X-ray spectroscopy characterization of cobalt stabilization within a monolayer carbon nitride in the oxygen evolution reaction

Anders K Vestergaard; Jens Jakob Gammelgaard; Zhaozong Sun; Siqi Zhao; Zheshen Li; Nina Lock; Kim Daasbjerg; Jeppe V Lauritsen

doi:10.1039/d4cp04148h

X-ray spectroscopy characterization of cobalt stabilization within a monolayer carbon nitride in the oxygen evolution reaction

Anders K Vestergaard, Jens Jakob Gammelgaard, Zhaozong Sun, Siqi Zhao, Zheshen Li, Nina Lock, Kim Daasbjerg, Jeppe V Lauritsen^*

^*Corresponding author for this work

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

Abstract

Carbon nitride-based catalysts containing earth-abundant metals such as Co have gained attention for the oxygen evolution and reduction reactions (OER and ORR). The catalytic activity of such materials is known to be sensitive to metal dispersion and coordination, which again may depend on reaction conditions, but exact information on the active state and the possible coordination state changes of Co in these materials induced by electrocatalytic conditions are in general lacking. Here, we study the redistribution of Co during the OER in a composite planar model system consisting of a well-defined single-atom Co-doped carbon nitride monolayer and Co nanoparticles on Au(111). Through a combination of electrocatalytic activity measurements and analysis of the catalyst surface pre- and post-electrochemical operation using X-ray photoelectron spectroscopy and near edge X-ray absorption fine structure spectroscopy, we investigate the induced changes in Co species and the carbon nitride network. Our findings indicate significant mobility during the OER of Co atoms originating from the Co nanoparticles, with the presence of the carbon nitride stabilizing Co in a dispersed form. The dispersion of Co leads to a steady increase in OER activity over time, which is only observed when both Co nanoparticles and Co-doped carbon nitride co-exist. We attribute this phenomenon to the carbon nitride's role in dispersing and stabilizing highly mobile cobalt species on the surface, thereby enhancing electrochemical stability.

Original language	English
Journal	Physical chemistry chemical physics : PCCP
Volume	27
Issue	10
Pages (from-to)	5326-5337
Number of pages	12
ISSN	1463-9076
DOIs	https://doi.org/10.1039/d4cp04148h
Publication status	E-pub / Early view - 24 Feb 2025

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Vestergaard, A. K., Gammelgaard, J. J., Sun, Z., Zhao, S., Li, Z., Lock, N., Daasbjerg, K., & Lauritsen, J. V. (2025). X-ray spectroscopy characterization of cobalt stabilization within a monolayer carbon nitride in the oxygen evolution reaction. Physical chemistry chemical physics : PCCP, 27(10), 5326-5337. Advance online publication. https://doi.org/10.1039/d4cp04148h

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title = "X-ray spectroscopy characterization of cobalt stabilization within a monolayer carbon nitride in the oxygen evolution reaction",

abstract = "Carbon nitride-based catalysts containing earth-abundant metals such as Co have gained attention for the oxygen evolution and reduction reactions (OER and ORR). The catalytic activity of such materials is known to be sensitive to metal dispersion and coordination, which again may depend on reaction conditions, but exact information on the active state and the possible coordination state changes of Co in these materials induced by electrocatalytic conditions are in general lacking. Here, we study the redistribution of Co during the OER in a composite planar model system consisting of a well-defined single-atom Co-doped carbon nitride monolayer and Co nanoparticles on Au(111). Through a combination of electrocatalytic activity measurements and analysis of the catalyst surface pre- and post-electrochemical operation using X-ray photoelectron spectroscopy and near edge X-ray absorption fine structure spectroscopy, we investigate the induced changes in Co species and the carbon nitride network. Our findings indicate significant mobility during the OER of Co atoms originating from the Co nanoparticles, with the presence of the carbon nitride stabilizing Co in a dispersed form. The dispersion of Co leads to a steady increase in OER activity over time, which is only observed when both Co nanoparticles and Co-doped carbon nitride co-exist. We attribute this phenomenon to the carbon nitride's role in dispersing and stabilizing highly mobile cobalt species on the surface, thereby enhancing electrochemical stability.",

author = "Vestergaard, {Anders K} and Gammelgaard, {Jens Jakob} and Zhaozong Sun and Siqi Zhao and Zheshen Li and Nina Lock and Kim Daasbjerg and Lauritsen, {Jeppe V}",

