Abstract
Silicon is an attractive lithium-ion battery anode material that is held back by its poor cycling stability. Herein, we report the synthesis of a novel CuLi2O@Si core-shell nanowall array electrode by lithiation of pre-synthesized CuO@Si core-shell nanowall arrays during the first cycle. The phase-transition progress from CuO to CuLi2O was realized through an electrochemically driven reduction process based on our voltage-controlled technique. CuLi2O@Si core-shell nanowall arrays, the actual anode material after the first lithiation process, show a high reversible capacity (2421 mAh g−1 at 0.2 C) and enhanced rate capability compared with planar CuSi electrodes. The composition and robustness of the core-shell structure are confirmed by TEM characterization after 5 cycles. In addition, the electrochemical performance of CuLi2O@Si nanowall arrays with different sputtering times has been investigated and the cycling remains stable at much higher mass loading.
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