纳滤
聚酰胺
界面聚合
化学工程
膜
材料科学
单体
水解
聚合
溶剂
高分子化学
聚合物
氯化锂
萃取(化学)
锂(药物)
图层(电子)
离子
氯化物
离子液体
无机化学
水溶液
芳纶
缓压渗透
卤水
基质(水族馆)
化学
离子强度
作者
Shuzhen Zhao,Liheng Dai,Feidong Yang,Bowen Li,Pengfei Zhang,Yanyan Liu,Mengyang Hu,Kecheng Guan,Ryosuke Takagi,Hideto Matsuyama
摘要
ABSTRACT Efficient lithium extraction from brines remains challenging due to the comparable hydrated radii of Li + and Mg 2+ and the extreme ionic strength of the feed solutions. In this work, a reconstructed polyamide (PA) nanofiltration membrane was developed via a two‐stage interfacial polymerization strategy, achieving simultaneous structural and electrostatic engineering of the PA selective layer. In the first stage, the relationship between substrate physicochemical properties and the resulting density and stability of the nascent polyamide layer was established through regulation of piperazine (PIP) adsorption‐diffusion behavior. In the second stage, careful selection of a non‐aqueous solvent effectively suppressed acyl chloride hydrolysis and preserved abundant active sites, allowing the successful incorporation of a bidentate quaternary ammonium monomer into the newly formed PA network. This reconstruction generated a confined sub‐nanometer selective layer with a tunable mild positive charge, enabling synergistic steric and electrostatic discrimination between Li + and Mg 2+ . The optimized membrane exhibited excellent Li + /Mg 2+ separation factors that exceeded 60 under diverse operating conditions, while the integrated nanofiltration process achieved nearly 60‐fold lithium enrichment, demonstrating a practical applicability in complex brine matrices. This study establishes a generalizable molecular‐level design reference for co‐ion selective membranes capable of lithium extraction under chemically demanding, high‐ionic‐strength conditions.
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