Impact of oxygen-defects induced electrochemical properties of three-dimensional flower-like CoMoO4 nanoarchitecture for supercapacitor applications

The rational strategy to design the well-ordered morphology of the metal oxides with defective engineering and tailoring them into specific electrode fabrication can significantly improve their electrochemical properties for high-performance energy storage systems. Herein, we adopted an effective strategy to introduce oxygen-defect into the well-ordered three-dimensional flower-like CoMoO4 nanoarchitecture. The Co-Mo precursor leads to the introduction of oxygen-defects into the CoMoO4 (rCMO) nanoarchitecture during the heat-treatment under an oxygen-controlled environment (argon). The oxygen-defects in the material could facilitate abundant electroactive sites and intrinsically enhance the conductivity and supercapacitor performance. The oxygen-defect CoMoO4 (rCMO) exhibits a specific capacity of 531 mAh g(-1) at a current density of 1 A g(-1) compared to the pristine CoMoO4 (CMO; ambient atmosphere) of 322 mAh g(-1) under the same current density. Meanwhile, the fabricated hybrid supercapacitor (HSC) of rCMO//AC provides a maximum specific capacitance of 159 F g(-1). Further, it distributes an energy density of 49.87 Wh kg(-1) at the power density of 845.45 W kg(-1) with an excellent cyclic life of similar to 91.03% over 10 000 cycles.

Automated summary

Introducing oxygen defects into the well-ordered three-dimensional flower-like CoMoO4 nanoarchitecture through defect engineering can significantly enhance its electrochemical properties, making it suitable for high-performance energy storage systems.