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Mesoporous spherical Ni(OH)2@g-C3N4 hybrid heterostructures with amorphous shell as battery-type capacitive cathodes for enabling high-performance hybrid supercapacitors

Rui Wang, Won Young Jang, Mule Vijayalakshmi, Raghava Reddy Kakarla, Ch. Venkata Reddy, Jaesool Shim

2024Journal of Energy Storage12 citationsDOIOpen Access PDF

Abstract

Ni(OH)2-based materials are widely considered advanced energy storage materials, but their poor cycle performance makes their practical application and commercialization slow. Herein, Ni(OH)2@g-C3N4 core-shell (crystal and amorphous) heterojunctions are synthesized. These heterojunctions enhance the specific surface area and ionic diffusion, especially the heterojunction formed by the amorphous shell, which shows robust performance. This heterojunction mainly uses the fast reversible Faraday reaction of battery type as the primary energy storage mechanism. The as-prepared core-shell heterojunction showed nearly double specific capacitance and excellent cycle stability (578.5 F g−1 and 109.3 % retentions after 5000 cycles) over pristine Ni(OH)2 (285.8 F g−1 and 101.6 % retentions after 5000 cycles). Finally, an efficient hybrid supercapacitor is developed via Ni(OH)2@g-C3N4//AC, which combines the advantages of the battery and supercapacitors. The hybrid supercapacitor device shows enhanced capacitance (311.8 F g−1) and outstanding cycle performance (84.3 % retentions after 10,000 cycles). In particular, the energy density of 78.0 Wh kg−1 can still be provided while maintaining the power density of 1201.1 W kg−1. This emerging heterostructure offers new insight into Ni(OH)2-based materials in energy applications.

Topics & Concepts

SupercapacitorHeterojunctionMaterials scienceAmorphous solidCapacitanceMesoporous materialChemical engineeringBattery (electricity)NanotechnologyEnergy storagePower densityOptoelectronicsElectrodeChemistryPower (physics)Organic chemistryPhysical chemistryCatalysisQuantum mechanicsPhysicsEngineeringSupercapacitor Materials and FabricationAdvanced battery technologies researchAdvancements in Battery Materials