Highly active ruthenium sites stabilized by modulating electron-feeding for sustainable acidic oxygen-evolution electrocatalysis
Zhejiang University · Central China Normal University · +3 more institutions
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Abstract
An electron-feeding modulation strategy is developed to stabilize the highly active ruthenium site and strengthen the adsorption of the OH* intermediate toward sustainable acidic water electrolysis.
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289
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- 12.72
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- 100%
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Authors
10Topics & keywords
Topics
Keywords
- Ruthenium
- Electrocatalyst
- Electrolysis of water
- Oxygen evolution
- Adsorption
- Electrolysis
- Chemistry
- Oxygen
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Funding
- NNNational Natural Science Foundation of ChinaAwards: 21878270, 21961160742, 21922811, U20A20246
- CAChinese Academy of Sciences
- ZUZhejiang University
- CUCentral University Basic Research Fund of ChinaAward: 2020XZZX002-09
- UAUniversity at Buffalo
- NSNatural Science Foundation of Zhejiang ProvinceAward: LR19B060002