Version 2 2022-10-25, 19:07Version 2 2022-10-25, 19:07
Version 1 2022-10-21, 08:29Version 1 2022-10-21, 08:29
journal contribution
posted on 2022-10-25, 19:07authored byYike Lei, Yuval Elias, Yongkang Han, Dongdong Xiao, Jun Lu, Jie Ni, Yingchuan Zhang, Cunman Zhang, Doron Aurbach, Qiangfeng Xiao
Li-rich Mn-based layered oxide cathodes with a high discharge
capacity
hold great promise for high energy density lithium-ion batteries.
However, application is hampered by voltage and capacity decay and
gas evolution during cycling due to interfacial side reactions. Here,
we report coating by oxygen-deficient perovskite La0.9Sr0.1CoO3 using the Pechini process. X-ray photoelectron
spectroscopy and scanning transmission electron microscopy both exhibit
a uniform coating layer with a high oxygen vacancy concentration.
The coating effectively mitigates the first cycle irreversible capacity
loss and voltage decay while increasing cyclability. Optimized coating
improves capacity retention from 55.6% to 84.8% after 400 cycles at
2 C. Operando differential electrochemical mass spectroscopy
shows that such a coating can significantly mitigate the release of
oxygen and carbon dioxide. Electrochemical impedance spectroscopy
and post-mortem analysis indicate that the coating layer forms a stable
interface and restricts structure evolution and cation mixing during
cycling, conferring these cathode materials with better cycling and
voltage stability. The perovskite can be applied to other cathodes
with high voltage and capacity to suppress interfacial side reactions
toward developing stable high energy density batteries.