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Abstract
This paper presents the development of a thin-film composite nanoporous membrane for highly efficient electrodialysis. Co-deposition of dopamine and polyethyleneimine tailors membrane surface properties, enhancing charge shielding and fast anion transfer. The membrane demonstrates superior electrodialytic fractionation of organics and NaCl with negligible fouling, outperforming existing anion exchange membranes. This research offers a facile design for high-performance anion-conducting membranes and reveals new mass transport mechanisms in electrodialytic separation, advancing sustainable wastewater management.
Publisher
Nature Water
Published On
Aug 03, 2023
Authors
Jiuyang Lin, Wenyuan Ye, Shuangling Xie, Jiale Du, Riri Liu, Dong Zou, Xiangyu Chen, Zijian Yu, Shengqiong Fang, Elisa Yun Mei Ang, William Toh, Dan Dan Han, Teng Yong Ng, Dong Han Seo, Shuaifei Zhao, Bart Van der Bruggen, Ming Xie, Young Moo Lee
Tags
thin-film composite
nanoporous membrane
electrodialysis
sustainable wastewater management
anion transfer
mass transport mechanisms
fouling

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