Direct oxygen isotope effect identifies the rate-determining step of electrocatalytic OER at an oxidic surface

Direct oxygen isotope effect identifies the rate-determining step of electrocatalytic OER at an oxidic surface

Understanding the mechanism of water oxidation to dioxygen represents the bottleneck towards the design of efficient energy storage schemes based on water splitting. The investigation of kinetic isotope effects has long been established for mechanistic studies of various such reactions. However, so...

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Published in:Nature communications Vol. 9; no. 1; pp. 4565 - 8
Main Authors: Haschke, Sandra, Mader, Michael, Schlicht, Stefanie, Roberts, André M., Angeles-Boza, Alfredo M., Barth, Johannes A. C., Bachmann, Julien
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-11-2018
Nature Publishing Group
Nature Portfolio
Subjects:
140/58
639/301/930/12
639/638/11/296
639/638/161/886
639/638/675
639/638/77/885
Electrode materials
Electrodes
Energy storage
Humanities and Social Sciences
Iron oxides
Isotope effect
Isotopes
multidisciplinary
Oxidation
Oxygen
Oxygen evolution reactions
Oxygen isotopes
Science
Science (multidisciplinary)
Water splitting
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Summary:Understanding the mechanism of water oxidation to dioxygen represents the bottleneck towards the design of efficient energy storage schemes based on water splitting. The investigation of kinetic isotope effects has long been established for mechanistic studies of various such reactions. However, so far natural isotope abundance determination of O 2 produced at solid electrode surfaces has not been applied. Here, we demonstrate that such measurements are possible. Moreover, they are experimentally simple and sufficiently accurate to observe significant effects. Our measured kinetic isotope effects depend strongly on the electrode material and on the applied electrode potential. They suggest that in the case of iron oxide as the electrode material, the oxygen evolution reaction occurs via a rate-determining O−O bond formation via nucleophilic water attack on a ferryl unit. Understanding reaction mechanisms is crucial for catalyst design. Here, natural-abundance isotope quantifications of O 2 yield mechanistically significant reaction kinetic isotope effects for water oxidation over metal oxide electrodes, the bottleneck step of water electrolysis.
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ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-018-07031-1