Regulation of interfacial polymerization process based on reversible enamine reaction for high performance nanofiltration membrane

The regulation of interfacial polymerization (IP) is the critical procedure for the preparation and industrialization of thin film composite (TFC) nanofiltration (NF) membranes. However, the IP control is still a huge challenge based on the extremely rapid reaction rate during the fabrication of the membrane. Herein, a new strategy was developed to modulate the IP process to increase the NF membrane performance. The aldehyde oxidized dextran (ODex) interlayer was deposited on the polysulfone ultrafiltration substrate, and the enamine would form between the secondary amines of aqueous phase monomer piperazine (PIP) and aldehyde groups of the ODex. Based on the by-products of IP, the enamine gradually decomposed reversibly in a hydrogen ion environment and the immobilized PIP was released and continued to react with organic phase monomer trimesoyl chloride (TMC). Accordingly, a thinner and exhibiting nanowire structures separation layer with fewer defects was obtained. The permeance of the optimal NF membrane with 0.7 wt% ODex interlayer deposition concentration could reach up to 208 ± 10.4 Lm −2 h −1 MPa −1 , which was more than 2.5 times permeance of the ordinary NF membrane, and the rejection rate for Na 2 SO 4 could reach 99.3 ± 0.3%. In addition, the mono- and divalent ion selectivity of the modified membrane was also greatly improved (α NaCl/Na2SO4 = 115). This study provides a new idea for the regulation of IP process, thereby suggesting a reasonable proposal for improving the performance of TFC NF membranes. •The enamine was formed between the secondary amines of piperazine and the aldehyde group on the oxidized dextran interlayer. •The interfacial polymerization procedure was effectively regulated by a reversible enamine reaction. •The effect of enamine reversible reaction on the structure of nanofiltration membrane was discussed in detail. •The performance of modified NF membranes for monovalent/divalent salts selectivity was significantly improved.