Tailoring atomic chemistry to refine reaction pathway for the most enhancement by magnetization in water oxidation

Tianze Wu; Jingjie Ge; Qian Wu; Xiao Ren; Fanxu Meng; Jiarui Wang; Shibo Xi; Xin Wang; Kamal Elouarzaki; Adrian Fisher; Zhichuan J. Xu

doi:10.1073/pnas.2318652121

Tailoring atomic chemistry to refine reaction pathway for the most enhancement by magnetization in water oxidation

Tianze Wu, Jingjie Ge, Qian Wu, Xiao Ren, Fanxu Meng, Jiarui Wang, Shibo Xi, Xin Wang, Kamal Elouarzaki, Adrian Fisher, Zhichuan J. Xu^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

Water oxidation on magnetic catalysts has generated significant interest due to the spin-polarization effect. Recent studies have revealed that the disappearance of magnetic domain wall upon magnetization is responsible for the observed oxygen evolution reaction (OER) enhancement. However, an atomic picture of the reaction pathway remains unclear, i.e., which reaction pathway benefits most from spin-polarization, the adsorbent evolution mechanism, the intermolecular mechanism (I2M), the lattice oxygen-mediated one, or more? Here, using three model catalysts with distinguished atomic chemistries of active sites, we are able to reveal the atomic-level mechanism. We found that spin-polarized OER mainly occurs at interconnected active sites, which favors direct coupling of neighboring ligand oxygens (I2M). Furthermore, our study reveals the crucial role of lattice oxygen participation in spin-polarized OER, significantly facilitating the coupling kinetics of neighboring oxygen radicals at active sites.

Original language	English
Article number	e2318652121
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	121
Issue number	19
DOIs	https://doi.org/10.1073/pnas.2318652121
Publication status	Published - May 7 2024
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2024 National Academy of Sciences. All rights reserved.

ASJC Scopus Subject Areas

General

Keywords

atomic chemistry
magnetic domain wall
magnetic field
oxygen evolution reaction

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10.1073/pnas.2318652121

Cite this

Wu, T., Ge, J., Wu, Q., Ren, X., Meng, F., Wang, J., Xi, S., Wang, X., Elouarzaki, K., Fisher, A., & Xu, Z. J. (2024). Tailoring atomic chemistry to refine reaction pathway for the most enhancement by magnetization in water oxidation. Proceedings of the National Academy of Sciences of the United States of America, 121(19), Article e2318652121. https://doi.org/10.1073/pnas.2318652121

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abstract = "Water oxidation on magnetic catalysts has generated significant interest due to the spin-polarization effect. Recent studies have revealed that the disappearance of magnetic domain wall upon magnetization is responsible for the observed oxygen evolution reaction (OER) enhancement. However, an atomic picture of the reaction pathway remains unclear, i.e., which reaction pathway benefits most from spin-polarization, the adsorbent evolution mechanism, the intermolecular mechanism (I2M), the lattice oxygen-mediated one, or more? Here, using three model catalysts with distinguished atomic chemistries of active sites, we are able to reveal the atomic-level mechanism. We found that spin-polarized OER mainly occurs at interconnected active sites, which favors direct coupling of neighboring ligand oxygens (I2M). Furthermore, our study reveals the crucial role of lattice oxygen participation in spin-polarized OER, significantly facilitating the coupling kinetics of neighboring oxygen radicals at active sites.",

keywords = "atomic chemistry, magnetic domain wall, magnetic field, oxygen evolution reaction",

author = "Tianze Wu and Jingjie Ge and Qian Wu and Xiao Ren and Fanxu Meng and Jiarui Wang and Shibo Xi and Xin Wang and Kamal Elouarzaki and Adrian Fisher and Xu, \{Zhichuan J.\}",

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Wu, T, Ge, J, Wu, Q, Ren, X, Meng, F, Wang, J, Xi, S, Wang, X, Elouarzaki, K, Fisher, A & Xu, ZJ 2024, 'Tailoring atomic chemistry to refine reaction pathway for the most enhancement by magnetization in water oxidation', Proceedings of the National Academy of Sciences of the United States of America, vol. 121, no. 19, e2318652121. https://doi.org/10.1073/pnas.2318652121

TY - JOUR

T1 - Tailoring atomic chemistry to refine reaction pathway for the most enhancement by magnetization in water oxidation

AU - Wu, Tianze

AU - Ge, Jingjie

AU - Wu, Qian

AU - Ren, Xiao

AU - Meng, Fanxu

AU - Wang, Jiarui

AU - Xi, Shibo

AU - Wang, Xin

AU - Elouarzaki, Kamal

AU - Fisher, Adrian

AU - Xu, Zhichuan J.

PY - 2024/5/7

Y1 - 2024/5/7

N2 - Water oxidation on magnetic catalysts has generated significant interest due to the spin-polarization effect. Recent studies have revealed that the disappearance of magnetic domain wall upon magnetization is responsible for the observed oxygen evolution reaction (OER) enhancement. However, an atomic picture of the reaction pathway remains unclear, i.e., which reaction pathway benefits most from spin-polarization, the adsorbent evolution mechanism, the intermolecular mechanism (I2M), the lattice oxygen-mediated one, or more? Here, using three model catalysts with distinguished atomic chemistries of active sites, we are able to reveal the atomic-level mechanism. We found that spin-polarized OER mainly occurs at interconnected active sites, which favors direct coupling of neighboring ligand oxygens (I2M). Furthermore, our study reveals the crucial role of lattice oxygen participation in spin-polarized OER, significantly facilitating the coupling kinetics of neighboring oxygen radicals at active sites.

AB - Water oxidation on magnetic catalysts has generated significant interest due to the spin-polarization effect. Recent studies have revealed that the disappearance of magnetic domain wall upon magnetization is responsible for the observed oxygen evolution reaction (OER) enhancement. However, an atomic picture of the reaction pathway remains unclear, i.e., which reaction pathway benefits most from spin-polarization, the adsorbent evolution mechanism, the intermolecular mechanism (I2M), the lattice oxygen-mediated one, or more? Here, using three model catalysts with distinguished atomic chemistries of active sites, we are able to reveal the atomic-level mechanism. We found that spin-polarized OER mainly occurs at interconnected active sites, which favors direct coupling of neighboring ligand oxygens (I2M). Furthermore, our study reveals the crucial role of lattice oxygen participation in spin-polarized OER, significantly facilitating the coupling kinetics of neighboring oxygen radicals at active sites.

KW - atomic chemistry

KW - magnetic domain wall

KW - magnetic field

KW - oxygen evolution reaction

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Tailoring atomic chemistry to refine reaction pathway for the most enhancement by magnetization in water oxidation

Abstract

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Keywords

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