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Abstract
Hydroxide exchange membrane (HEM) electrolyzers can produce green H2 with only earth-abundant catalysts and electrolyte-free (nominally pure) water feed, significantly decreasing system cost and complexity. However, HEM technology suffers from short lifetimes, attributed in part to poor stability of anion-exchange polymers used in the membrane and catalyst layers. Here, we use electrochemical analysis and ex-situ characterization techniques to study anion exchange polymer degradation in electrolyzers. Using multiple ionomers, catalyst layer additives, and electrolyte feed, we show anode ionomer oxidation is the dominant degradation mechanism for all HEM-based electrolyzers tested. We show improved device stability using oxidation-resistant catalyst layer binders and offer new design strategies for advanced ionomer and catalyst layer development.
Supplementary materials
Title
Supplemental Information: Oxidative instability of ionomers in hydroxide-exchange-membrane electrolyzers
Description
PNB ionomer conductivity, ion exchange capacity and water uptake measurements; detailed description of electrolyzer assembly with reference electrode with figures; comparison of total cell impedance with and without reference electrode; comparison of ionomer mass content in anode PTE; additional XPS results; XPS and cross section image of control test of electrolyzer operation with water flow and no applied current; cross section image of Nafion PTEs
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Title
Supplemental Video 1
Description
Vide of SEM cross section of IrOx/PTFE anode PTE
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