synthesis of advantageously united copper stannate nanoparticles for a new high powered supercapacitor electrode

In this study, we demonstrate the design and fabrication of a novel flexible nanoarchitecture by facile coating ultrathin copper stannate nanoparticles (Cu 2 SnO 4 NPs) grown radially on nickel foam (NF) to achieve a high specific capacitance, high-energy density, high-power density, and long-term life for supercapacitor electrode applications. The structural and morphological properties of the material were characterized using different techniques. The Cu 2 SnO 4 NPs were used as the active electrode material for supercapacitor applications. The electrochemical properties of the Cu 2 SnO 4 NPs as a binder-free electrode for a supercapacitor were examined using cyclic voltammetry (CV), galvanostatic charge and discharge analysis (GCD), electrochemical impedance spectroscopy (EIS), and cycle life measurements in 2 M KOH electrolyte. The GCD analysis exhibited a specific capacitance as high as 2329.68 F g −1 at 1 A g −1 and a good rate capability (1330 F g −1 at 70 A g −1 ). Moreover, this approach also offers an exceptionally high area-normalized capacitance of 4.66 F cm −2 . This capacitor electrode has excellent cyclic stability with 91.4% capacitance retention after 3000 cycles at 20 A g −1 , together with 99.2% Coulomb efficiency in a three-electrode system. The superior electrochemical performance of the Cu 2 SnO 4 NPs/NF composites is attributed to the synergistic effects of the hierarchical porosity, Cu 2 SnO 4 NPs, and 3D nickel foam network structure, which can effectively accommodate the huge volume change of the Cu 2 SnO 4 nanoparticles during cycling and maintain perfect electrical conductivity throughout the electrode. Furthermore, the asymmetric supercapacitors (ASCs) based on the as-obtained Cu 2 SnO 4 NPs cathode and activated carbon (AC) anode displayed an excellent electrochemical behavior with a high energy density of 91.04 W h kg −1 at 4.35 kW kg −1 and superior cyclic stability. It also shows a small leakage current. Furthermore, the SC device retains 1.1 V of its initial voltage (1.4 V) after the 8 h self-discharge test, which suggests the good state of health of the SC device. These results demonstrate that Cu 2 SnO 4 NPs could be a promising electrode for high-performance energy storage devices. A novel CuNi 2 O 4 @SnS@rGO/NF multicomponent hybrid material leads to fast ion/electron transfers at the electrode/electrolyte interface.