by melting method using rare earth-containing blast furnace slag as the main raw material and Fe2O3 and Cr2O3 as composite nucleating agents. The influence of ZnO on the structure and properties of glass–ceramics was studied by changing the addition amount of ZnO. The existence state and solidification mechanism of heavy metals Zn, Mn, Cr and rare earth ions in glass–ceramics were also analyzed simultaneously. The results showed that the high electric field characteristics of Cr ions contributed to the formation of spinel phase, while Zn and Mn ions can enter the spinel crystal by substitution and exist stably. The Zn ions were mainly distributed in the spinel phase and glass phase, and the Zn ions in the glass phase affected the physicochemical properties of glass–ceramics by changing the glass network structure. In addition, the rare earth ions were mainly found in the augite and glass phases. The leaching characteristics of heavy metals in glass–ceramics showed that the leaching concentrations of heavy metals Zn, Mn and Cr ions were much lower than the standard value of hazardous waste leaching toxicity, indicated that glass–ceramics have good curing effects on Zn, Mn and Cr ions.

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高炉矿渣制备微晶玻璃及其重金属固化性能研究
以含稀土高炉渣为主要原料,以Fe2O3和Cr2O3为复合成核剂,采用熔融法制备了高性能矿渣微晶玻璃。通过改变ZnO的加入量,研究了ZnO对微晶玻璃结构和性能的影响。同时分析了重金属Zn、Mn、Cr和稀土离子在微晶玻璃中的存在状态和凝固机理。结果表明,Cr离子的强电场特性有助于尖晶石相的形成,而Zn和Mn离子可以通过取代进入尖晶石晶体并稳定存在。Zn离子主要分布在尖晶石相和玻璃相中,玻璃相中的Zn离子通过改变玻璃网络结构来影响微晶玻璃的理化性能。稀土离子主要存在于奥辉石相和玻璃相中。重金属在微晶玻璃中的浸出特性表明,重金属Zn、Mn和Cr离子的浸出浓度远低于危险废物浸出毒性标准值,表明微晶玻璃对Zn、Mn和Cr离子具有良好的固化效果。
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来源期刊
CiteScore
5.30
自引率
16.10%
发文量
205
审稿时长
4.8 months
期刊介绍: The Journal of Material Cycles and Waste Management has a twofold focus: research in technical, political, and environmental problems of material cycles and waste management; and information that contributes to the development of an interdisciplinary science of material cycles and waste management. Its aim is to develop solutions and prescriptions for material cycles. The journal publishes original articles, reviews, and invited papers from a wide range of disciplines related to material cycles and waste management. The journal is published in cooperation with the Japan Society of Material Cycles and Waste Management (JSMCWM) and the Korea Society of Waste Management (KSWM).
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