Atomic metal–non-metal catalytic pair drives efficient hydrogen oxidation catalysis in fuel cells

Qilun Wang; Huawei Wang; Hao Cao; Ching Wei Tung; Wei Liu; Sung Fu Hung; Weijue Wang; Chun Zhu; Zihou Zhang; Weizheng Cai; Yaqi Cheng; Hua Bing Tao; Hao Ming Chen; Yang Gang Wang; Yujing Li; Hong Bin Yang; Yanqiang Huang; Jun Li; Bin Liu

doi:10.1038/s41929-023-01017-z

Atomic metal–non-metal catalytic pair drives efficient hydrogen oxidation catalysis in fuel cells

Qilun Wang, Huawei Wang, Hao Cao, Ching Wei Tung, Wei Liu, Sung Fu Hung, Weijue Wang, Chun Zhu, Zihou Zhang, Weizheng Cai, Yaqi Cheng, Hua Bing Tao^*, Hao Ming Chen, Yang Gang Wang^*, Yujing Li^*, Hong Bin Yang^*, Yanqiang Huang, Jun Li, Bin Liu^*

^*Corresponding author for this work

School of Material Science and Engineering

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

55 Citations (Scopus)

Abstract

Rational design of efficient hydrogen oxidation reaction (HOR) electrocatalysts with maximum utilization of platinum-group metal sites is critical to hydrogen fuel cells, but remains a major challenge due to the formidable potential-dependent energy barrier for hydrogen intermediate (H*) desorption on single metal centres. Here we report atomically dispersed iridium–phosphorus (Ir–P) catalytic pairs with strong electronic coupling that integratively facilitate HOR kinetics, in which the reactive hydroxyl species adsorbed on the more oxophilic P site induces an alternative thermodynamic pathway to facilely combine with H* on the adjacent Ir atom, whereas isolated single-atom Ir catalysts are inactive. In H₂–O₂ fuel cells, this catalyst enables a peak power density of 1.93 W cm⁻² and an anodic mass activity as high as 17.11 A mg_Ir⁻¹ at 0.9 V_iR-free, significantly outperforming commercial Pt/C. This work not only advances the development of anodic catalysts for fuel cells, but also provides a precise and universal active-site design principle for multi-intermediate catalysis. [Figure not available: see fulltext.].

Original language	English
Pages (from-to)	916-926
Number of pages	11
Journal	Nature Catalysis
Volume	6
Issue number	10
DOIs	https://doi.org/10.1038/s41929-023-01017-z
Publication status	Published - Oct 2023

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Wang, Q., Wang, H., Cao, H., Tung, C. W., Liu, W., Hung, S. F., Wang, W., Zhu, C., Zhang, Z., Cai, W., Cheng, Y., Tao, H. B., Chen, H. M., Wang, Y. G., Li, Y., Yang, H. B., Huang, Y., Li, J., & Liu, B. (2023). Atomic metal–non-metal catalytic pair drives efficient hydrogen oxidation catalysis in fuel cells. Nature Catalysis, 6(10), 916-926. https://doi.org/10.1038/s41929-023-01017-z

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title = "Atomic metal–non-metal catalytic pair drives efficient hydrogen oxidation catalysis in fuel cells",

abstract = "Rational design of efficient hydrogen oxidation reaction (HOR) electrocatalysts with maximum utilization of platinum-group metal sites is critical to hydrogen fuel cells, but remains a major challenge due to the formidable potential-dependent energy barrier for hydrogen intermediate (H*) desorption on single metal centres. Here we report atomically dispersed iridium–phosphorus (Ir–P) catalytic pairs with strong electronic coupling that integratively facilitate HOR kinetics, in which the reactive hydroxyl species adsorbed on the more oxophilic P site induces an alternative thermodynamic pathway to facilely combine with H* on the adjacent Ir atom, whereas isolated single-atom Ir catalysts are inactive. In H2–O2 fuel cells, this catalyst enables a peak power density of 1.93 W cm−2 and an anodic mass activity as high as 17.11 A mgIr−1 at 0.9 ViR-free, significantly outperforming commercial Pt/C. This work not only advances the development of anodic catalysts for fuel cells, but also provides a precise and universal active-site design principle for multi-intermediate catalysis. [Figure not available: see fulltext.].",

