Enhanced Redox Electrocatalysis in High-Entropy Perovskite Fluorides by Tailoring d–p Hybridization

Highlights The tailored KCoMnNiMgZnF 3 -HEC cathode delivers extremely high discharge capacity (22,104 mAh g −1 ), outstanding long-term cyclability (over 500 h), preceding majority of traditional catalysts reported. Entropy effect of multiple sites in KCoMnNiMgZnF 3 -HEC engenders appropriate regul...

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Published in:Nano-micro letters 2024-12, Vol.16 (1), p.55-18, Article 55
Main Authors: Li, Xudong, Qiang, Zhuomin, Han, Guokang, Guan, Shuyun, Zhao, Yang, Lou, Shuaifeng, Zhu, Yongming
Format: Article
Language:English
Subjects:
Catalysts
Catalytic kinetics
Discharge
d–p orbital hybridization
Electrocatalysis
Electrocatalysts
Engineering
Entropy
Entropy effect
Fluorides
Hybridization
KCoMnNiMgZnF3-HEC perovskite fluoride
Lithium batteries
Lithium–oxygen batteries
Mass transfer
Nanoscale Science and Technology
Nanotechnology
Nanotechnology and Microengineering
Nucleation
Perovskites
Reaction intermediates
Reaction kinetics
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Summary:Highlights The tailored KCoMnNiMgZnF 3 -HEC cathode delivers extremely high discharge capacity (22,104 mAh g −1 ), outstanding long-term cyclability (over 500 h), preceding majority of traditional catalysts reported. Entropy effect of multiple sites in KCoMnNiMgZnF 3 -HEC engenders appropriate regulation of 3 d orbital structure, leading to a moderate hybridization with the p orbital of key intermediate. The homogeneous nucleation of Li 2 O 2 is achieved on multiple cation site, contributing to effective mass transfer at the three-phase interface, and thus, the reversibility of O 2 /Li 2 O 2 conversion. High-entropy catalysts featuring exceptional properties are, in no doubt, playing an increasingly significant role in aprotic lithium-oxygen batteries. Despite extensive effort devoted to tracing the origin of their unparalleled performance, the relationships between multiple active sites and reaction intermediates are still obscure. Here, enlightened by theoretical screening, we tailor a high-entropy perovskite fluoride (KCoMnNiMgZnF 3 -HEC) with various active sites to overcome the limitations of conventional catalysts in redox process. The entropy effect modulates the d -band center and d orbital occupancy of active centers, which optimizes the d – p hybridization between catalytic sites and key intermediates, enabling a moderate adsorption of LiO 2 and thus reinforcing the reaction kinetics. As a result, the Li–O 2 battery with KCoMnNiMgZnF 3 -HEC catalyst delivers a minimal discharge/charge polarization and long-term cycle stability, preceding majority of traditional catalysts reported. These encouraging results provide inspiring insights into the electron manipulation and d orbital structure optimization for advanced electrocatalyst.
ISSN:2311-6706
2150-5551
2150-5551
DOI:10.1007/s40820-023-01275-3