Trunk-Leaf Vein structure inspired synthesis of mesoporous Carbon@Nickel oxide/nickel ternary composite for sustainable supercapacitor electrode

Supercapacitors are sustainable energy storage devices with the characteristics of high power density, long life span and ultrafast charge-discharge time. Herein, considering low conductivity of NiO and inspired by the trunk-leaf vein structure, mesoporous carbon and nickel dots are introduced into structure reacting as electron scaffold via facile hydrothermal and annealing procedures. Special hierarchical structure is obtained with oxygen modified mesoporous carbon (OMC) as core and NiO sheets as core accompanying with metallic nickel dots deposited on NiO sheets. Such trunk-leaf vein architecture can effectively ensure more active sites contacting with electrolyte, furthermore provide conductive scaffolds for electron transport. As expected, the OMC@NiO/Ni exhibits high specific capacitance of 651.3 F g(-1) at 2 A g(-1) and superior cycling life of 92.2% after 4000 cycles. Moreover, a novel negative electrode rGO/VOx is synthesized ascribe to the superior capacitance and life span. At last, an asymmetric device is assembled using OMC@NiO/Ni as positive electrode and rGO/VOx as negative electrode, which delivers maximum energy density of 44.3 Wh kg(-1), high power density of 12,000 W kg(-1) and excellent cycling life of 94.5% after 5000 cycles. The high performance of OMC@NiO/Ni renders it a potential material for energy storage-conversion equipments.

Automated summary

By introducing mesoporous carbon and nickel dots, the special structure of OMC@NiO/Ni has been created, enhancing the active sites contacting with electrolyte and providing conductive scaffolds for electron transport. This structure exhibits high specific capacitance and excellent cycling life, offering potential application prospects for energy storage-conversion equipments.