▎ 摘 要
Demanding more reliable power sources causes a huge development of modern electronic and optoelectronic devices with a high energy density (ENDE) and exceptional durability. Accordingly, designing modern electrode materials with outstanding structures can improve the construction of a new generation of electronic devices. Transition metal oxides hollow structures (TMOHS) have received considerable attention as appropriate materials for supercapacitors due to their structural properties and electrochemical performances. As a fascinating TMOHS, we make a new highly porous triple-shelled cobalt gallium oxide (CoGa2O4) hollow spheres (HTS-CGOHS) with triple narrow shells, and pseudocapacitive graphene wrapped CuFeS2 hollow spheres (GW@CFSHS) as developed positive and negative electrodes, respectively, in an energy storage device. The HTS-CGOHS electrode shows specific capacitance (SpCa) of 1724.30 F g(-1) (239.5 mAh g(-1)) at 1 A g(-1) which maintains as high as 1198.40 F g(-1)(166.44 mAh g(-1)) at 24 A g(-1), and reasonable durableness (96.80% capacity retention at 12 A g(-1)) owing to the low internal resistance, fast kinetics, reversibility, high surface area (104.30 m(2) g(-1)), and numerous active sites. Moreover, the GW@CFSHS advanced negative electrode reveals electrochemical performance comprising a SpCa of 621.20 F g(-1) (172.6 mAh g(-1)), rate performance of 58% and excellent durableness, which are superior to that of CuFeS2 hollow sphere (CFSHS) electrode. According to the electrochemical nature of the as-obtained pseudocapacitive electrode materials, an energy storage device (ESD) based on the HTS-CGOHS as a cathode and GW@CFSHS as an anode was studied. The HTS-CGOHSHGW@CFSHS device shows SpCa of 376.40 F g(-1) (153.1 mAh g(-1)), high ENDE of 114.8 W h kg(-1), and notable durableness (only 6.3% decrease after 5000 cycles at 6 A g(-1)).