Heterogeneous Degradation in Thick Nickel-Rich Cathodes During High-Temperature Storage and Mitigation of Thermal Instability by Regulating Cationic Disordering.
Lihan ZhangChenglong ZhaoXianying QinShuwei WangLunhua HeKun QianTing HanZhangping YangFeiyu KangBaohua LiPublished in: Small (Weinheim an der Bergstrasse, Germany) (2021)
The thermal instability is a major problem in high-energy nickel-rich layered cathode materials for large-scale battery application. Due to the scarce investigation of thick electrodes at the practical full-cell level, the understanding of thermal failure mechanism is still insufficient. Herein, an intrinsic origin of thermal instability in fully charged industrial pouch cells during high-temperature storage is discovered. Through the investigation from crystals to particles, and from electrodes to cells, it is shown that serious top-down heterogeneous degradation occurs along the depth direction of the thick electrode, including phase transition, cationic disordering, intergranular/intragranular cracks, and side reactions. Such degradation originates from the abundant oxygen vacancies and reduced catalytic Ni2+ at cathode surface, causing microstructural defects and directly leading to the thermal instability. Nonmagnetic elements doping and surface modification are suggested to be effective in mitigating the thermal instability through modulating cationic disordering.
Keyphrases
- reduced graphene oxide
- high temperature
- induced apoptosis
- carbon nanotubes
- cell cycle arrest
- gold nanoparticles
- ion batteries
- cell proliferation
- metal organic framework
- solid state
- mesenchymal stem cells
- heavy metals
- oxidative stress
- optical coherence tomography
- single cell
- pi k akt
- bone marrow
- transition metal
- risk assessment
- room temperature