Facile fabrication of polyethyleneimine interlayer-assisted graphene oxide incorporated reverse osmosis membranes for water desalination.

Current reverse osmosis membrane still suffers from permeability/selectivity trade-off, chlorine attack and fouling. To address these problems, a new interlayer-assisted interfacial polymerization (i.e., polyethyleneimine (PEI) interlayer) in the presence of graphene oxide (GO) at various loading was adopted in this work. Their effects on membrane properties and performances were systematically investigated. Results showed that the PEI-interlayered thin film composite (iTFC) membrane exhibited higher pure water permeance (PWP) (1.76 L/m2·h·bar) and NaCl rejection (97.69%) compared to the conventional TFC (cTFC) membrane (1.34 L/m2·h·bar; 96.91%), assigning to the thin and compact PA formed. Performance of iTFC membrane was further enhanced upon inclusion of 0.01 wt/ v % GO, producing PEI-interlayered thin film nanocomposite (iTFN-10) membrane with greater PWP (2.66 L/m2·h·bar) without compensating rejection. This was ascribed to the enhanced surface roughness, hydrophilicity and nanochannels created by GO within the PA. The antifouling property of iTFN-10 membrane was comparable with commercial TFC but better than iTFC membrane. Unlike iTFC membrane, the NaCl rejection of iTFN-10 membrane was least deteriorated after chlorination. This membrane also demonstrated better antibacterial properties (E. coli : 44.26% and S. aureus : 77.55%) than commercial membrane (E. coli : 24.68% and S. aureus : 48.98%) due to the presence of amine groups on membrane surface. [Display omitted] • Interlayer-assisted IP yielded TFC membrane with thin, uniform and compact PA. • Embedding GO in PA layer further enhanced the properties of interlayered membrane. • PEI-interlayered membrane showed improved desalination and antibacterial properties. • The optimized interlayered membrane could also reduce the degree of chlorine attack. [ABSTRACT FROM AUTHOR]