Thin-film composite bicontinuous cubic lyotropic liquid crystal polymer membranes: Effects of anion-exchange on water filtration performance

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• 作者：Blaine M. Carter ; Brian R. Wiesenauer ; Richard D. Noble ; Douglas L. Gin
• 关键词：Lyotropic liquid crystal ; Nanofiltration ; Reverse osmosis ; Nanoporous ; Uniform pores ; Anion-exchange
• 刊名：Journal of Membrane Science
• 出版年：1 April, 2014
• 年：2014
• 卷：455
• 期：Complete
• 页码：143-151
• 全文大小：1292 K

文摘

The effects of anion-exchange on the filtration performance of thin-film composite (TFC) membranes with an active layer consisting of a nanostructured, lyotropic (i.e., surfactant) liquid crystal (LLC) polymer were investigated. These TFC LLC membranes are made by the in situ cross-linking of reactive amphiphiles (i.e., surfactants) that self-organize in the presence of glycerol into a type I bicontinuous cubic (Q_I) phase that contains a uniform, 3D-interconnected pore network lined with tethered cationic moieties and free mobile anions in the pores. In this study, a systematic series of experiments were performed to independently investigate how monovalent cations and anions affect transport in these TFC Q_I membranes. TFC Q_I membranes exposed to feed solutions that contain different cations (i.e., Li⁺_(aq), Na⁺_(aq), and K⁺_(aq)) but have the same monovalent anion as the free mobile anion in the membrane (i.e., Br^-_(aq)) have a constant flux and a high rejection (>98%). When the cation is kept constant (i.e., Na⁺_(aq)) and the anion in the feed is varied (i.e., Cl^-_(aq), Br^-_(aq), , and I^-_(aq)) and allowed to partially anion-exchange with the membrane, a high rejection is maintained (鈮?6%), but the flux significantly changes depending on the anion in the feed solution. The flux of the TFC Q_I membranes can also be repeatedly be cycled by contacting the membranes with different anions. Control experiments with completely anion-exchanged TFC Q_I membranes (i.e., with Cl^-_(aq), Br^-_(aq), _, and I^-_(aq)) showed that the rejection of sodium salts and uncharged organic solutes was virtually the same for all of the completely anion-exchanged membranes. As a whole, these results demonstrate that the flux of these TFC Q_I membranes can be tuned by changing the anion with little to no change in the rejection performance. The unique performance characteristics of TFC Q_I membranes may offer advantages over conventional NF and RO membranes for water purification applications or other aqueous separations.