Facile fabrication of flower-like binary metal oxide as a potential electrode material for high-performance hybrid supercapacitors

Developing efficient electrode material with rational design and structure remains a crucial and great challenge for the significant improvement of high-performance hybrid supercapacitors (HSCs). Particularly, the performance of the HSCs can be largely enhanced by designing the battery-type Faradaic material with well-defined morphology and defective engineering. Here, a facile and effective strategy is utilized to develop oxygen deficient flower-like three-dimensional NiMoO4-delta (O-d-NMO) nanomaterial via hydrothermal process and following thermal-treatment under an inert-gas atmosphere. The presence of oxygen deficiency in the O-d-NMO is evaluated utilizing various spectroscopy techniques by comparing the pristine NiMoO4 (P-NMO) heat treated under an ambient atmosphere. The electrochemical studies indicate that the oxygen defect sites in the O-d-NMO electrode have a considerable role in the betterment of supercapacitive performances. Hence, the O-d-NMO electrode provides a large specific capacity of 789 mA h g(-1) at 1 A g(-1) with an excellent rate capability than the P-NMO (579 mA h g(-1)). Besides, the fabricated HSC based on O-d-NMO flower and activated carbon as the positive and negative electrodes, delivers a specific capacitance as high as 153 F g(-1) and accomplishes a large energy density (47.76 W h kg(-1)) and power density (51.69 kW kg(-1)) with improved long-term stability.

Automated summary

Developing efficient electrode materials is crucial for improving high-performance hybrid supercapacitors. In this study, oxygen deficient flower-like three-dimensional NiMoO4-delta (O-d-NMO) nanomaterial is synthesized and demonstrated to have better supercapacitive performances due to the presence of oxygen defect sites.