Surface oxidation/spin state determines oxygen evolution reaction activity of cobalt-based catalysts in acidic environment.
Jinzhen HuangCamelia Nicoleta BorcaThomas HuthwelkerNur Sena YüzbasiDominika BasterMario El KazziChristof W SchneiderThomas Justus SchmidtEmiliana FabbriPublished in: Nature communications (2024)
Co-based catalysts are promising candidates to replace Ir/Ru-based oxides for oxygen evolution reaction (OER) catalysis in an acidic environment. However, both the reaction mechanism and the active species under acidic conditions remain unclear. In this study, by combining surface-sensitive soft X-ray absorption spectroscopy characterization with electrochemical analysis, we discover that the acidic OER activity of Co-based catalysts are determined by their surface oxidation/spin state. Surfaces composed of only high-spin Co II are found to be not active due to their unfavorable water dissociation to form Co III -OH species. By contrast, the presence of low-spin Co III is essential, as it promotes surface reconstruction of Co oxides and, hence, OER catalysis. The correlation between OER activity and Co oxidation/spin state signifies a breakthrough in defining the structure-activity relationship of Co-based catalysts for acidic OER, though, interestingly, such a relationship does not hold in alkaline and neutral environments. These findings not only help to design efficient acidic OER catalysts, but also deepen the understanding of the reaction mechanism.
Keyphrases
- transition metal
- ionic liquid
- room temperature
- electron transfer
- highly efficient
- single molecule
- density functional theory
- metal organic framework
- hydrogen peroxide
- high resolution
- structure activity relationship
- magnetic resonance
- visible light
- nitric oxide
- molecular dynamics
- magnetic resonance imaging
- mass spectrometry
- computed tomography
- contrast enhanced
- solid state