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    题名: Progress of Interfacial Polymerization Techniques for Polyamide Thin Film (Nano)Composite Membrane Fabrication: A Comprehensive Review
    作者: Seah, MQ;Lau, WJ;Goh, PS;Tseng, HH;Wahab, RA;Ismail, AF
    关键词: interfacial polymerization;polyamide;thin film composite;membrane;nanomaterials
    日期: 2020
    上传时间: 2022-08-09T09:27:18Z (UTC)
    出版者: MDPI
    摘要: In this paper, we review various novel/modified interfacial polymerization (IP) techniques for the fabrication of polyamide (PA) thin film composite (TFC)/thin film nanocomposite (TFN) membranes in both pressure-driven and osmotically driven separation processes. Although conventional IP technique is the dominant technology for the fabrication of commercial nanofiltration (NF) and reverse osmosis (RO) membranes, it is plagued with issues of low membrane permeability, relatively thick PA layer and susceptibility to fouling, which limit the performance. Over the past decade, we have seen a significant growth in scientific publications related to the novel/modified IP techniques used in fabricating advanced PA-TFC/TFN membranes for various water applications. Novel/modified IP lab-scale studies have consistently, so far, yielded promising results compared to membranes made by conventional IP technique, in terms of better filtration efficiency (increased permeability without compensating solute rejection), improved chemical properties (crosslinking degree), reduced surface roughness and the perfect embedment of nanomaterials within selective layers. Furthermore, several new IP techniques can precisely control the thickness of the PA layer at sub-10 nm and significantly reduce the usage of chemicals. Despite the substantial improvements, these novel IP approaches have downsides that hinder their extensive implementation both at the lab-scale and in manufacturing environments. Herein, this review offers valuable insights into the development of effective IP techniques in the fabrication of TFC/TFN membrane for enhanced water separation.
    URI: http://dx.doi.org/10.3390/polym12122817
    https://www.webofscience.com/wos/woscc/full-record/WOS:000602477200001
    https://ir.csmu.edu.tw:8080/handle/310902500/25030
    關聯: POLYMERS ,2020 ,v12 ,issue 12
    显示于类别:[中山醫學大學研究成果] 其他文獻

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