Unveiling the Activity Origin of Electrochemical Oxygen Evolution on Heteroatom-Decorated Carbon Matrix

Yang Li; Cailing Chen; Guoxiang Zhao; Huawei Huang; Yuanfu Ren; Shouwei Zuo; Zhi Peng Wu; Lirong Zheng; Zhiping Lai; Jian Zhang; Magnus Rueping; Yu Han; Huabin Zhang

doi:10.1002/anie.202411218

Unveiling the Activity Origin of Electrochemical Oxygen Evolution on Heteroatom-Decorated Carbon Matrix

Yang Li, Cailing Chen, Guoxiang Zhao, Huawei Huang, Yuanfu Ren, Shouwei Zuo, Zhi Peng Wu, Lirong Zheng, Zhiping Lai, Jian Zhang, Magnus Rueping, Yu Han, Huabin Zhang^*

^*Corresponding author for this work

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

6 Scopus citations

Abstract

Chemical modification via functional dopants in carbon materials holds great promise for elevating catalytic activity and stability. To gain comprehensive insights into the pivotal mechanisms and establish structure-performance relationships, especially concerning the roles of dopants, remains a pressing need. Herein, we employ computational simulations to unravel the catalytic function of heteroatoms in the acidic oxygen evolution reaction (OER), focusing on a physical model of high-electronegative F and N co-doped carbon matrix. Theoretical and experimental findings elucidate that the enhanced activity originates from the F and pyridinic-N (P_y−N) species that achieve carbon activation. This activated carbon significantly lowers the conversion energy barrier from O* to OOH*, shifts the potential-limiting step from OOH* formation to O* generation, and ultimately optimizes the energy barrier of the potential-limiting step. This wok elucidates that the critical role of heteroatoms in catalyzing the reaction and unlocks the potential of carbon materials for acidic OER.

Original language	English (US)
Article number	e202411218
Journal	Angewandte Chemie - International Edition
Volume	63
Issue number	50
DOIs	https://doi.org/10.1002/anie.202411218
State	Published - Dec 9 2024

Keywords

activity origin
co-doping
metal-free electrocatalyst
oxygen evolution reaction
water splitting

ASJC Scopus subject areas

Catalysis
General Chemistry

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/anie.202411218

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title = "Unveiling the Activity Origin of Electrochemical Oxygen Evolution on Heteroatom-Decorated Carbon Matrix",

abstract = "Chemical modification via functional dopants in carbon materials holds great promise for elevating catalytic activity and stability. To gain comprehensive insights into the pivotal mechanisms and establish structure-performance relationships, especially concerning the roles of dopants, remains a pressing need. Herein, we employ computational simulations to unravel the catalytic function of heteroatoms in the acidic oxygen evolution reaction (OER), focusing on a physical model of high-electronegative F and N co-doped carbon matrix. Theoretical and experimental findings elucidate that the enhanced activity originates from the F and pyridinic-N (Py−N) species that achieve carbon activation. This activated carbon significantly lowers the conversion energy barrier from O* to OOH*, shifts the potential-limiting step from OOH* formation to O* generation, and ultimately optimizes the energy barrier of the potential-limiting step. This wok elucidates that the critical role of heteroatoms in catalyzing the reaction and unlocks the potential of carbon materials for acidic OER.",

keywords = "activity origin, co-doping, metal-free electrocatalyst, oxygen evolution reaction, water splitting",

author = "Yang Li and Cailing Chen and Guoxiang Zhao and Huawei Huang and Yuanfu Ren and Shouwei Zuo and Wu, {Zhi Peng} and Lirong Zheng and Zhiping Lai and Jian Zhang and Magnus Rueping and Yu Han and Huabin Zhang",

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doi = "10.1002/anie.202411218",

language = "English (US)",

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T1 - Unveiling the Activity Origin of Electrochemical Oxygen Evolution on Heteroatom-Decorated Carbon Matrix

AU - Li, Yang

AU - Chen, Cailing

AU - Zhao, Guoxiang

AU - Huang, Huawei

AU - Ren, Yuanfu

AU - Zuo, Shouwei

AU - Wu, Zhi Peng

AU - Zheng, Lirong

AU - Lai, Zhiping

AU - Zhang, Jian

AU - Rueping, Magnus

AU - Han, Yu

AU - Zhang, Huabin

PY - 2024/12/9

Y1 - 2024/12/9

N2 - Chemical modification via functional dopants in carbon materials holds great promise for elevating catalytic activity and stability. To gain comprehensive insights into the pivotal mechanisms and establish structure-performance relationships, especially concerning the roles of dopants, remains a pressing need. Herein, we employ computational simulations to unravel the catalytic function of heteroatoms in the acidic oxygen evolution reaction (OER), focusing on a physical model of high-electronegative F and N co-doped carbon matrix. Theoretical and experimental findings elucidate that the enhanced activity originates from the F and pyridinic-N (Py−N) species that achieve carbon activation. This activated carbon significantly lowers the conversion energy barrier from O* to OOH*, shifts the potential-limiting step from OOH* formation to O* generation, and ultimately optimizes the energy barrier of the potential-limiting step. This wok elucidates that the critical role of heteroatoms in catalyzing the reaction and unlocks the potential of carbon materials for acidic OER.

AB - Chemical modification via functional dopants in carbon materials holds great promise for elevating catalytic activity and stability. To gain comprehensive insights into the pivotal mechanisms and establish structure-performance relationships, especially concerning the roles of dopants, remains a pressing need. Herein, we employ computational simulations to unravel the catalytic function of heteroatoms in the acidic oxygen evolution reaction (OER), focusing on a physical model of high-electronegative F and N co-doped carbon matrix. Theoretical and experimental findings elucidate that the enhanced activity originates from the F and pyridinic-N (Py−N) species that achieve carbon activation. This activated carbon significantly lowers the conversion energy barrier from O* to OOH*, shifts the potential-limiting step from OOH* formation to O* generation, and ultimately optimizes the energy barrier of the potential-limiting step. This wok elucidates that the critical role of heteroatoms in catalyzing the reaction and unlocks the potential of carbon materials for acidic OER.

KW - activity origin

KW - co-doping

KW - metal-free electrocatalyst

KW - oxygen evolution reaction

KW - water splitting

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U2 - 10.1002/anie.202411218

DO - 10.1002/anie.202411218

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SN - 1433-7851

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JO - Angewandte Chemie - International Edition

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IS - 50

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ER -

Unveiling the Activity Origin of Electrochemical Oxygen Evolution on Heteroatom-Decorated Carbon Matrix

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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