Affiliation:
1. Department of Materials Science and Engineering Berkeley 94720 USA
2. Materials Sciences Division Lawrence Berkeley National Laboratory Berkeley 94720 USA
3. Material, Physical and Chemical Sciences Center Sandia National Laboratories Sandia 87185 USA
Abstract
AbstractRechargeable multivalent‐ion batteries are attractive alternatives to Li‐ion batteries to mitigate their issues with metal resources and metal anodes. However, many challenges remain before they can be practically used due to the low solid‐state mobility of multivalent ions. In this study, a promising material identified by high‐throughput computational screening is investigated, ε‐VOPO4, as a Mg cathode. The experimental and computational evaluation of ε‐VOPO4 suggests that it may provide an energy density of >200 Wh kg−1 based on the average voltage of a complete cycle, significantly more than that of well‐known Chevrel compounds. Furthermore, this study finds that Mg‐ion diffusion can be enhanced by co‐intercalation of Li or Na, pointing at interesting correlation dynamics of slow and fast ions.
Funder
U.S. Department of Energy
Basic Energy Sciences
National Energy Research Scientific Computing Center
Fulbright Association