A Coherent Pd–Pd16B3 Core–Shell Electrocatalyst for Controlled Hydrogenation in Nitrogen Reduction Reaction

The manipulation of surface catalytic sites has rarely been explored for metal borides, and the subsurface effects on the electrocatalytic activity of the nitrogen reduction reaction (NRR) remain unknown. Herein, this work develops a core–shell nanoparticle catalyst with a Pd core that ensures high...

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Bibliographic Details
Published in:Advanced functional materials 2024-08, Vol.34 (34), p.n/a
Main Authors: Wen, Yankun, Wang, Tongde, Hao, Jiace, Zhuang, Zechao, Gao, Guohua, Lai, Feili, Lu, Shuanglong, Wang, Xiaofan, Kang, Qi, Wu, Guangming, Du, Mingliang, Zhu, Han
Format: Article
Language:English
Subjects:
Ammonia
atomic structural evolution
Borides
Chemical reduction
Chemical synthesis
Core-shell particles
core–shell nanocrystals
Diffusion rate
Electrocatalysts
Electron transfer
electronic states
Hydrogen evolution reactions
metal borides
nitrogen reduction reaction
Palladium
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Summary:The manipulation of surface catalytic sites has rarely been explored for metal borides, and the subsurface effects on the electrocatalytic activity of the nitrogen reduction reaction (NRR) remain unknown. Herein, this work develops a core–shell nanoparticle catalyst with a Pd core that ensures high electron transfer rates and an Pd16B3 atomical shell that possess tunable active sites for regulating the NRR. The atomic structural evolution from Pd to Pd16B3 is investigated by precisely controlling the B atom diffusion, molecular rearrangement, and d–sp orbital hybridization. Pd/Pd16B3 core–shell nanocrystals exhibit an exceptional NRR performance with a high NH3 Faradaic efficiency of 30.8%, which is superior to those of pristine Pd (1.2%) and B‐doped Pd (4.8%) under identical conditions, and a yield rate of 0.81 µmol h−1 cm−2. This work discovers that the Pd16B3 shell could promote the NRR selectivity by separating the separating the hydrogen evolution reaction proceeded on hole sites and NRR proceeded on bridge sites, and the Pd core could provide the excellent conductivity to Pd16B3 shell through regulated electron interactions. Consequently, the controlled chemical ordering of palladium boride on palladium surfaces provides insight into the synthesis of advanced NRR electrocatalysts. This rationally designs a core–shell nanoparticle catalyst with a Pd core that ensures high electron transfer rates and Pd16B3 atomical shell that possess tunable active sites for regulating the NRR., simultaneously achieving the distinguished NRR activity and selectivity with Faradaic efficiency of 30.8% and NH3 yield of 0.81 µmol h−1 cm−2.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202400849