High‑nickel layered oxides, particularly LiNi₀.₈Co₀.₁Mn₀.₁O₂ (NCM811), are regarded as front-runners for next-generation lithium-ion battery cathodes due to their high energy density and reduced cobalt content. However, their practical implementation is hindered by rapid surface degradation, oxygen evolution, and severe lattice collapse under high-voltage operation. Here, we propose a dynamic cathode-electrolyte interphase (CEI) engineering strategy via a synergistic AlF dual surface modification, which concurrently stabilizes the bulk lattice and protects the interface. Fluorination with ammonium fluoride (NH₄F) promotes the formation of a dense, LiF-enriched CEI, while a conformal Al₂O₃ nanoshell provides adaptive protection against parasitic reactions and mechanical stress. The dual-modified NCM811 exhibits outstanding electrochemical performance, delivering a high initial discharge capacity of 227 mAh g-1 at 0.1C and maintaining 93.2 % capacity retention over 500 cycles at 0.2C. In-situ and ex-situ analyses, including X-ray diffraction and electrochemical impedance spectroscopy, reveal significant suppression of lattice distortion and interfacial resistance under high-voltage cycling. This scalable and cost-effective approach offers a universal platform for enabling high-voltage stability in Ni-rich cathodes, advancing their commercialization in high-energy lithium-ion batteries.
Keywords: AlF dual surface modification; Dynamic CEI structuring; High-voltage stability; Lithium-ion batteries; NCM811 cathodes.
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