Bulk-Interface Synergy Enables Stable High-Voltage P2-Type Layered Oxide Cathodes for Fast-Charging Sodium-Ion Batteries

P2-type layered oxides hold great promise for high-energy sodium-ion batteries (SIBs) but are hindered by irreversible P2–O2 transitions and interfacial degradation that accelerate capacity fading. Herein, we present a bulk-interface dual-engineering strategy through synergistic Mg2+ doping and CeO2 surface modulation to overcome these challenges. The designed P2-type Na0.67Mg0.1Ni0.23Mn0.67O2–CeO2 (NNMMO-Ce) cathode integrates structural reinforcement and redox synergy: bulk Mg2+ stabilizes the lattice, widens Na+ diffusion channels, and suppresses destructive high-voltage transitions, while a conformal CeO2 nanolayer buffers lattice strain (∼0.9%), prevents intragranular cracking, and enables the storage and release of (O2)n− species through reversible Ce3+/Ce4+ redox activity. This coupled mechanism coordinates electron–ion transport, minimizes polarization effects, and significantly reduces charge transfer resistance as well as the escape of lattice oxygen. Consequently, NNMMO-Ce exhibits superior performance with 94.0% capacity retention at 0.1 C and 66.2 mAh g–1 at 20 C, along with highly reversible P2-OP4 transitions and >35-fold enhanced Na+ diffusion. When paired with a hard-carbon anode, the full cell delivers a high energy density of 258.97 Wh kg–1 and excellent cycling stability over 2–4.35 V. This work establishes a cooperative bulk-interface strategy for constructing high-capacity, fast-charging, and long-lived SIB cathodes.

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