Environmentally sustainable technology for the treatment of electrolytic manganese residue: Enabling harmless disposal and utilization in building materials

IF 5.8 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Sustainable Chemistry and Pharmacy Pub Date : 2025-10-10 DOI:10.1016/j.scp.2025.102224

Yu Xue , Xiaoming Liu , Zengqi Zhang , Yinming Sun , Huasheng Liao

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引用次数: 0

Abstract

Electrolytic manganese residue (EMR) is an industrial solid waste discharged by the electrolytic manganese metal (EMM) industry with a growing stockpile that currently exceeds 160 million tons in China. EMR contains impurities and harmful ions such as Mn²⁺ and NH₄⁺ that cause severe environmental pollution. Fortunately, EMR also contains a high concentration of CaSO₄, similar to industrial gypsum, which makes EMR an alternative to gypsum in building materials. In addition, the harmful elements are stabilized and essentially eliminated when EMR is used as a building material. To facilitate future research with EMR, this paper provides a comprehensive review on the harmless treatment of EMR and its use as a building material. The harmless treatment methods for EMR include leaching (e.g., chemical, biological, electrochemical), solidification/stabilization (e.g., via chemical reagents or other industrial wastes) and roasting. The use cases of EMR as a building material include cement, concrete, bricks, road base materials, backfill materials, geopolymers, ceramic and ceramsite. After reviewing each of the aforementioned processes separately, their challenges and prospects are discussed together. Finally, several ways are proposed to better streamline current EMR research toward more efficient large scale industrial applications.

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环境可持续的电解锰渣处理技术：在建筑材料中实现无害化处理和利用

电解锰渣（EMR）是电解金属锰（EMM）行业排放的一种工业固体废物，目前中国电解金属锰的储存量已超过1.6亿吨。EMR中含有杂质和有害离子，如Mn2+、NH4+等，对环境造成严重污染。幸运的是，EMR还含有高浓度的CaSO4，类似于工业石膏，这使得EMR成为建筑材料中石膏的替代品。此外，当EMR用作建筑材料时，有害元素被稳定并基本消除。为了促进EMR的进一步研究，本文对EMR的无害化处理及其作为建筑材料的应用进行了全面的综述。EMR的无害化处理方法包括浸出（如化学、生物、电化学）、固化/稳定（如通过化学试剂或其他工业废物）和焙烧。EMR作为建筑材料的用例包括水泥、混凝土、砖、道路基础材料、回填材料、地聚合物、陶瓷和陶粒。在分别回顾了上述每个过程之后，我们将一起讨论它们的挑战和前景。最后，提出了几种方法，以更好地简化当前EMR研究，使其更有效地大规模工业应用。

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

Sustainable Chemistry and Pharmacy Environmental Science-Pollution

CiteScore

8.20

自引率

6.70%

发文量

274

审稿时长

37 days

期刊介绍： Sustainable Chemistry and Pharmacy publishes research that is related to chemistry, pharmacy and sustainability science in a forward oriented manner. It provides a unique forum for the publication of innovative research on the intersection and overlap of chemistry and pharmacy on the one hand and sustainability on the other hand. This includes contributions related to increasing sustainability of chemistry and pharmaceutical science and industries itself as well as their products in relation to the contribution of these to sustainability itself. As an interdisciplinary and transdisciplinary journal it addresses all sustainability related issues along the life cycle of chemical and pharmaceutical products form resource related topics until the end of life of products. This includes not only natural science based approaches and issues but also from humanities, social science and economics as far as they are dealing with sustainability related to chemistry and pharmacy. Sustainable Chemistry and Pharmacy aims at bridging between disciplines as well as developing and developed countries.