Quantum capacitance induced by electron orbital reconstruction of g-C 3 N 4 /Co 3 O 4 heterojunction: Improving electrochemical performance

Utilizing diverse material combinations in heterogeneous structures has become an effective approach for regulating interface characteristics and electronic structures. The g-C N /Co O heterostructures were fabricated by uniformly modifying Co O nanoparticles onto discrete clusters of g-C N nanosheets. Then, they were subsequently employed as positive electrode materials for assembling hybrid supercapacitors. According to the first-principles calculation, Co O and g-C N formed Co-N ionic bonds, establishing interfacial space symmetry-broken heterojunction and direct exchange and superexchange between ions at the interface and sub-interface. This resulted in a high-density spin-orbit hybrid heterogeneous polarization interface, significantly improving the quantum capacitance of heterojunction materials. Experimental results showed that the heterojunction had a specific capacitance of 2662 F g at 1 A g . When the power density was 750 W kg , the energy density reached 128 Wh kg . Even when the power density was 16850 W kg , it could show an energy density of 62.5 Wh kg . The g-C N /Co O heterojunction could realize high energy density charge storage as the cathode material of supercapacitors. The construction of heterogeneous polarization interfaces for high-energy quantum capacitors provides a new and effective method for the energy storage field.