Superior electrochemical performance of metal ligand framework-neodymium oxide composite for energy storage devices

Battery supercapacitor hybrids are gaining increasing importance in the realm of energy storage, driven by their exceptional electrochemical attributes, where the choice of electrode material emerges as a paramount factor for their efficacy. Here the enhancement in the electrochemical activity from the synergistic effect produced by combining copper benzene tetra carboxylate with neodymium oxide (Cu-1,3,5-BTC/Nd2O3) along with the individual samples Cu-1,3,5-BTC, and Nd2O3, is studied via various electrochemical measurements which includes CV, GCD and EIS in half cell assembly and for real-world applications in full cell assembly. The hybrid device achieved a specific capacity (Qs) of 390 C/g with an energy density (Es) of 91 W/kg and power density (Ps) of 5950 Wh/kg respectively. Theoretical approaches like linear and quadratic models were further employed and compared to scrutinize the CV curves and to deconvolute the capacitive and diffusive contribution.