Journal
ACS ENERGY LETTERS
Volume -, Issue -, Pages 1354-1361Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acsenergylett.3c00083
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In this study, the cycling stability of a Ni-rich NCMA93 cathode was improved by a combination strategy involving microstructural refinement and surface modification, leading to the formation of a robust cathode-electrolyte interphase (CEI) layer on the cathode surface, which suppressed surface degradation and extended battery life.
Li[Ni1-x-y-zCoxMnyAlz]O2 (NCMA) cathodes have attracted public attention owing to their improved durability by leveraging the advantages of NCM and NCA cathodes. As the Ni content approaches 90%, however, it is challenging to realize high-energy Ni-rich NCMA cathodes without sacrificing durability. Herein, we improve the cycling stability of a Ni-rich Li[Ni0.93Co0.03Mn0.03Al0.01]O2 (NCMA93) cathode using a combination strategy involving microstructural refinement and surface modification. The F-coating-induced protective layer of the F coated, Sb-doped NCMA93 cathode combined with its engineered microstructure enables the formation of a robust cathode-electrolyte interphase (CEI) layer on the cathode surface, which suppresses surface degradation to afford a long battery life. However, the F coating alone does not significantly improve the cycling stability of cathode because it suffers severe microcracking during cycling owing to its suboptimal microstructure. To realize a cathode with a long lifespan, a robust CEI layer should be generated and maintained on the cathode without severe microcracking.
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