In Situ Electrochemically Activated Vanadium Oxide Cathode for Advanced Aqueous Zn-Ion Batteries

The search for large-capacity and high-energy-density cathode materials for aqueous Zn-ion batteries is still challenging. Here, an in situ electrochemical activation strategy to boost the electrochemical activity of a carbon-confined vanadium trioxide (V2O3@C) microsphere cathode is demonstrated. Tunnel-structured V2O3 undergoes a complete phase transition to a layered, amorphous, and oxygen-deficient Zn0.4V2O5–m ·nH2O on the first charge, thus allowing subsequent (de)­intercalation of zinc cations on the basis of the latter structure, which can be regulated by the amount of H2O in the electrolyte. The electrode thus delivers excellent stability with a significantly high capacity of 602 mAh g–1 over 150 cycles upon being subjected to a low-current-rate cycling, as well as a high-energy density of 439.6 Wh kg–1 and extended life up to 10000 cycles with a 90.3% capacity retention. This strategy will be exceptionally desirable to achieve ultrafast Zn-ion storage with high capacity and energy density.