反冲洗
膜
材料科学
水处理
生物污染
碳纳米管
化学工程
导电体
饮用水净化
碳纤维
聚合物
电导率
流出物
纳米技术
产量(工程)
电势能
污水处理
制浆造纸工业
环境科学
复合材料
工艺工程
电阻率和电导率
废水
环境工程
储能
电
膜技术
作者
Yongke Zhang,Jiajian Xing,Gaoliang Wei,Linhua Rao,G. He,Hao Du,Haiguang Zhang,Xu Wang,Shuo Chen,Xie Quan
标识
DOI:10.1038/s41467-025-66260-3
摘要
Decentralized water supply is essential for providing clean and safe drinking water, especially in underdeveloped regions. Membrane technology is a key process for removing pathogens and suspended solids from polluted water sources. This study constructs electrically conductive membranes (ECMs) using carbon nanotubes (CNTs) confined within polarized poly(vinylidene fluoride) (PVDF) through C-F interactions. The resulting membranes achieve ultrahigh water permeance, 3.5 to 5.2 times higher than four commercial polymer membranes with similar pore sizes. They maintain good electrical conductivity and mechanical strength. Applying a weak negative potential induces electrostatic repulsion between the ECMs and foulants, enhancing antifouling performance by over 10 times in terms of backwashing interval compared to conventional polymer membranes. A demonstration project confirms the feasibility of industrial-scale production with a capacity of 11.5 m2 h−1, corresponding to an annual yield of approximately 100,000 m². Another field demonstration for drinking water treatment, with a capacity of 300 m3 day−1, shows improved effluent quality, 53% energy savings, and 95% cost reduction for chemical cleaning compared to conventional processes. This study provides a cost-effective and efficient solution for addressing drinking water security challenges in underdeveloped regions through the enhanced performance of CNTs-PVDF ECMs. Access to clean water is crucial, especially in underdeveloped areas. Here, authors develop electrically conductive membranes using carbon nanotubes and poly(vinylidene fluoride), achieving higher water permeance and improved antifouling, reducing costs and energy use
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