Litcius/Paper detail

Polyamide-based membranes with structural homogeneity for ultrafast molecular sieving

Liang Shen, Ruihuan Cheng, Ming Yi, Wei‐Song Hung, Susilo Japip, Lian Tian, Xuan Zhang, Shu‐Dong Jiang, Song Li, Yan Wang

2022Nature Communications348 citationsDOIOpen Access PDF

Abstract

Thin-film composite membranes formed by conventional interfacial polymerization generally suffer from the depth heterogeneity of the polyamide layer, i.e., nonuniformly distributed free volume pores, leading to the inefficient permselectivity. Here, we demonstrate a facile and versatile approach to tune the nanoscale homogeneity of polyamide-based thin-film composite membranes via inorganic salt-mediated interfacial polymerization process. Molecular dynamics simulations and various characterization techniques elucidate in detail the underlying molecular mechanism by which the salt addition confines and regulates the diffusion of amine monomers to the water-oil interface and thus tunes the nanoscale homogeneity of the polyamide layer. The resulting thin-film composite membranes with thin, smooth, dense, and structurally homogeneous polyamide layers demonstrate a permeance increment of ~20-435% and/or solute rejection enhancement of ~10-170% as well as improved antifouling property for efficient reverse/forward osmosis and nanofiltration separations. This work sheds light on the tunability of the polyamide layer homogeneity via salt-regulated interfacial polymerization process.

Topics & Concepts

PolyamideInterfacial polymerizationMembraneMaterials scienceNanofiltrationThin-film composite membraneReverse osmosisChemical engineeringHomogeneity (statistics)PolymerizationPermeanceComposite numberNanoscopic scaleThin filmPolymer chemistryMonomerPolymerComposite materialNanotechnologyChemistryPermeationBiochemistryEngineeringMathematicsStatisticsMembrane Separation TechnologiesNanopore and Nanochannel Transport StudiesMembrane Separation and Gas Transport