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Evolution of photocatalytic membrane for antibiotics degradation: Perspectives and insights for sustainable environmental remediation

光催化 抗生素 废物管理 化学 环境科学 纳米技术 材料科学 工程类 催化作用 生物化学 有机化学
作者
Jing Yi Chin,Abdul Latif Ahmad,Siew Chun Low
出处
期刊:Journal of water process engineering [Elsevier]
卷期号:51: 103342-103342 被引量:42
标识
DOI:10.1016/j.jwpe.2022.103342
摘要

Development of antibiotic resistance genes contributed by unregulated disposal of antibiotics to the environment has become an overwhelming risk worldwide. An evolutionary technology, photocatalytic membrane (PM) that integrates both photocatalysis and membrane separation in one unit is introduced to treat the antibiotics. The ability of photocatalytic membrane to simultaneously degrade antibiotics while promoting handy recovery of photocatalysts from the wastewater dramatically enhances process sustainability and minimize treatment unit footprint. To date, reviews on antibiotics removal only focus on standalone photocatalysis and membrane process. In this work, a pioneer overview that focuses on treatment of one specific pollutant: antibiotics by employing the hybrid PM technology was performed. Configurations of PM, materials including ceramic and polymer used as the membrane base are summarized, followed by factors influencing performance of the integrated process. Photocatalysts harnessed in photocatalytic membrane to treat antibiotics mainly focused on TiO2 and g-C3N4, regardless of the materials of membranes. From energy consumption and economic evaluations of PM technology, process parameters are reported to significantly influence the energy requirement and costing. As light source is accounted for the highest portion of energy consumption, harnessing natural sunlight to power the photocatalytic reaction would be a great direction to be ventured into. Future potential of sunlight-powered photocatalytic membrane to treat antibiotics in the escalating aquaculture industry is proposed.
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