Engineering single-atom electrocatalysts for enhancing kinetics of acidic Volmer reaction
The design of active and low-cost electrocatalyst for hydrogen evolution reaction (HER) is the key to achieving a clean hydrogen energy infrastructure. The most successful design principle of hydrogen electrocatalyst is the activity volcano plot, which is based on Sabatier principle and has been use...
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sg-ntu-dr.10356-1714022023-10-24T03:02:25Z Engineering single-atom electrocatalysts for enhancing kinetics of acidic Volmer reaction Cao, Hao Wang, Qilun Zhang, Zisheng Yan, Hui-Min Zhao, Hongyan Yang, Hongbin Liu, Bin Li, Jun Wang, Yang-Gang School of Chemistry, Chemical Engineering and Biotechnology Engineering::Chemical engineering Hydrogen Evolution Oxygen Reduction The design of active and low-cost electrocatalyst for hydrogen evolution reaction (HER) is the key to achieving a clean hydrogen energy infrastructure. The most successful design principle of hydrogen electrocatalyst is the activity volcano plot, which is based on Sabatier principle and has been used to understand the exceptional activity of noble metal and design of metal alloy catalysts. However, this application of volcano plot in designing single-atom electrocatalysts (SAEs) on nitrogen doped graphene (TM/N4C catalysts) for HER has been less successful due to the nonmetallic nature of the single metal atom site. Herein, by performing ab initio molecular dynamics simulations and free energy calculations on a series of SAEs systems (TM/N4C with TM = 3d, 4d, or 5d metals), we find that the strong charge-dipole interaction between the negatively charged *H intermediate and the interfacial H2O molecules could alter the transition path of the acidic Volmer reaction and dramatically raise its kinetic barrier, despite its favorable adsorption free energy. Such kinetic hindrance is also experimentally confirmed by electrochemical measurements. By combining the hydrogen adsorption free energy and the physics of competing interfacial interactions, we propose a unifying design principle for engineering the SAEs used for hydrogen energy conversion, which incorporates both thermodynamic and kinetic considerations and allows going beyond the activity volcano model. This work is financially supported by NSFC (Grant 22022504) of China, Guangdong “Pearl River” Talent Plan (Grant 2019QN01L353), Shenzhen Science and Technology Program (Grant JCYJ20210324103608023), and Guangdong Provincial Key Laboratory of Catalysis (Grant 2020B121201002). B.L. acknowledges the financial support from City University of Hong Kong startup fund. The XAS measurement was performed at Shanghai Synchrotron Radiation Facility by Prof. Xiaozhi Su and was supported by NSFC (Grant 22102207) of China. 2023-10-24T03:02:25Z 2023-10-24T03:02:25Z 2023 Journal Article Cao, H., Wang, Q., Zhang, Z., Yan, H., Zhao, H., Yang, H., Liu, B., Li, J. & Wang, Y. (2023). Engineering single-atom electrocatalysts for enhancing kinetics of acidic Volmer reaction. Journal of the American Chemical Society, 145(24), 13038-13047. https://dx.doi.org/10.1021/jacs.2c13418 0002-7863 https://hdl.handle.net/10356/171402 10.1021/jacs.2c13418 37285479 2-s2.0-85163919932 24 145 13038 13047 en Journal of the American Chemical Society © 2023 American Chemical Society. All rights reserved. |
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Engineering::Chemical engineering Hydrogen Evolution Oxygen Reduction Cao, Hao Wang, Qilun Zhang, Zisheng Yan, Hui-Min Zhao, Hongyan Yang, Hongbin Liu, Bin Li, Jun Wang, Yang-Gang Engineering single-atom electrocatalysts for enhancing kinetics of acidic Volmer reaction |
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The design of active and low-cost electrocatalyst for hydrogen evolution reaction (HER) is the key to achieving a clean hydrogen energy infrastructure. The most successful design principle of hydrogen electrocatalyst is the activity volcano plot, which is based on Sabatier principle and has been used to understand the exceptional activity of noble metal and design of metal alloy catalysts. However, this application of volcano plot in designing single-atom electrocatalysts (SAEs) on nitrogen doped graphene (TM/N4C catalysts) for HER has been less successful due to the nonmetallic nature of the single metal atom site. Herein, by performing ab initio molecular dynamics simulations and free energy calculations on a series of SAEs systems (TM/N4C with TM = 3d, 4d, or 5d metals), we find that the strong charge-dipole interaction between the negatively charged *H intermediate and the interfacial H2O molecules could alter the transition path of the acidic Volmer reaction and dramatically raise its kinetic barrier, despite its favorable adsorption free energy. Such kinetic hindrance is also experimentally confirmed by electrochemical measurements. By combining the hydrogen adsorption free energy and the physics of competing interfacial interactions, we propose a unifying design principle for engineering the SAEs used for hydrogen energy conversion, which incorporates both thermodynamic and kinetic considerations and allows going beyond the activity volcano model. |
| author2 |
School of Chemistry, Chemical Engineering and Biotechnology |
| author_facet |
School of Chemistry, Chemical Engineering and Biotechnology Cao, Hao Wang, Qilun Zhang, Zisheng Yan, Hui-Min Zhao, Hongyan Yang, Hongbin Liu, Bin Li, Jun Wang, Yang-Gang |
| format |
Article |
| author |
Cao, Hao Wang, Qilun Zhang, Zisheng Yan, Hui-Min Zhao, Hongyan Yang, Hongbin Liu, Bin Li, Jun Wang, Yang-Gang |
| author_sort |
Cao, Hao |
| title |
Engineering single-atom electrocatalysts for enhancing kinetics of acidic Volmer reaction |
| title_short |
Engineering single-atom electrocatalysts for enhancing kinetics of acidic Volmer reaction |
| title_full |
Engineering single-atom electrocatalysts for enhancing kinetics of acidic Volmer reaction |
| title_fullStr |
Engineering single-atom electrocatalysts for enhancing kinetics of acidic Volmer reaction |
| title_full_unstemmed |
Engineering single-atom electrocatalysts for enhancing kinetics of acidic Volmer reaction |
| title_sort |
engineering single-atom electrocatalysts for enhancing kinetics of acidic volmer reaction |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/171402 |
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1781793742079918080 |