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Spinel-type FeNi<sub>2</sub>S<sub>4</sub> with rich sulfur vacancies grown on reduced graphene oxide toward enhanced supercapacitive performance
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Citations
58
References
2021
Year
Materials ScienceRich Sulfur VacanciesEngineeringElectrode-electrolyte InterfaceNanomaterialsReduced GrapheneHybrid CapacitorApplied PhysicsElectrochemical InterfaceGrapheneEnhanced Supercapacitive PerformanceSupercapacitorSuperior Specific CapacitanceChemistryFunctional MaterialsElectrode Reaction MechanismElectrochemistry
Due to the coexistence of rich sulfur vacancies and rGO, the r-FeNi<sub>2</sub>S<sub>4</sub>-rGO electrode shows a superior specific capacitance.
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