纳米级零价铁(nZVI)在地下水过度开采区重金属污染修复中的作用

IF 0.7 4区 材料科学 Q3 Materials Science Materials Express Pub Date : 2023-12-01 DOI:10.1166/mex.2023.2555
Yuan Fang, Shichang Gao, Lei Wu, Jing Wang, Chao Yang, Lijun Tang, Pengwei Su, Qi Li
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引用次数: 0

摘要

本研究探讨了利用玉米植物部分生产生物炭的改良方法对过度开发地区重金属污染地下水的修复。采用水热法对生物炭进行改性,采用纳米级零价铁(nZVI)材料制备吸附水体重金属的复合材料。对水中存在的Cr、Cu、Zn离子进行了吸附实验。通过对吸附材料用量、溶液pH、吸附材料稳定性等方面的研究,验证了纳米级零价铁修饰生物炭复合材料(Fe-CBC-MO)对水中重金属离子(Cu、Cr、Zn)的去除和吸附能力。结果表明,吸附量的大小顺序为Cr > Zn > Cu。增加吸附剂用量可提供更多的吸附位点,从而提高水体中重金属的去除效率。考虑成本-效果,最佳投加量为0.15 g。在碱性条件下,Cu和Zn离子沉淀显著,重金属去除率持续较高。相应的,反应速率常数也较高。在酸性环境中,由于腐蚀钝化,Cr的速率常数显著降低。复合材料Fe-CBC-MO对三种重金属(Cr、Cu、Zn)均有较好的去除效果,显示出较强的重金属修复能力。
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The role of nanoscale zero-valent iron (nZVI) in remediation of heavy metal contamination in groundwater overexploitation areas
This study investigates the remediation of groundwater contaminated with heavy metals in overexploited areas using a modified approach involving the use of corn plant parts to produce biochar. The biochar was modified using a hydrothermal method, employing nanoscale zero-valent iron (nZVI) material to create a composite material for adsorbing heavy metals from water bodies. Adsorption experiments were conducted on the presence of Cr, Cu, and Zn ions in the water. The experimental investigations focused on the dosage of adsorption materials, solution pH, and stability of the adsorption material to validate the enhanced capability of the nanoscale zero-valent iron modified biochar composite (Fe-CBC-MO) for removing and adsorbing heavy metal ions (Cu, Cr, and Zn) from water. The results indicate that the adsorption capacity follows the sequence: Cr > Zn > Cu. Increasing the adsorbent dosage provides more adsorption sites, thereby improving the removal efficiency of heavy metals from water bodies. Considering cost-effectiveness, an optimal dosage of 0.15 g was selected. Under alkaline conditions, Cu and Zn ions precipitated significantly, leading to sustained high removal rates of heavy metals. Correspondingly, the rate constants were also relatively high. In acidic environments, the rate constant for Cr decreased significantly due to corrosion passivation. The composite material Fe-CBC-MO exhibited remarkable removal efficiency for all three heavy metals (Cr, Cu, Zn), demonstrating a strong capability for remediating heavy metal pollution.
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Materials Express
Materials Express NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY
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