The design of nanosheets
interlayer between the substrate and polyamide
layer has attracted growing attention to improve the performance of
thin-film composite membranes. However, the membrane size is limited
by current fabrication methods such as vacuum filtration. Herein,
a high-performance MXene (Ti3C2T
x
) interlayered polyamide forward osmosis (FO) membrane
is fabricated based on a combination of a facile and scalable brush-coating
of MXene on nylon substrates and the interfacial polymerization process.
The as-prepared FO membrane shows high water permeability of 31.8
L m–2 h–1 and low specific salt
flux of 0.27 g L–1 using 2.0 mol L–1 sodium chloride as the draw solution. This is attributed to the
adjustment of substrate properties and the polyamide layer by coating
of MXene as well as the facilitation of water transportation by the
interlayer distances between Ti3C2T
x
. The membrane also exhibits a good organic solvent
forward osmosis performance with high ethanol flux as 9.5 L m–2 h–1 and low specific salt flux
of 0.4 g L–1 using 2.0 mol L–1 lithium chloride as the draw solution. Moreover, the MXene interlayered
FO membrane demonstrates a feasible application in real seawater desalination
and industrial textile wastewater treatment. This work presents an
effective approach to fabricating nanomaterials interlayered FO membranes
with superior performance for both desalination and organic solvent
recovery.
Tight ultrafiltration (TUF) membranes with high performance have attracted more and more attention in the separation of organic molecules. To improve membrane performance, some methods such as interface polymerization have been applied. However, these approaches have complex operation procedures. In this study, a polydopamine (PDA) modified MoS2 (MoS2@PDA) blending polyethersulfone (PES) membrane with smaller pore size and excellent selectivity was fabricated by a simple phase inversion method. The molecular weight cut-off (MWCO) of as-prepared MoS2@PDA mixed matrix membranes (MMMs) changes, and the effective separation of dye molecules in MoS2@PDA MMMs with different concentrations were obtained. The addition amount of MoS2@PDA increased from 0 to 4.5 wt %, resulting in a series of membranes with the MWCO values of 7402.29, 7007.89, 5803.58, 5589.50, 6632.77, and 6664.55 Da. The MWCO of the membrane M3 (3.0 wt %) was the lowest, the pore size was defined as 2.62 nm, and the pure water flux was 42.0 L m−2 h−1 bar−1. The rejection of Chromotrope 2B (C2B), Reactive Blue 4 (RB4), and Janus Green B (JGB) in aqueous solution with different concentrations of dyes was better than that of unmodified membrane. The separation effect of M3 and M0 on JGB at different pH values was also investigated. The rejection rate of M3 to JGB was higher than M0 at different pH ranges from 3 to 11. The rejection of M3 was 98.17–99.88%. When pH was 11, the rejection of membranes decreased with the extension of separation time. Specifically, at 180 min, the rejection of M0 and M3 dropped to 77.59% and 88.61%, respectively. In addition, the membrane had a very low retention of salt ions, Nacl 1.58%, Na2SO4 10.52%, MgSO4 4.64%, and MgCl2 1.55%, reflecting the potential for separating salts and dyes of MoS2@PDA/PES MMMs.
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