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Article Abstract
As an important cathode candidate for the high-performance sodium ion batteries (SIBs), P2-type oxides with layered structures are needed to balance the specific capacities and cycling stability. As a result, a cation and anion codoped strategy has been adopted to tune the electrochemical activity of the redox centers and modulate the structure properties. Herein, a series of P2-NaMnNiOF ( = 0, 0.03, 0.05, and 0.07) cathodes with microsphere structures are synthesized, using a solid-state reaction in the presence of MnO microsphere self-templates. Compared with the cation-doped NaMnNiO, additional F-doping can affect the lattice parameters and redox centers of NaMnNiOF. Comprehensively considering the specific capacities, cycling stability, and rate capability, the optimized x value in NaMnNiOF is determined to be 0.05. In the half cells, NaMnNiOF (F-0.05) maintains a capacity of 90.5 mA h g in the first cycle at 1.0 A g, giving a capacity retention of 78% within 900 cycles. The superior rate capability of F-0.05 is guaranteed by the larger diffusion coefficient of Na () combined with higher charge transfer speed. In addition, when coupled with MoSe/PC anodes, the full cells also exhibit impressive electrochemical performance.
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