通过焦耳酚和聚乙烯亚胺的简易共沉积设计高性能电驱动纳滤膜,实现垃圾填埋场渗滤液浓缩物的可持续资源回收

Jiale Du , Zijian Yu , Jiangjing Li , Shuangling Xie , Lianxin Chen , Jiuyang Lin
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摘要

垃圾填埋场渗滤液浓缩物的传统处理方法主要是降解或去除腐殖质,容易造成二次污染,不符合当前可持续发展的要求。垃圾填埋场渗滤液浓缩物可持续管理的关键是将现有的腐殖质和无机盐作为独立资源进行精确分馏。在此,我们利用高碘酸钠诱导焦聚糖醇和聚乙烯亚胺在疏松的聚酰胺基纳滤基底膜上共沉积,制备了电驱动纳滤膜,作为高性能阴离子传导膜。焦棓酚/聚乙烯亚胺复合涂层使电驱动纳滤膜的表面负电荷和比电阻降低,从而增强了阴离子传导能力。在电驱动纳滤过程中,经过 30 分钟共沉积的制备膜具有极快的阴离子转移速度和出色的分馏性能,腐殖质回收率高达 99.08%。特别是,所制备的膜在 8 个周期的电驱动纳滤操作中表现出稳定的分离能力,显示出较低的结垢倾向。我们的研究揭示了通过共沉积焦耳酚和聚乙烯亚胺来制造高性能电驱动纳滤膜的策略,为垃圾填埋场渗滤液浓缩物的可持续处理铺平了道路。
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Design of high-performance electro-driven nanofiltration membrane via facile co-deposition of pyrogallol and polyethyleneimine for sustainable resource recovery from landfill leachate concentrate
Conventional treatment methods of landfill leachate concentrate mainly focus on the degradation or removal of humic substance, which are prone to secondary pollution and fail to meet the requirements of current sustainable development. The key to sustainable management of landfill leachate concentrate is to precisely fractionate the existing humic substance and inorganic salts as individual resources. Here, electro-driven nanofiltration membranes were fabricated by sodium periodate inducing co-deposition of pyrogallol and polyethyleneimine on the loose polyamide-based nanofiltration substrate membranes as high-performance anion conducting membrane. The pyrogallol/polyethyleneimine composite coating layer endowed the electro-driven nanofiltration membranes with reduced surface negative charge and specific areal electric resistance for enhanced anion transfer. During the electro-driven nanofiltration process, the fabricated membrane with a 30-min co-deposition exhibited an extremely fast anion transfer rate and outstanding fractionation performance with 99.08 ​% humic substance recovery of 99.08 ​%. Particularly, the fabricated membrane showed stable separation capacity over an 8-cycle electro-driven nanofiltration operation, demonstrating a low fouling propensity. Our study sheds light on the strategy to fabricate high-performance electro-driven nanofiltration membranes via co-deposition of pyrogallol and polyethyleneimine, paving the way to sustainable treatment of landfill leachate concentrate.
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