Abstract
In this work, we investigate the effect of membrane surface chemistry on fouling in surface water treatment for polyelectrolyte multilayer based nanofiltration (NF) membranes. The polyelectrolyte multilayer approach allows us to prepare three membranes with the same active separation layer, apart from a difference in surface chemistry: nearly uncharged crosslinked Poly(allylamine hydrochloride) (PAH), strongly negative poly(sodium 4-styrene sulfonate) PSS and zwitterionic poly(2-methacryloyloxyethyl phosphorylcholine-co-acrylic acid) (PMPC-co-AA). Initially, we study foulant adsorption for the three different surfaces (on model interfaces), to demonstrate how a different surface chemistry of the top layer affects the subsequent adsorption of five different model foulants (Humic Acids, Alginates, Silica Nanoparticles, negatively and positively charged Proteins). Subsequently, we study fouling of the same model foulants on our polyelectrolyte multilayer based hollow fiber NF membranes with identical surface chemistry to the model surfaces. Our results show that nearly uncharged crosslinked PAH surface generally fouls more than strongly negatively charged PSS surface. While negative BSA adsorbs better on PSS, probably due to charge regulation. Overall, fouling was mainly driven by electrostatic and acid-base interactions, which led, for both PAH and PSS terminated membranes, to flux decline and changes in selectivity. In contrast, we demonstrate through filtration experiments carried out with synthetic and real surface water, that the bio-inspired zwitterionic phosphatidylcholine surface chemistry exhibits excellent fouling resistance and thus stable performance during filtration.
Highlights
High quality drinking water is produced worldwide from surface water
We investigate the effect of membrane surface chem istry on fouling in surface water treatment for polyelectrolyte multilayer based nanofiltration membranes
We study the adsorption of model foulants, such as bioproteins (Lysozyme and BSA), standard humic acids, silica nanoparticles (LUDOX®) and alginates, on PEMs prepared on model surfaces with final layers with different charge and surface chemistry
Summary
High quality drinking water is produced worldwide from surface water. This is partly possible thanks to the advances made in membrane filtration. In the last 20 years, membrane filtration has started to replace conventional water treatment techniques, such as coagulation, floccu lation, sedimentation, flotation, and sand filtration [1,2]. This is espe cially due to their versatility: membranes allow the removal of a wide spectrum of components, ranging from suspended solids (micro filtration) to small organic pollutants and ions (reverse osmosis) [2]. NF allows the removal of humic substances [4,5], micro pollutants [6,7], heavy metals and salinity [8] from surface water, with a substantially lower energy footprint than reverse osmosis [2,9]
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