Enhancing Mg2+/Li+ separation performance of nanofiltration membranes through polyelectrolyte modulation and surface modification

The increasing demand for lithium resources in the rapidly growing new energy industry has spurred interest in efficient lithium extraction from salt-lakes using Nanofiltration membranes, owing to their impressive ionic rejection capabilities. However, achieving effective Mg2+/Li+ selective separati...

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Bibliographic Details
Published in:Journal of membrane science 2024-05, Vol.701, p.122725, Article 122725
Main Authors: Wang, Jingjun, Zhang, Hao, Tian, Rukang, Shen, Huiyan, Li, Wei-Hua, Wang, Yunkun
Format: Article
Language:English
Subjects:
Mg2+/Li+ separation
Modified polyethersulfone substrate
Modulate interfacial polymerization
Polyelectrolyte
Post modified
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Summary:The increasing demand for lithium resources in the rapidly growing new energy industry has spurred interest in efficient lithium extraction from salt-lakes using Nanofiltration membranes, owing to their impressive ionic rejection capabilities. However, achieving effective Mg2+/Li+ selective separation remains a critical challenge for the widespread application of NF membranes in lithium extraction. This study focuses on the utilization of poly(dimethyldiallylammonium chloride)-modified polyethersulfone substrate for interfacial polymerization modulation in the preparation of polyamide nanofiltration membrane. The prepared membrane exhibited high MgCl2 rejection. And then the prepared membrane was subsequently optimized by post-modification with piperazine. Previous and subsequent modifications resulted in smaller pores, narrower pore size distribution, and lower surface negativity of the modified membrane. These properties contributed to the significantly higher MgCl2 rejection rate of the modified membrane (94.7%) than that of the Control membrane (46.1%). This excellent rejection property ensured the efficient Mg2+/Li + separation performance of the modified membrane. It was noteworthy that the Mg2+/Li+ separation factor for lithium extraction in simulated brine reached an impressive 77.2. In addition, the modified membrane retained a comparable pure water permeance and Na2SO4 rejection rate as the control membrane and showed excellent stability, significantly improving the Mg2+/Li + separation efficiency while reducing energy consumption. This study presents a simple strategy to fabricate NF membranes with excellent Mg2+/Li+ separation factor. [Display omitted] •The PDADMAC-modified substrate exhibits a weaker surface negativity.•The PDADMAC-modified substrate demonstrates enhanced PIP capacity.•PIP post-modification results in a narrower pore size distribution of the NF membrane.•The prepared membrane exhibits excellent Mg2+/Li+ selective separation performance.
ISSN:0376-7388
1873-3123
DOI:10.1016/j.memsci.2024.122725