Realization of a 594 Wh kg-1 Lithium-Metal Battery Using a Lithium-Free V2O5 Cathode with Enhanced Performances by Nanoarchitecturing

To realize a high-energy lithium metal battery (LMB) using a high-capacity Li-free cathode, in this work, nanoplate-stacked V2O5 with dominantly exposed (010) facets and a relatively short [010] length is proposed to be used as a cathode. The V2O5 nanostructure can be fabricated via a modified hydrothermal method, including a Li+ crystallization inhibitor, followed by heat treatment. In particular, the enlargement of the favorable Li+ diffusion pathway in the [010] direction and the formation of a robust hierarchical nanoplate-stacked structure in the modified V2O5 improves the electrochemical kinetics and stability; as a result, the nanoplate-stacked V2O5 electrode exhibits a higher capacity and rate performance (258 mAh g(-1) at 50 mA g(-1) [0.17 C], 140 mAh g(-1) at 1 A g(-1) [3.4 C]) and cycling capability (79% capacity retention after 100 cycles at 0.5 C) compared to the previously reported V2O5 nanobelt electrode. Notably, the LMB composed of Li//nanoplate-stacked V2O5 full-cells shows high specific energy densities of 594.1 and 296.2 Wh kg(-1) at 0.1 and 1.0 C, respectively, and a high Coulombic efficiency of 99.6% during 50 cycles.

Automated summary

In this work, a high-energy lithium metal battery with a high-capacity cathode composed of nanoplate-stacked V2O5 is proposed. The V2O5 nanostructure with dominantly exposed (010) facets and a relatively short [010] length is achieved via a modified hydrothermal method. The results show that the nanoplate-stacked V2O5 electrode exhibits improved electrochemical kinetics and stability, leading to higher capacity, rate performance, and cycling capability. The LMB composed of Li//nanoplate-stacked V2O5 full-cells demonstrates high specific energy densities and Coulombic efficiency.