Three-Electrode Study of Electrochemical Ionomer Degradation Relevant to Anion-Exchange-Membrane Water Electrolyzers

Among existing water electrolysis (WE) technologies, anion-exchange-membrane water electrolyzers (AEMWEs) show promise for low-cost operation enabled by the basic solid-polymer electrolyte used to conduct hydroxide ions. The basic environment within the electrolyzer, in principle, allows the use of...

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Veröffentlicht in:	ACS applied materials & interfaces 2022-04, Vol.14 (16)
Hauptverfasser:	Krivina, Raina A., Lindquist, Grace A., Yang, Min Chieh, Cook, Amanda K., Hendon, Christopher H., Motz, Andrew R., Capuano, Christopher, Ayers, Katherine E., Hutchison, James E., Boettcher, Shannon W.
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Schlagworte:	anion-exchange-membrane water electrolysis degradation electrochemical degradation electrodes electrolytes INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY ionomer ionomers supporting electrolyte thin films XPS
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creator	Krivina, Raina A. Lindquist, Grace A. Yang, Min Chieh Cook, Amanda K. Hendon, Christopher H. Motz, Andrew R. Capuano, Christopher Ayers, Katherine E. Hutchison, James E. Boettcher, Shannon W.
description	Among existing water electrolysis (WE) technologies, anion-exchange-membrane water electrolyzers (AEMWEs) show promise for low-cost operation enabled by the basic solid-polymer electrolyte used to conduct hydroxide ions. The basic environment within the electrolyzer, in principle, allows the use of non-platinum-group metal catalysts and less-expensive cell components compared to acidic-membrane systems. Nevertheless, AEMWEs are still underdeveloped, and the degradation and failure modes are not well understood. To improve performance and durability, supporting electrolytes such as KOH and K2CO3 are often added to the water feed. The effect of the anion interactions with the ionomer membrane (particularly other than OH–), however, remains poorly understood. We studied three commercial anion-exchange ionomers (Aemion, Sustainion, and PiperION) during oxygen evolution (OER) at oxidizing potentials in several supporting electrolytes and characterized their chemical stability with surface-sensitive techniques. We analyzed factors including the ionomer conductivity, redox potential, and pH tolerance to determine what governs ionomer stability during OER. Specifically, we discovered that the oxidation of Aemion at the electrode surface is favored in the presence of CO32–/HCO3– anions perhaps due to the poor conductivity of that ionomer in the carbonate/bicarbonate form. Sustainion tends to lose its charge-carrying groups as a result of electrochemical degradation favored in basic electrolytes. PiperION seems to be similarly negatively affected by a pH drop and low carbonate/bicarbonate conductivity under the applied oxidizing potential. Furthermore, the insight into the interactions of the supporting electrolyte anions with the ionomer/membrane helps shed light on some of the degradation pathways possible inside of the AEMWE and enables the informed design of materials for water electrolysis.
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subjects	anion-exchange-membrane water electrolysis degradation electrochemical degradation electrodes electrolytes INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY ionomer ionomers supporting electrolyte thin films XPS
title	Three-Electrode Study of Electrochemical Ionomer Degradation Relevant to Anion-Exchange-Membrane Water Electrolyzers
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