Correlative operando microscopy of oxygen evolution electrocatalysts
Autor: | William E. Gent, William C. Chueh, David A. Shapiro, Young-Sang Yu, J. Tyler Mefford, Haitao D. Deng, Minkyung Kang, Andrew R. Akbashev, Cameron Luke Bentley, Patrick R. Unwin, Norman Salmon, Daan Hein Alsem |
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Rok vydání: | 2021 |
Předmět: |
Tafel equation
Multidisciplinary Materials science Open-circuit voltage Oxygen evolution 02 engineering and technology 010402 general chemistry 021001 nanoscience & nanotechnology Electrocatalyst Electrochemistry 01 natural sciences Redox 0104 chemical sciences Catalysis Chemical engineering Oxidation state 0210 nano-technology |
Zdroj: | Nature. 593:67-73 |
ISSN: | 1476-4687 0028-0836 |
Popis: | Transition metal (oxy)hydroxides are promising electrocatalysts for the oxygen evolution reaction1–3. The properties of these materials evolve dynamically and heterogeneously4 with applied voltage through ion insertion redox reactions, converting materials that are inactive under open circuit conditions into active electrocatalysts during operation5. The catalytic state is thus inherently far from equilibrium, which complicates its direct observation. Here, using a suite of correlative operando scanning probe and X-ray microscopy techniques, we establish a link between the oxygen evolution activity and the local operational chemical, physical and electronic nanoscale structure of single-crystalline β-Co(OH)2 platelet particles. At pre-catalytic voltages, the particles swell to form an α-CoO2H1.5·0.5H2O-like structure—produced through hydroxide intercalation—in which the oxidation state of cobalt is +2.5. Upon increasing the voltage to drive oxygen evolution, interlayer water and protons de-intercalate to form contracted β-CoOOH particles that contain Co3+ species. Although these transformations manifest heterogeneously through the bulk of the particles, the electrochemical current is primarily restricted to their edge facets. The observed Tafel behaviour is correlated with the local concentration of Co3+ at these reactive edge sites, demonstrating the link between bulk ion-insertion and surface catalytic activity. Mapping the operational chemical, physical and electronic structure of an oxygen evolution electrocatalyst at the nanoscale links the properties of the material with the observed oxygen evolution activity. |
Databáze: | OpenAIRE |
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