author = "Qilun Wang and Huawei Wang and Hao Cao and Tung, {Ching Wei} and Wei Liu and Hung, {Sung Fu} and Weijue Wang and Chun Zhu and Zihou Zhang and Weizheng Cai and Yaqi Cheng and Tao, {Hua Bing} and Chen, {Hao Ming} and Wang, {Yang Gang} and Yujing Li and Yang, {Hong Bin} and Yanqiang Huang and Jun Li and Bin Liu",

note = "Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2023",

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doi = "10.1038/s41929-023-01017-z",

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T1 - Atomic metal–non-metal catalytic pair drives efficient hydrogen oxidation catalysis in fuel cells

AU - Wang, Qilun

AU - Wang, Huawei

AU - Cao, Hao

AU - Tung, Ching Wei

AU - Liu, Wei

AU - Hung, Sung Fu

AU - Wang, Weijue

AU - Zhu, Chun

AU - Zhang, Zihou

AU - Cai, Weizheng

AU - Cheng, Yaqi

AU - Tao, Hua Bing

AU - Chen, Hao Ming

AU - Wang, Yang Gang

AU - Li, Yujing

AU - Yang, Hong Bin

AU - Huang, Yanqiang

AU - Li, Jun

AU - Liu, Bin

PY - 2023/10

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N2 - Rational design of efficient hydrogen oxidation reaction (HOR) electrocatalysts with maximum utilization of platinum-group metal sites is critical to hydrogen fuel cells, but remains a major challenge due to the formidable potential-dependent energy barrier for hydrogen intermediate (H*) desorption on single metal centres. Here we report atomically dispersed iridium–phosphorus (Ir–P) catalytic pairs with strong electronic coupling that integratively facilitate HOR kinetics, in which the reactive hydroxyl species adsorbed on the more oxophilic P site induces an alternative thermodynamic pathway to facilely combine with H* on the adjacent Ir atom, whereas isolated single-atom Ir catalysts are inactive. In H2–O2 fuel cells, this catalyst enables a peak power density of 1.93 W cm−2 and an anodic mass activity as high as 17.11 A mgIr−1 at 0.9 ViR-free, significantly outperforming commercial Pt/C. This work not only advances the development of anodic catalysts for fuel cells, but also provides a precise and universal active-site design principle for multi-intermediate catalysis. [Figure not available: see fulltext.].

AB - Rational design of efficient hydrogen oxidation reaction (HOR) electrocatalysts with maximum utilization of platinum-group metal sites is critical to hydrogen fuel cells, but remains a major challenge due to the formidable potential-dependent energy barrier for hydrogen intermediate (H*) desorption on single metal centres. Here we report atomically dispersed iridium–phosphorus (Ir–P) catalytic pairs with strong electronic coupling that integratively facilitate HOR kinetics, in which the reactive hydroxyl species adsorbed on the more oxophilic P site induces an alternative thermodynamic pathway to facilely combine with H* on the adjacent Ir atom, whereas isolated single-atom Ir catalysts are inactive. In H2–O2 fuel cells, this catalyst enables a peak power density of 1.93 W cm−2 and an anodic mass activity as high as 17.11 A mgIr−1 at 0.9 ViR-free, significantly outperforming commercial Pt/C. This work not only advances the development of anodic catalysts for fuel cells, but also provides a precise and universal active-site design principle for multi-intermediate catalysis. [Figure not available: see fulltext.].

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Atomic metal–non-metal catalytic pair drives efficient hydrogen oxidation catalysis in fuel cells

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