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Electrochemical Proton-Transfer Kinetics Using Model Tungsten Oxide Thin Films

Dwaipayan Roychowdhury, Nick D’Antona, Yang Zhao, Yogesh Surendranath, Veronica Augustyn, Paul A. Kempler, Shannon W. Boettcher

2025ACS electrochemistry.10 citationsDOIOpen Access PDF

Abstract

Understanding interfacial ion-transfer kinetics is central to advancing electrochemical processes associated with energy storage and catalysis. Here we investigate electrochemical proton-insertion kinetics at the electrode/electrolyte interface using dense crystalline WO 3 films between ∼5 and 40 nm in thickness as a model system. Monoclinic WO 3 is prepared on conductive F:SnO 2 substrates via W-metal sputtering and calcination. Thin films offer a reasonably well-defined interface where confounding effects of ion and electron transport present in typical (nano)porous electrodes are avoided. We develop a current-response model to decouple overlapping contributions of double-layer charging and electrochemical proton-insertion kinetics, enabling the quantification of kinetic parameters. Voltammetry, potential-step, and impedance spectroscopy experiments illustrate the influence of film crystallinity, thickness, and state of charge (SoC) on interfacial ion-transfer. Temperature-dependent measurements yield an activation energy of 29 kJ/mol for proton insertion/de-insertion, consistent with a molecular mechanism involving proton-transfer from hydronium at the WO 3 /electrolyte interface. This work establishes initial benchmark values for proton-insertion kinetics into solids and provides an experimental platform to study the interplay between interfacial structure and ion-transfer.

Topics & Concepts

Tungsten oxideKineticsElectrochemistryProtonTungstenMaterials scienceOxideChemical engineeringElectrodeChemistryMetallurgyPhysical chemistryPhysicsEngineeringNuclear physicsQuantum mechanicsTransition Metal Oxide NanomaterialsSemiconductor materials and devicesElectronic and Structural Properties of Oxides
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