Research Progress in the Detoxification and Resource Utilization of Chromium Slag: Recovery Technologies, Large-Scale Utilization, and Emerging Challenges-A Review.
- 2026-05-14
- Materials (Basel, Switzerland) 19(10)
- Bin Wang
- Jianjun Gao
- Feng Wang
- Yue Yu
- Yuanhong Qi
- PubMed: 42195693
- DOI: 10.3390/ma19102054
Study Design
- Type
- Review
- Methods
- Systematic review of recovery technologies, industrial-scale utilization pathways, and key challenges
Chromium slag, a chromium-bearing solid waste characterized by substantial environmental hazards yet with appreciable resource potential, has become a focal topic in solid-waste pollution control and the circular economy. Centered on the overarching logic of "evidence chain-system boundary-scalable and verifiable acceptance," this review systematically synthesizes recovery technologies, industrial-scale utilization pathways, and the key challenges associated with the detoxification and resource utilization of chromium slag. From the perspective of recovery technologies, we examine pyrometallurgical and hydrometallurgical routes, solidification/stabilization (S/S), and bioelectrochemical coupling approaches, elucidating their fundamental principles, applicability boundaries, and critical nodes where environmental burdens may be transferred across media. We emphasize that process design should concurrently consider detoxification efficiency, resource recovery performance, and whole-process pollution control. Regarding utilization pathways, this review highlights three major routes with strong scale-up relevance-metallurgical process co-treatment (CAP-sintering-blast furnace), bulk utilization in construction materials, and high-value utilization-and analyzes their industrial potential and engineering constraints. Particular attention is given to the lack of long-term leaching and durability evidence, which represents a central bottleneck limiting product-side credibility. Furthermore, we discuss cross-cutting challenges including the long-term stabilization of Cr(VI), the verifiability of "green utilization" concepts, cost and economic feasibility, and standardized acceptance criteria. We propose that future research should shift from single-process optimization toward multi-objective, system-level evaluation, and establish a full-chain evidence system covering "speciation/mineral phases-process mechanisms-environmental behavior-risk assessment-engineering scale-up-standardized acceptance." This review aims to provide a systematic analytical framework and practical reference for improving comparability across resource-utilization technologies and supporting engineering decision-making for chromium slag management.