Flexible nickel disulfide nanoparticles-anchored carbon nanofiber hybrid mat as a flexible binder-free cathode for solid-state asymmetric supercapacitors
Surbhi Anand, Md. Wasi Ahmad, Atiya Fatima, Anupam Kumar, Arvind Bharadwaj, Duck‐Joo Yang, Arup Choudhury
Abstract
Abstract Nickel disulfide nanoparticles (NiS 2 NPs)-anchored carbon nanofibers (NiS 2 NPs@CNF) hybrid mats were fabricated via the sequential process of stabilization and carbonization of electrospun polyacrylonitrile-based fibers followed by hydrothermal growth of NiS 2 NPs on the porous surface of CNFs. The vertical growth of NiS 2 NPs on entire surfaces of porous CNFs appeared in the SEM images of hybrid mat. The hierarchical NiS 2 NPs@CNF core–shell hybrid nanofibers with 3D interconnected network architecture can endow continuous channels for easy and rapid ionic diffusion to access the electroactive NiS 2 NPs. The conductive and interconnected CNF core could facilitate electron transfer to the NiS 2 shell. Moreover, the porous CNF as a buffering matrix can resist volumetric deformation during the long-term charge–discharge process. The NiS 2 NPs@CNF electrode can yield high specific capacitance (916.3 F g −1 at 0.5 A g −1 ) and reveal excellent cycling performances. The solid-state asymmetric supercapacitor (ASC) was fabricated with NiS 2 NPs@CNF mat as a binder-free positive electrode and activated carbon cloth as a negative electrode. As-assembled ASC not only produce high specific capacitance (364.8 F g −1 at 0.5 A g −1 ) but also exhibit excellent cycling stability (∼92.8% after 5000 cycles). The ASC delivered a remarkably high energy density of 129.7 Wh kg −1 at a power density of 610 W kg −1 . These encouraging results could make this NiS 2 NPs@CNF hybrid mat a good choice of cathode material for the fabrication of flexible solid-state ASC for various flexible/wearable electronics.