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Surface Lattice Modulation through Chemical Delithiation toward a Stable Nickel-Rich Layered Oxide Cathode.

Si-Qi LuQinghua ZhangFanqi MengYa-Ning LiuJianjun MaoSijie GuoMu-Yao QiYan-Song XuYan QiaoSi-Dong ZhangKecheng JiangLin GuYang XiaShuguang ChenGuanHua ChenAn-Min CaoLi-Jun Wan
Published in: Journal of the American Chemical Society (2023)
Nickel-rich layered oxides (NLOs) are considered as one of the most promising cathode materials for next-generation high-energy lithium-ion batteries (LIBs), yet their practical applications are currently challenged by the unsatisfactory cyclability and reliability owing to their inherent interfacial and structural instability. Herein, we demonstrate an approach to reverse the unstable nature of NLOs through surface solid reaction, by which the reconstructed surface lattice turns stable and robust against both side reactions and chemophysical breakdown, resulting in improved cycling performance. Specifically, conformal La(OH) 3 nanoshells are built with their thicknesses controlled at nanometer accuracy, which act as a Li + capturer and induce controlled reaction with the NLO surface lattices, thereby transforming the particle crust into an epitaxial layer with localized Ni/Li disordering, where lithium deficiency and nickel stabilization are both achieved by transforming oxidative Ni 3+ into stable Ni 2+ . An optimized balance between surface stabilization and charge transfer is demonstrated by a representative NLO material, namely, LiNi 0.83 Co 0.07 Mn 0.1 O 2 , whose surface engineering leads to a highly improved capacity retention and excellent rate capability with a strong capability to inhibit the crack of NLO particles. Our study highlights the importance of surface chemistry in determining chemical and structural behaviors and paves a research avenue in controlling the surface lattice for the stabilization of NLOs toward reliable high-energy LIBs.
Keyphrases
  • reduced graphene oxide
  • ion batteries
  • metal organic framework
  • gold nanoparticles
  • solid state
  • carbon nanotubes