Carbon-encapsulated V2O3 nanorods for high-performance aqueous Zn-ion batteries

Searching for stable cathodes is of paramount importance to the commercial development of low-cost and safe aqueous Zn-ion batteries (AZIBs). V2O3 is a good candidate for AZIB cathodes but has unsatisfied cycling stability. Herein, we solve the stability issue of a V2O3 cathode by coating a robust carbon shell. Strong evidence was provided that V2O3 was oxidized to favorable V(2)O(5)Greek ano teleianH(2)O during charging and the carbon shell could promote the oxidation of V2O3 to V(2)O(5)Greek ano teleianH(2)O. The discharge capacity was increased from & SIM;45 mA h g(-1) to 336 mA h g(-1) after V2O3 was oxidized to V(2)O(5)Greek ano teleianH(2)O, indicating a higher Zn2+-storage capability of V(2)O(5)Greek ano teleianH(2)O than V2O3. In addition, the rate-capability and long-term cycling performance are greatly enhanced after coating carbon shells on the surface of V2O3 nanorods. Therefore, the presented strategy of introducing carbon shells and fundamental insights into the favorable role of carbon shells in this study contribute to the advancement of highly stable AZIBs.