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Engineering Bipolar Interfaces for Water Electrolysis Using Earth-Abundant Anodes

Andrew W. Tricker, Jason Keonhag Lee, Finn Babbe, Jason R. Shin, Adam Z. Weber, Xiong Peng

2023ACS Energy Letters16 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Developing efficient and low-cost water electrolyzers for clean hydrogen production to reduce the carbon footprint of traditional hard-to-decarbonize sectors is a grand challenge toward tackling climate change. Bipolar-based water electrolysis combines the benefits of kinetically more favorable half-reactions and relatively inexpensive cell components compared to incumbent technologies, yet it has been shown to have limited performance. Here, we develop and test a bipolar-interface water electrolyzer (BPIWE) by combining an alkaline anode porous transport electrode with an acidic catalyst-coated membrane. The role of TiO 2 as a water dissociation (WD) catalyst is investigated at three representative loadings, which indicates the importance of balancing ionic conductivity and WD activity derived from the electric field for optimal TiO 2 loading. The optimized BPIWE exhibits negligible performance degradation up to 500 h at 400 mA cm –2 fed with pure water using earth-abundant anode materials. Our experimental findings provide insights into designing bipolar-based electrochemical devices.

Topics & Concepts

AnodeElectrolysisElectrolysis of waterMaterials scienceHydrogen productionElectrochemistryWater splittingPolymer electrolyte membrane electrolysisChemical engineeringHydrogenCatalysisEnvironmental scienceElectrodeChemistryElectrolytePhysical chemistryBiochemistryOrganic chemistryPhotocatalysisEngineeringElectrocatalysts for Energy ConversionAdvanced battery technologies researchHybrid Renewable Energy Systems
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