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Zinc-iodine redox reaction enables direct brine valorization with efficient high-water-recovery desalination

Authors
Lim, JunbeomKim, MinchanKwak, Rhokyun
Issue Date
May-2024
Citation
Nature Water, v.2, no.5, pp 475 - 484
Pages
10
Indexed
ESCI
Journal Title
Nature Water
Volume
2
Number
5
Start Page
475
End Page
484
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/206148
DOI
10.1038/s44221-024-00238-1
ISSN
2731-6084
2731-6084
Abstract
Current desalination methods, with high energy/cost demands and large volumes of brine discharged to the environment, are not sustainable. Here we propose a sustainable electrodialysis that enables direct brine valorization with efficient high-water-recovery desalination via zinc-iodine redox reactions. In a single process comprising electrodialysis and two chemical reactions in brine streams, we achieve seawater desalination with a remarkable water recovery of 90.09% without compromising other metrics (salt-removal ratio <98.29%, electric energy consumption of <2.18 kWh m(-3)). Such performance advantage is attributable to (1) high solubility of zinc-iodine-based 'water-in-salt' electrolytes mitigating the osmotic pressure, achieving high water recovery even for high concentration feed water (98-82% for 0.1-1.5 M) with minimal energy burdens, (2) zinc-iodine redox potential lowering electric energy demand and (3) electroconvection in the overlimiting regime enhancing desalination speed. Also, profitable ZnCl2/NaI are electrosynthesized in brine, enabling direct valorization of desalination brines.
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