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  Yan, Y.; Zhou, S.; Zheng, Y.; Zhang, H.; Chen, J.; Zeng, G.; Zhang, B.; Tang, Y.; Zheng, Q.; Wang, C.; Wang, C.W.; Liao, H.G.; Manke, I.; Kuai, X.; Dong, K.; Sun, Y.; Qiao, Y.; Sun, S.G.: Lattice-Matched Interfacial Modulation Based on Olivine Enamel-Like Front-Face Fabrication for High-Voltage LiCoO₂. Advanced Functional Materials 34 (2024), p. 2310799/1-10

10.1002/adfm.202310799

Abstract:
The high-voltage induced undesirable surface passivation bilayer (cathode/electrolyte interface and cation-densified surface phase) of LiCoO2 inevitably leads to battery degradation. Herein, a continual/uniform enamel-like olivine layer on LiCoO2 surface is fabricated by employing a high-speed mechanical fusion method . The enamel-like layer suppresses interfacial side reactions by tuning EC dehydrogenation, contributing to an ultrathin and stable cathode/electrolyte interface. The strong bonding affinity between LiCoO2 and enamel-like layer restrains both lattice oxygen loss and associated layered-to-spinel structural distortion. Moreover, the thermal stability of highly delithiated LiCoO2 is improved, as both the onset temperatures of layered-to-spinel transition and O2 evolution are simultaneously postponed. Stable operation of LiCoO2 at 4.6 V high-voltage and 55 °C elevated temperature (both >85% capacity retention after 200 cycles) is achieved. This facile and scalable high-speed solid-phase coating strategy establishes a technical paradigm to enhance surface/interface stability of high-energy-density cathode candidates by constructing an ideal enamel-like surface layer.