Abstract
A novel technique for the covalent attachment of a light-responsive spiropyran onto polyamide thin film composite nanofiltration (NF) membranes in a one-step reaction using low-energy electron beam technology is described. The effect of illumination of the immobilized spiropyran was studied, as well as the resulting membrane properties with respect to MgSO4 retention, water permeability rate, and chlorine resistance. Electron beam irradiation showed a direct effect on the transformation of the rough PA NF membrane surface into a ridge-and-valley structure. Upon UV light irradiation, the spiropyran transformed into zwitterionic merocyanine, which had shown MgSO4 removal of >95% with water permeation rates of 6.5 L/(m2·h·bar). Alternatively, visible light was used to convert merocyanine to spiropyran, which achieved >95% of MgSO4 retention with a water flux of around 5.25 L/(m2·h·bar). The modified NF membranes showed higher chlorine resistance as well as a higher normalized water flux as compared to the reference membrane, without a loss of ion retention. All the NF membranes were characterized by scanning electron microscopy and X-ray photoelectron spectroscopy. This study demonstrates a simple and inexpensive method for the immobilization of molecules onto polymeric membranes, which may be applied in water softening.
Highlights
Hard water refers to a high mineral content, especially when loaded with large amounts of magnesium and calcium ions
It might be due to the electron beam (EB)-mediated radical formation, which causes internal polymer crosslinking, as we proved in our earlier study [12]
·bar),salt but lower than the explained with a chlorine attack followed by hydrolysis of the amide bonds (–CO–NH–) of the PA
Summary
Hard water refers to a high mineral content, especially when loaded with large amounts of magnesium and calcium ions. Hard drinking water damages industrial settings, e.g., breaking boiler pipelines and other instruments that handle hard water. It thwarts the foam formation when water minerals are agitated with soap, which decreases cleaning efficiency. Hard water causes the deposition of insoluble metals or salts in containers, sinks, and bathtubs [2]. Removing these excessive mineral contents from water through a process called water softening is a must to avoid these problems
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