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“Wrapped” nitrogen-doped defective reduced graphene oxide (ND-rGO): A virtual electron bed for enhanced supercapacitive charge storage in stepped-surfaced-NiCo2O4/ND-rGO||Bi2O3 asymmetric device

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Abstract In the context of low impedance electron transfer in electrochemical charge storage devices, stepped-surfaced solids are important because they provide low work function and suitable interface for electron transfer.… Click to show full abstract

Abstract In the context of low impedance electron transfer in electrochemical charge storage devices, stepped-surfaced solids are important because they provide low work function and suitable interface for electron transfer. Contextually, in this work, for the first time a carbonate-mediated synthesis method is adopted to fabricate severely stepped-surfaced porous NiCo2O4. Further, N-doped defective rGO (ND-rGO) wrapped NiCo2O4 is assembled and the electron bedding effect of ND-rGO on the supercapacitive charge storage performance of NiCo2O4 is thoroughly studied. Physicochemical studies authenticate restricted crystal growth of NiCo2O4 on ND-rGO and chemical bonding between ND-rGO and NiCo2O4. Detailed electrochemical studies using cyclic voltammetry (CV), galvanostatic charge-discharge (GCD) and electrochemical impedance spectroscopy (EIS) techniques show redox-mediated charge storage in NiCo2O4 and ND-rGO-induced enhanced high-rate supercapacitive charge storage and lower charge-transfer resistance, equivalent series resistance and Warburg resistance in NiCo2O4/ND-rGO heteronanocomposite. Further, for the first time, Bi2O3 was used as a super compatible negative electrode material to fabricate asymmetric supercapacitor (ASC) devices based on pristine NiCo2O4 and NiCo2O4/ND-rGO, and in depth electrochemical characterizations show redox-capacitive charge storage behaviour in both the devices. Further, the NiCo2O4/ND-rGO||Bi2O3 demonstrates 2-times more areal capacitance at extreme rate condition, lower iR drop, very low charge transfer resistance, solution resistance and ion-diffusion resistance as compared to NiCo2O4||Bi2O3 ASC device. The NiCo2O4/ND-rGO||Bi2O3 ASC device also retains a very high 93.1% of specific capacitance after 5000 GCD cycles at an extreme applied current density of 32 mA cm−2. Further, the NiCo2O4/ND-rGO||Bi2O3 offers twice the energy density as compared to NiCo2O4||Bi2O3 ASC device, under elevated power density up to ∼10,000 Wh kg−1. The enhanced supercapacitive performance of NiCo2O4/ND-rGO||Bi2O3 ASC device is ascribed to electron bedding effect of wrapped ND-rGO which provides a continuous conducting network, and ND-rGO induced improved wettability, activated NiCo2O4|ND-rGO interface, and excellent electromechanical properties of NiCo2O4/ND-rGO heteronanocomposite.

Keywords: bi2o3; nico2o4 rgo; rgo; charge storage

Journal Title: Electrochimica Acta
Year Published: 2020

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