Abstract
In this study, we focused on the effective disposal of radioactive wastewater through the development of nanofiltration membranes using biomass materials. We developed functionalized nanofilms using a bio-derived polymer for the decontamination of nuclear wastewater. The synthesis involved a straightforward interfacial polymerization (IP) process, followed by post-functionalization with polyethyleneimine (PEI). We investigated the impact of curdlan self-assembly on membrane separation performance, both pre- and post-IP reaction. Simultaneous self-assembly of curdlan and PEI grafting led to membranes exhibiting superior separation performance. By manipulating PEI molecular weights, we optimized the membranes' physicochemical properties, leading to superior separation efficiency. As a result, exceptional rejections of Co2+, Sr2+, and Cs+ ions were achieved, with rejection rates reaching 95.5 %, 93.7 %, and 92.54 %, respectively. Furthermore, long-term stability experiments validated the membrane's potential for purifying nuclear wastewater. These findings hold promise for the application of biomaterial-based membranes in the treatment of radioactive nuclear wastewater.
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