4.7 Article

Simultaneous immobilization of multiple heavy metals in polluted soils amended with mechanical activation waste slag

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SCIENCE OF THE TOTAL ENVIRONMENT
卷 894, 期 -, 页码 -

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ELSEVIER
DOI: 10.1016/j.scitotenv.2023.164730

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Electrolytic manganese slags; Heavy metals; Adsorption; Soil remediation

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This study investigates the adsorption performance of mechanically activated and modified electrolytic manganese slags (M-EMS) for heavy metals, as well as its passivation ability, impact on dissolved organic matter (DOM), and microbial community structure in soil. The results demonstrate that M-EMS shows remarkable removal performance for different heavy metals and can stabilize them in contaminated soils through ion exchange, electrostatic adsorption, complex precipitation, and microbial-induced mechanisms. These findings provide new insights into the ecological remediation of heavy-metal-contaminated soils and water bodies.
Heavy metal soil contamination has become an increasingly serious problem in industrial development. However, industrial byproducts used for remediation are one aspect of green remediation that can contribute to sustainable practices in waste recycling. In this study, electrolytic manganese slags (EMS) were mechanically activated and modified into a passivator (M-EMS), and the heavy metal adsorption performance of M-EMS, heavy metal passivation ability in soil, dissolved organic matter (DOM) change and its effect on the microbial community structure of soil were investigated. The findings revealed that the maximum adsorption capacities of As(V), Cd2+, Cu2+ and Pb2+ were 76.32 mg/g, 301.41 mg/g, 306.83 mg/g and 826.81 mg/g, respectively, indicating that M-EMS demonstrated remarkable removal performance for different heavy metals. The Langmuir model fits Cd2+, Cu2+ and Pb2+ better than the Freundlich model, and monolayer adsorption is the main process. Surface complexation played a major role in the As (V) adsorption's on the surface of metal oxides in M-EMS. The passivation effect was ranked as Pb > Cr > As>Ni > Cd > Cu, with the highest passivation rate of 97.59 % for Pb, followed by Cr (94.76 %), then As (71.99 %), Ni (65.17 %), Cd (61.44 %), and the worst one was Cu (25.17 %). In conclusion, the passivator has the effect of passivation for each heavy metal. The addition of passivating agent can enhance the diversity of microorganisms. Then it can change the dominant flora and induce the passivation of heavy metals through microorganisms. XRD, FTIR, XPS and the microbial community structure of soil indicated that M-EMS can stabilize heavy metals in contaminated soils through four main mechanisms: ion exchange, electrostatic adsorption, complex precipitation and the microbially induced stabilization. The results of this study may provide new insights into the ecological remediation of multiple heavy-metal-contaminated soils and water bodies and research on the strategy of waste reduction and harmlessness by using EMS-based composites in combination with heavy metals in soil.

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