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Effective Enhancement of Energy Density of Zinc-Polyiodide Flow Batteries by Organic/Penta-iodide Complexation.

Jae-Ik LeeAbdullah Bin FaheemWon Joon JangKyung Mi KimJin Seong ChaNoh-Uk SeoHansung KimKyung-Koo LeeJung Hoon Yang
Published in: ACS applied materials & interfaces (2023)
Based on the ambipolar characteristics and high solubility of ZnI 2 , zinc-polyiodide flow batteries (ZIFB) have attracted attention as high-energy density flow batteries. However, due to the various oxidation products of iodide (I - ) and the formation of iodine (I 2 ) solid precipitates at the positive electrode, the limiting state-of-charge (SoC) of ZIFB has not been clearly defined. Herein, a clear definition of SoC in ZIFBs is given based on the thermodynamic relationship among I - (aq) , I 3 - (aq) , I 5 - (aq) , and I 2(aq) in the electrolyte. Conventional ZIFBs are limited by their maximum attainable SoC of 87%, at which the fully charged catholyte includes I - , I 3 - , and I 5 - ions at molar ratios of 49.6, 32.2, and 18.1%, respectively. Furthermore, two effective strategies to extend the maximum SoC are suggested: (1) increasing the formation constant ( K eq ) of I 3 - can raise the availability of I - for electrooxidation by suppressing I 2 precipitation, and (2) promoting the production of higher-order polyiodides such as I 5 - can increase the oxidation state of the charged electrolyte. The addition of 5 vol % triethylene glycol (tri-EG) to the electrolyte increased K eq from 710 to 1123 L mol -1 ; this increase was confirmed spectrophotometrically. Tri-EG stabilized I 5 - ions in the form of the I 5 - /tri-EG complex, thereby converting the main oxidation product from I 3 - to I 5 - . The preferred electrochemical production of I 5 - in the tri-EG electrolyte was observed by electrochemical and computational analyses. As a result, the maximum attainable SoC was enhanced remarkably to 116%, yielding molar ratios of I - , I 3 - , and I 5 - ions of 9.1, 11.2, and 79.7%, respectively. This SoC extension effect was confirmed in the ZIFB flow cell with stable charge-discharge cycling at the SoC 120% limit, demonstrating the highest energy density, 249.9 Wh L -1 , among all reported ZIFBs.
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