Space-Confined Synthesis of Thinner Ether-Functionalized Nanofiltration Membranes with Coffee Ring Structure for Li+/Mg2+ Separation

Positively charged nanofiltration membranes have attracted much attention in the field of lithium extraction from salt lakes due to their excellent ability to separate mono- and multi-valent cations. However, the thicker selective layer and the lower affinity for Li + result in lower separation efficiency of the membranes. Here, PEI-P membranes with highly efficient Li + /Mg 2+ separation performance are prepared by introducing highly lithophilic 4,7,10-Trioxygen-1,13-tridecanediamine (DCA) on the surface of PEI-TMC membranes using a post-modification method. Characterization and experimental results show that the utilization of the DCA-TMC crosslinked structure as a space-confined layer to inhibit the diffusion of the monomer not only increases the positive charge density of the membrane but also reduces its thickness by ≈35% and presents a unique coffee-ring structure, which ensures excellent water permeability and rejection of Mg 2+ . The ion–dipole interaction of the ether chains with Li + facilitates Li + transport and improves the Li + /Mg 2+ selectivity ( S Li,Mg = 23.3). In a three-stage nanofiltration process for treating simulated salt lake water, the PEI-P membrane can reduce the Mg 2+ /Li + ratio of the salt lake by 400-fold and produce Li 2 CO 3 with a purity of more than 99.5%, demonstrating its potential application in lithium extraction from salt lakes.