面向可持续水净化的工程超透防污水渠仿生膜

IF 4.9 Q1 ENGINEERING, CHEMICAL
Xuesong Li , Linyan Yang , Jaume Torres , Rong Wang
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引用次数: 0

摘要

基于水道的仿生膜(WBM)由于水道在提高透水性和打破渗透选择性权衡方面的有效性而越来越受到关注。然而,超渗透WBM可能会遇到严重的膜污染问题,因为高的水通量往往会导致加速污染,从而损害从使用水道中获得的好处。本文提出了一种新的原位改性方案,以提高超渗透WBM的防污性能。通过简单的自组装方法,用聚乙二醇刷(即聚乙二醇化)对掺入水通道蛋白(AQP)水通道的纳米囊泡进行功能化,然后通过界面聚合将其封装在薄膜复合膜的选择性层中。改性对AQP功能的影响最小,导致WBM具有高透水性(~8.2LMH/bar)和良好的NaCl截留率(96.4%),与未改性的WBM相当。此外,原位改性大大提高了膜的表面亲水性,使膜对有机污染物具有优异的防污性能。防污性的提高确保了超渗透WBM的更可持续的运行,特别是在有利于高水通量的情况下。这种简单的改性策略为制造用于可持续水净化的超渗透和防污WBM提供了一种有效的方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Engineering Ultra-Permeable and Antifouling Water Channel-based Biomimetic Membranes toward Sustainable Water Purification

Water channel-based biomimetic membranes (WBMs) are gaining increasing attention due to the effectiveness of water channels in enhancing water permeability and breaking the permselectivity trade-off. However, the ultra-permeable WBMs may suffer from severe membrane fouling issue because a high-water flux tends to result in an accelerated fouling and thus compromises the benefits gained from the usage of water channels. Herein, a novel in-situ modification protocol was proposed to enhance the antifouling performance of ultra-permeable WBMs. The nanovesicles incorporated with aquaporin (AQP) water channels were functionalized with polyethylene glycol brushes (i.e., PEGylation) via a facile self-assembly approach and subsequently encapsulated in the selective layer of thin-film composite membranes through interfacial polymerization. The modification had minimal impact on the function of AQPs, resulting in WBMs with a high water permeance (∼8.2 LMH/bar) and good NaCl rejection (96.4%) comparable to the unmodified WBMs. Moreover, the in-situ modification drastically enhanced the surface hydrophilicity, which endowed the membrane with a superior fouling resistance to organic foulants. The improved fouling resistance ensured a more sustainable operation of ultra-permeable WBMs, particularly in scenarios that favor high water fluxes. This facile modification strategy provides an efficient way to fabricate ultra-permeable and antifouling WBMs for sustainable water purification.

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