College of Environmental Science and Engineering, Hunan University and Key Laboratory of Environmental Biology and Pollution Control (Hunan University), Ministry of Education, Changsha 410082, PR China.
College of Environmental Science and Engineering, Hunan University and Key Laboratory of Environmental Biology and Pollution Control (Hunan University), Ministry of Education, Changsha 410082, PR China.
Sci Total Environ. 2022 Oct 20;844:156924. doi: 10.1016/j.scitotenv.2022.156924. Epub 2022 Jun 30.
Arsenic is one of the most common and harmful pollutants in environment throughout the world, especially in aqueous solutions. In this study, two kinds of industrial solid wastes (Oxide scale (OS) and Blast furnace slag (BFS)) and one kind of phytoremediation plant waste (Ramie stalk) were used to prepare an environmentally friendly, low-cost, and efficient calcium silicate coated nano zero-valent iron (nZVI)/biochar composite (BOS) for As(V) adsorption. The potential environmental risks of BOS and their effects on removal of arsenic ions from aqueous media were investigated. The adsorption mechanism was explored and discussed based on XRD, SEM-EDS, XPS, etc. The results suggested that the environmental risk and heavy metals toxicity in BOS by co-pyrolysis were significantly reduced compared to the original materials, and no additional contaminant was observed in the subsequent experiments. Simultaneously, the BOS showed excellent As(V) removal capacity (>99%) and regenerative properties. The As(V) removal mechanisms are mainly ascribed to the complexation and co-precipitation between Fe and As, and the hydrogen bond between CO functional group of BOS and As. The mechanism of enhanced nZVI activity for As(V) removal was revealed. A protective layer of CaSiO was formed on the surface of nZVI during the co-pyrolysis process to prevent the passivation of nZVI. During the reaction process, the CaSiO covering the nZVI surface would be continuously detached to expose the fresh surface of nZVI, thus providing more redox activity and adsorption sites. This study provides a new way to treat and recycle industrial steel solid wastes and phytoremediation plant wastes, and the produced calcium silicate coated-nZVI/biochar composite is proposed to be a very promising material for practical remediation of As(V)-contaminated water bodies.
砷是全世界环境中最常见和最有害的污染物之一,尤其在水溶液中。在这项研究中,使用了两种工业固体废物(氧化皮(OS)和高炉渣(BFS))和一种植物修复植物废物(苎麻秸秆)来制备一种环保、低成本、高效的硅酸钙涂层纳米零价铁(nZVI)/生物炭复合材料(BOS),用于吸附 As(V)。研究了 BOS 的潜在环境风险及其对水溶液中砷离子去除的影响。基于 XRD、SEM-EDS、XPS 等对吸附机制进行了探讨和讨论。结果表明,与原始材料相比,共热解后 BOS 的环境风险和重金属毒性显著降低,随后的实验中没有观察到额外的污染物。同时,BOS 表现出优异的 As(V)去除能力(>99%)和可再生性能。As(V)的去除机制主要归因于 Fe 与 As 的络合和共沉淀,以及 BOS 的 CO 官能团与 As 之间的氢键。揭示了增强 nZVI 活性去除 As(V)的机制。在共热解过程中,在 nZVI 表面形成了一层 CaSiO 保护层,以防止 nZVI 的钝化。在反应过程中,覆盖在 nZVI 表面的 CaSiO 会不断脱落,暴露出新鲜的 nZVI 表面,从而提供更多的氧化还原活性和吸附位点。本研究为处理和回收工业钢铁固体废物和植物修复植物废物提供了一种新方法,所制备的硅酸钙涂层-nZVI/生物炭复合材料被提议为实际修复含 As(V)水体的很有前途的材料。
