Lithium-Ion Conductive Coatings for Nickel-Rich Cathodes for Lithium-Ion Batteries.
Yijia ShaoJia XuAmardeep AmardeepYakang XiaXiangbo MengJian LiuShijun LiaoPublished in: Small methods (2024)
Nickel (Ni)-rich cathodes are among the most promising cathode materials of lithium batteries, ascribed to their high-power density, cost-effectiveness, and eco-friendliness, having extensive applications from portable electronics to electric vehicles and national grids. They can boost the wide implementation of renewable energies and thereby contribute to carbon neutrality and achieving sustainable prosperity in the modern society. Nevertheless, these cathodes suffer from significant technical challenges, leading to poor cycling performance and safety risks. The underlying mechanisms are residual lithium compounds, uncontrolled lithium/nickel cation mixing, severe interface reactions, irreversible phase transition, anisotropic internal stress, and microcracking. Notably, they have become more serious with increasing Ni content and have been impeding the widespread commercial applications of Ni-rich cathodes. Various strategies have been developed to tackle these issues, such as elemental doping, adding electrolyte additives, and surface coating. Surface coating has been a facile and effective route and has been investigated widely among them. Of numerous surface coating materials, have recently emerged as highly attractive options due to their high lithium-ion conductivity. In this review, a thorough and comprehensive review of lithium-ion conductive coatings (LCCs) are made, aimed at probing their underlying mechanisms for improved cell performance and stimulating new research efforts.
Keyphrases
- solid state
- reduced graphene oxide
- ion batteries
- metal organic framework
- quality improvement
- ionic liquid
- healthcare
- gold nanoparticles
- primary care
- stem cells
- single cell
- carbon nanotubes
- single molecule
- risk assessment
- density functional theory
- cell therapy
- transition metal
- molecular dynamics
- high resolution
- high speed