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language = "English",

volume = "27",

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X-ray spectroscopy characterization of cobalt stabilization within a monolayer carbon nitride in the oxygen evolution reaction. / Vestergaard, Anders K; Gammelgaard, Jens Jakob; Sun, Zhaozong et al.
In: Physical chemistry chemical physics : PCCP, Vol. 27, No. 10, 24.02.2025, p. 5326-5337.

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

TY - JOUR

T1 - X-ray spectroscopy characterization of cobalt stabilization within a monolayer carbon nitride in the oxygen evolution reaction

AU - Vestergaard, Anders K

AU - Gammelgaard, Jens Jakob

AU - Sun, Zhaozong

AU - Zhao, Siqi

AU - Li, Zheshen

AU - Lock, Nina

AU - Daasbjerg, Kim

AU - Lauritsen, Jeppe V

PY - 2025/2/24

Y1 - 2025/2/24

N2 - Carbon nitride-based catalysts containing earth-abundant metals such as Co have gained attention for the oxygen evolution and reduction reactions (OER and ORR). The catalytic activity of such materials is known to be sensitive to metal dispersion and coordination, which again may depend on reaction conditions, but exact information on the active state and the possible coordination state changes of Co in these materials induced by electrocatalytic conditions are in general lacking. Here, we study the redistribution of Co during the OER in a composite planar model system consisting of a well-defined single-atom Co-doped carbon nitride monolayer and Co nanoparticles on Au(111). Through a combination of electrocatalytic activity measurements and analysis of the catalyst surface pre- and post-electrochemical operation using X-ray photoelectron spectroscopy and near edge X-ray absorption fine structure spectroscopy, we investigate the induced changes in Co species and the carbon nitride network. Our findings indicate significant mobility during the OER of Co atoms originating from the Co nanoparticles, with the presence of the carbon nitride stabilizing Co in a dispersed form. The dispersion of Co leads to a steady increase in OER activity over time, which is only observed when both Co nanoparticles and Co-doped carbon nitride co-exist. We attribute this phenomenon to the carbon nitride's role in dispersing and stabilizing highly mobile cobalt species on the surface, thereby enhancing electrochemical stability.

AB - Carbon nitride-based catalysts containing earth-abundant metals such as Co have gained attention for the oxygen evolution and reduction reactions (OER and ORR). The catalytic activity of such materials is known to be sensitive to metal dispersion and coordination, which again may depend on reaction conditions, but exact information on the active state and the possible coordination state changes of Co in these materials induced by electrocatalytic conditions are in general lacking. Here, we study the redistribution of Co during the OER in a composite planar model system consisting of a well-defined single-atom Co-doped carbon nitride monolayer and Co nanoparticles on Au(111). Through a combination of electrocatalytic activity measurements and analysis of the catalyst surface pre- and post-electrochemical operation using X-ray photoelectron spectroscopy and near edge X-ray absorption fine structure spectroscopy, we investigate the induced changes in Co species and the carbon nitride network. Our findings indicate significant mobility during the OER of Co atoms originating from the Co nanoparticles, with the presence of the carbon nitride stabilizing Co in a dispersed form. The dispersion of Co leads to a steady increase in OER activity over time, which is only observed when both Co nanoparticles and Co-doped carbon nitride co-exist. We attribute this phenomenon to the carbon nitride's role in dispersing and stabilizing highly mobile cobalt species on the surface, thereby enhancing electrochemical stability.

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JO - Physical chemistry chemical physics : PCCP

JF - Physical chemistry chemical physics : PCCP

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X-ray spectroscopy characterization of cobalt stabilization within a monolayer carbon nitride in the oxygen evolution reaction

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