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用于水处理的先进氧化工艺与纳米材料联用

Advanced Oxidation Processes Coupled with Nanomaterials for Water Treatment.

作者信息

Cardoso Inês M F, Cardoso Rita M F, da Silva Joaquim C G Esteves

机构信息

Chemistry Research Unit (CIQUP), DGAOT, Faculty of Sciences of University of Porto (FCUP), Rua do Campo Alegre 697, 4169-007 Porto, Portugal.

出版信息

Nanomaterials (Basel). 2021 Aug 11;11(8):2045. doi: 10.3390/nano11082045.

DOI:10.3390/nano11082045
PMID:34443876
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8400743/
Abstract

Water quality management will be a priority issue in the near future. Indeed, due to scarcity and/or contamination of the water, regulatory frameworks will be increasingly strict to reduce environmental impacts of wastewater and to allow water to be reused. Moreover, drinking water quality standards must be improved in order to account for the emerging pollutants that are being detected in tap water. These tasks can only be achieved if new improved and sustainable water treatment technologies are developed. Nanomaterials are improving the ongoing research on advanced oxidation processes (AOPs). This work reviews the most important AOPs, namely: persulfate, chlorine and NHCl based processes, UV/HO, Fenton processes, ozone, and heterogeneous photocatalytic processes. A critical review of the current coupling of nanomaterials to some of these AOPs is presented. Besides the active role of the nanomaterials in the degradation of water contaminants/pollutants in the AOPs, the relevance of their adsorbent/absorbent function in these processes is also discussed.

摘要

水质管理将是近期的一个优先问题。事实上,由于水资源的稀缺和/或污染,监管框架将越来越严格,以减少废水对环境的影响并实现水的再利用。此外,饮用水质量标准必须提高,以应对在自来水中检测到的新兴污染物。只有开发出新的改进型可持续水处理技术,这些任务才能实现。纳米材料正在推动对高级氧化工艺(AOPs)的持续研究。本文综述了最重要的AOPs,即:过硫酸盐、基于氯和NHCl的工艺、UV/HO、芬顿工艺、臭氧和多相光催化工艺。对目前纳米材料与其中一些AOPs的耦合进行了批判性综述。除了纳米材料在AOPs中对水污染物/污染物降解的积极作用外,还讨论了它们在这些过程中的吸附剂/吸收剂功能的相关性。

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