Advanced lithium extraction nanofiltration membrane with fast transport channels via competitive diffusion and reaction of rigid electropositive phenylbiguanide molecules

IF 8.4 1区 工程技术 Q1 ENGINEERING, CHEMICAL
Yunhao Li , Haijun Yu , Lixin Li , Yanfang Liu , Guodong Kang , Xinmiao Liang , Yiming Cao
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Abstract

The utilization of nanofiltration membranes for lithium extraction from Salt-Lake holds the potential to address lithium resource scarcity and drive energy transformation. Nevertheless, the trade-off effect between water permeability and Mg2+/Li+ separation selectivity poses a challenge in the application of these membranes. In this work, rigid-flexible interpenetration and competitive diffusion reaction strategies were proposed to regulate the pore structure and charge density of the functional layer, thus enhancing the overall separation performance of nanofiltration membrane. Phenylbiguanide (PBG) possessing rigid structure, high positive charge density, and low energy transfer barrier was embedded into flexible polyethyleneimine-based polyamide network. This integration facilitated the formation of continuous and semi-permanent microcavities with rigid-flexible coupled structure, and meanwhile, elevated the density of positive charges. Consequently, the modification extended the water molecular transport channels within the functional layer, leading to a notable enhancement in pure water flux, from 7.40 to 26.43 L m−2h−1. In addition, due to the faster diffusion of PBG than polyethyleneimine with high molecular weight (70000 Da, as aqueous monomer in this work), it could react with excess 1,3,5-trimesoyl chloride (TMC) on the surface of initial membrane to form a new polyamide layer, which repaired the defects in the functional layer and also enhanced the charge density inside pore channels. Therefore, Mg2+/Li+ separation selectivity factor increased from 3.79 of TFC membrane to 22.98 of PBG membrane, i.e., by about 6 times. This study provided an effective strategy to develop nanofiltration membranes with both good water permeability and Mg2+/Li+ selectivity.

Abstract Image

通过刚性正电分子的竞争性扩散和反应实现具有快速传输通道的先进锂萃取纳滤膜
利用纳滤膜从盐湖中提取锂有望解决锂资源稀缺的问题,并推动能源转型。然而,透水性和 Mg2+/Li+ 分离选择性之间的权衡效应给这些膜的应用带来了挑战。本研究提出了刚柔互穿和竞争扩散反应策略来调节功能层的孔隙结构和电荷密度,从而提高纳滤膜的整体分离性能。苯基双胍(PBG)具有刚性结构、高正电荷密度和低能量传递障碍,被嵌入到柔性聚乙烯亚胺基聚酰胺网络中。这种整合促进了具有刚柔耦合结构的连续半永久性微腔的形成,同时提高了正电荷密度。因此,这种改性扩展了功能层内的水分子传输通道,从而显著提高了纯水通量,从 7.40 升 m-2h-1 提高到 26.43 升 m-2h-1。此外,由于 PBG 的扩散速度快于高分子量的聚乙烯亚胺(7 万 Da,在本研究中为水单体),它可以与初始膜表面过量的 1,3,5-三甲基甲酰氯(TMC)反应,形成新的聚酰胺层,从而修复了功能层的缺陷,并提高了孔道内的电荷密度。因此,Mg2+/Li+ 分离选择因子从 TFC 膜的 3.79 提高到 PBG 膜的 22.98,即提高了约 6 倍。这项研究为开发具有良好透水性和 Mg2+/Li+ 选择性的纳滤膜提供了一种有效的策略。
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来源期刊
Journal of Membrane Science
Journal of Membrane Science 工程技术-高分子科学
CiteScore
17.10
自引率
17.90%
发文量
1031
审稿时长
2.5 months
期刊介绍: The Journal of Membrane Science is a publication that focuses on membrane systems and is aimed at academic and industrial chemists, chemical engineers, materials scientists, and membranologists. It publishes original research and reviews on various aspects of membrane transport, membrane formation/structure, fouling, module/process design, and processes/applications. The journal primarily focuses on the structure, function, and performance of non-biological membranes but also includes papers that relate to biological membranes. The Journal of Membrane Science publishes Full Text Papers, State-of-the-Art Reviews, Letters to the Editor, and Perspectives.
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