Removal of arsenic from water by silver nanoparticles and Fe-Ce mixed oxide supported on polymeric anion exchanger

IF 5.9 2区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Journal of Environmental Sciences-china Pub Date : 2024-04-18 DOI:10.1016/j.jes.2024.04.009
Li Li , Su-juan Yu , Rong-gang Zheng , Qing-cun Li , Rui Liu , Jing-fu Liu
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Abstract

By encapsulating nanoscale particles of goethite (α-FeO(OH)), hydrous ceric oxide (CeO2·H2O, HCO) and silver nanoparticles (AgNPs) in the pores of polystyrene anion exchanger D201, a novel nanocomposite FeO(OH)-HCO-Ag-D201 was prepared for the effective removal of arsenic from water. The isotherm study shows that FeO(OH)-HCO-Ag-D201 has excellent adsorption performance for As(III) and As(V), with an increased adsorption capacity of As(III) to 40.12 mg/g compared to that of 22.03 mg/g by the composite adsorbent without AgNPs (FeO(OH)-HCO-D201). The adsorption kinetics data showed that the sorption rate of FeO(OH)-HCO-Ag-D201 for As(III) is less than that for As(V), and the adsorption of As(III) and As(V) were consistent with the pseudo-second-order model and the pseudo-first-order model, respectively. Neutral or basic conditions are favored for the adsorption of As(III/V) by FeO(OH)-HCO-Ag-D201. Compared with nitrate/chloride/bicarbonate, sulfate/silicate/phosphate showed more remarkable inhibition of arsenic removal by FeO(OH)-HCO-Ag-D201, whereas natural organic matter showed no interference to the arsenic removal. The As(V) adsorption involved different interactions such as electrostatic attraction and surface complexation, while the adsorption of As(III) involved the part oxidization of As(III) to As(V) and the simultaneous adsorption of As(III) and As(V). In addition to the Ce(IV) in CeO2·H2O acted as an oxidant, the synergistic effect of α-FeO(OH) and AgNPs also contributed to the oxidization of As(III) to As(V). Moreover, the reusable property suggested that this FeO(OH)-HCO-Ag-D201 nanocomposite has great potential for arsenic-contaminated water purification.

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聚合物阴离子交换器上支持的银纳米粒子和铁铈混合氧化物去除水中的砷
通过在聚苯乙烯阴离子交换剂 D201 的孔隙中封装纳米级的戈氏体(α-FeO(OH))、无水氧化陶瓷(CeO2-H2O, HCO)和纳米银颗粒(AgNPs),制备了一种新型纳米复合材料 FeO(OH)-HCO-Ag-D201 ,用于有效去除水中的砷。等温线研究表明,FeO(OH)-HCO-Ag-D201 对 As(III)和 As(V)具有优异的吸附性能,与不含 AgNPs 的复合吸附剂(FeO(OH)-HCO-D201)的 22.03 mg/g 相比,As(III)的吸附容量增加到 40.12 mg/g。吸附动力学数据表明,FeO(OH)-HCO-Ag-D201 对 As(III)的吸附速率小于对 As(V)的吸附速率,对 As(III)和 As(V)的吸附分别符合伪二阶模型和伪一阶模型。FeO(OH)-HCO-Ag-D201 对 As(III/V)的吸附有利于中性或碱性条件。与硝酸盐/氯酸盐/碳酸氢盐相比,硫酸盐/硅酸盐/磷酸盐对 FeO(OH)-HCO-Ag-D201 除砷的抑制作用更为显著,而天然有机物对砷的去除没有干扰。As(V)的吸附涉及静电吸引和表面络合等不同的相互作用,而 As(III)的吸附涉及 As(III)部分氧化为 As(V)以及 As(III)和 As(V)的同时吸附。除了 CeO2-H2O 中的 Ce(IV) 起到氧化剂的作用外,α-FeO(OH) 和 AgNPs 的协同作用也有助于将 As(III) 氧化成 As(V)。此外,这种可重复使用的特性表明,FeO(OH)-HCO-Ag-D201 纳米复合材料在砷污染水的净化方面具有巨大潜力。
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来源期刊
Journal of Environmental Sciences-china
Journal of Environmental Sciences-china 环境科学-环境科学
CiteScore
13.70
自引率
0.00%
发文量
6354
审稿时长
2.6 months
期刊介绍: The Journal of Environmental Sciences is an international journal started in 1989. The journal is devoted to publish original, peer-reviewed research papers on main aspects of environmental sciences, such as environmental chemistry, environmental biology, ecology, geosciences and environmental physics. Appropriate subjects include basic and applied research on atmospheric, terrestrial and aquatic environments, pollution control and abatement technology, conservation of natural resources, environmental health and toxicology. Announcements of international environmental science meetings and other recent information are also included.
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