Ni crossover catalysis: truth of hydrogen evolution in Ni-rich cathode-based lithium-ion batteries

Hydrogen in Ni-rich cathode-based batteries is always accompanied by capacity decay and safety risks. However, insights into the H 2 evolution have puzzled the battery community for decades. In general, solvent reduction on the anode side is considered the reason. However, we have found that it cont...

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Bibliographic Details
Published in:Energy & environmental science 2023-03, Vol.16 (3), p.12-129
Main Authors: Wang, Xingqin, Ren, Dongsheng, Liang, Hongmei, Song, Youzhi, Huo, Hua, Wang, Aiping, Gao, Yunzhi, Liu, Jianhong, Gao, Yun, Wang, Li, He, Xiangming
Format: Article
Language:English
Subjects:
Batteries
Catalysis
Catalysts
Cathodes
Evolution
Hydrogen evolution
Lithium
Lithium-ion batteries
Nickel
Protons
Rechargeable batteries
Solvents
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Summary:Hydrogen in Ni-rich cathode-based batteries is always accompanied by capacity decay and safety risks. However, insights into the H 2 evolution have puzzled the battery community for decades. In general, solvent reduction on the anode side is considered the reason. However, we have found that it contradicts some experimental results. Herein, we experimentally demonstrate the clear pathway of H 2 evolution, which we call "double crossover-double catalysis" (DC-DC). The first "catalysis" occurs on the cathode side, where Ni catalyzes solvent decomposition, forming proton-containing side products. The "double crossover" indicates that the side products and dissolved nickel ions both cross to the anode side, where the nickel ion is reduced to the Ni metal catalyst. The second "catalysis" is that the Ni metal on the anode catalyzes the reduction of the proton-containing side-products, forming H 2 . This study emphasizes the catalytic effect of Ni on both electrodes and establishes a "DC-DC" pathway for H 2 evolution in LIBs, shedding light on the hindrance of H 2 evolution in Ni-rich cathode-based batteries. A "double catalysis-double crossover" (DC-DC) mechanism is proposed for H 2 evolution in NMC-based LIBs. Two catalyses exist on both electrodes and two crossovers occur from cathode to anode, which all contribute to H 2 evolution in NMC-based LIBs.
ISSN:1754-5692
1754-5706
DOI:10.1039/d2ee04109j