Xie, RongxuanYue, DiqingPeng, ZhenmengWie, Xiaoliang2023-10-172023-10-172023-01-10Xie, R., Yue, D., Peng, Z., & Wei, X. (2023). Achieving Energy-Saving, Continuous Redox Flow Desalination with Iron Chelate Redoxmers. Energy Material Advances, 4, 0009. https://doi.org/10.34133/energymatadv.0009https://hdl.handle.net/1805/36412Desalination of saline water is becoming an increasingly critical strategy to overcome the global challenge of drinkable water shortage, but current desalination methods are often plagued with major drawbacks of high energy consumption, high capital cost, or low desalination capacity. To address these drawbacks, we have developed a unique continuous-mode redox flow desalination approach capitalizing on the characteristics of redox flow batteries. The operation is based on shuttled redox cycles of very dilute Fe2+/Fe3+ chelate redoxmers with ultralow cell overpotentials. The air instability of Fe2+ chelate is naturally compensated for by its in situ electrochemical generation, making the desalination system capable of operations with electrolytes at any specified state of charge. Under unoptimized conditions, fast desalination rates up to 404.4 mmol·m−2·h−1 and specific energy consumptions as low as 7.9 Wh·molNaCl−1 have been successfully achieved. Interestingly, this desalination method has offered an opportunity of sustainable, distributed drinkable water supplies through direct integration with renewable energy sources such as solar power. Therefore, our redox flow desalination design has demonstrated competitive desalination performance, promising to provide an energy-saving, high-capacity, robust, cost-effective desalination solution.en-USAttribution 4.0 Internationaldesalinationrenewable energy sourcescontinuous-mode redox flowshuttled redox cyclesArticle