Abstract
Ultrathin and smooth polyamide (PA) reverse osmosis (RO) membranes have attracted significant interest due to their potential advantages of high permeance and low fouling propensity. Although a layered interfacial polymerization (LIP) technique aided by the insertion of a polyelectrolyte interlayer has proven effective in fabricating ultrathin and uniform membranes, the RO performance and pH stability of the fabricated LIP membrane remain inadequate. In this study, a poly(piperazineamide) (PIPA) layer prepared via interfacial polymerization (IP) was employed as an interlayer to overcome the limitations of the prototype LIP method. Similar to the control polyelectrolyte-interlayered LIP membrane, the PIPA-interlayered LIP (pLIP) membrane had a much thinner (~20 nm) and smoother selective layer than the membrane fabricated via conventional IP due to the highly surface-confined and uniform LIP reaction. The pLIP membrane also exhibited RO performance exceeding that of the control LIP and conventional IP-assembled membranes, by enabling denser monomer deposition and a more confined interfacial reaction. Importantly, the chemically crosslinked PIPA interlayer endowed the pLIP membrane with higher pH stability than the control polyelectrolyte interlayer. The proposed strategy enables the fabrication of high-performance and pH-stable PA membranes using hydrophilic supports, which can be applied to other separation processes, including osmosis-driven separation and organic solvent filtration.
Highlights
Environmental pollution and freshwater shortages have become critical global challenges in modern society
We propose a new strategy to enhance the reverse osmosis (RO) performance and pH stability of the layered interfacial polymerization (LIP) membrane by employing a poly(piperazineamide) (PIPA) layer, prepared via interfacial polymerization (IP) of piperazine (PIP) and trimesoyl chloride (TMC) as an interlayer
The PIPA interlayer was optimized by characterizing its surface structure and RO performance as a function of PIP and TMC concentrations used for its formation (Figures 2 and 3)
Summary
Environmental pollution and freshwater shortages have become critical global challenges in modern society. The PA selective layer is typically synthesized via interfacial polymerization (IP) of two monomers, m-phenylenediamine (MPD) and trimesoyl chloride (TMC), dissolved in immiscible water and an organic solvent, respectively [5,6]. This IP process enables the fabrication of TFC membranes with reliable RO performance in a scalable and fast manner. We propose a new strategy to enhance the RO performance and pH stability of the LIP membrane by employing a poly(piperazineamide) (PIPA) layer, prepared via IP of piperazine (PIP) and TMC as an interlayer. The structure, physicochemical properties, RO performance, and pH stability of the optimized pLIP membrane were comprehensively characterized and compared with those of the control LIP and conventional IP membranes
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