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Electrolyte-Induced Restructuring of Acid-Stable Oxygen Evolution Catalysts

Samuel S. Veroneau, Agnes E. Thorarinsdottir, Daniel M. Loh, Alaina C. Hartnett, Thomas P. Keane, Daniel G. Nocera

2023Chemistry of Materials11 citationsDOI

Abstract

Crystalline metal oxide catalysts operating under oxygen evolution reaction (OER) conditions invariably restructure, resulting in active sites with hydroxo/oxo species in an amorphous environment. An increase in the population of terminal hydroxo/oxo species (i.e., edge sites) facilitates proton-coupled electron-transfer (PCET) kinetics for oxygen generation and thus improves catalyst competency. While amorphous films benefit from a greater density of active sites, they suffer from diminished charge transport as compared to that of extended crystalline lattices. Managing this amorphous–crystalline dichotomy is essential when designing OER catalysts, which we highlight with the examination of electrodeposited PbO x materials, which historically are very poor OER catalysts. Along these lines, the presence of phosphate during PbO x electrodeposition truncates the growth of an extended lattice owing to its strong bonding to oxide surfaces to afford an amorphous catalyst film (A-PbO x ) with significant charge-transfer resistance (138 ± 42 Ω) and poor OER kinetics (420 ± 105 mV dec –1 Tafel slope). Conversely, electrodeposition of Pb 2+ in the presence of less coordinating electrolytes such as nitrate affords crystalline β-PbO 2 with improved charge-transfer resistance (42.6 ± 1.1 Ω), though still poor OER kinetics (134 ± 36 mV dec –1 Tafel slope). By operating amorphous A-PbO x in less coordinating electrolytes, however, a new partially crystalline material can be generated (μc-PbO x ) with further reduced charge-transfer resistance (33.0 ± 1.4 Ω) and improved OER kinetics (70 ± 15 mV dec –1 Tafel slope). The enhanced OER activity of μc-PbO x is the result of coupling the high edge-site population of an amorphous PbO x phase with crystalline-like charge transport properties. The ability to use an electrolyte to induce OER activity in an inactive amorphous form of PbO x highlights the benefits of optimizing the amorphous–crystalline phase compositions in the design of active OER catalysts.

Topics & Concepts

Tafel equationOxygen evolutionElectrolyteAmorphous solidMaterials sciencePopulationOxideCatalysisChemical engineeringChemistryInorganic chemistryCrystallographyPhysical chemistryElectrodeMetallurgyElectrochemistryOrganic chemistryEngineeringDemographySociologyElectrocatalysts for Energy ConversionAdvanced battery technologies researchFuel Cells and Related Materials
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