Energy-Density Improvement in Li-Ion Rechargeable Batteries Based on LiCoO(2) + LiV(3)O(8) and Graphite + Li-Metal Hybrid Electrodes

We developed a novel battery system consisting of a hybrid (LiCoO(2) + LiV(3)O(8)) cathode in a cell with a hybrid (graphite + Li-metal) anode and compared it with currently used systems. The hybrid cathode was synthesized using various ratios of LiCoO(2):LiV(3)O(8), where the 80:20 wt% ratio yielded the best electrochemical performance. The graphite and Li-metal hybrid anode, the composition of which was calculated based on the amount of non-lithiated cathode material (LiV(3)O(8)), was used to synthesize a full cell. With the addition of LiV(3)O(8), the discharge capacity of the LiCoO(2) + LiV(3)O(8) hybrid cathode increased from 142.03 to 182.88 mA h g(−1) (a 28.76% improvement). The energy density of this cathode also increased significantly, from 545.96 to 629.24 W h kg(−1) (a 15.21% improvement). The LiCoO(2) + LiV(3)O(8) hybrid cathode was characterized through X-ray diffraction analysis, scanning electron microscopy, and energy-dispersive X-ray spectroscopy. Its electrochemical performance was analyzed using a battery-testing system and electrochemical impedance spectroscopy. We expect that optimized synthesis conditions will enable the development of a novel battery system with an increase in energy density and discharge capacity.