Metallic telluride-based nanomaterials have garnered appreciable curiosity as cathode electrode supplies for supercapacitors as a result of their plentiful redox-active websites, sturdy chemical stability, and glorious electrical conductivity. On this work, these advantageous properties are additional enhanced by hybridizing NiTe2-FeTe2 hole nanorods with diminished graphene oxide (RGO), leading to an NFT@RGO composite appropriate for supercapacitor functions. The hole rod-like construction promotes environment friendly ion diffusion and maximizes the publicity of electroactive websites, whereas the RGO community boosts conductivity and mitigates nanomaterial agglomeration, thus preserving structural integrity and prolonging materials sturdiness. The NFT@RGO-based electrode reveals a notable capability of 1388.5 C/g at 1 A/g, with 93.82% capability retention after 10000 cycles. This outstanding efficiency arises from the synergistic contributions of the Ni and Fe metals, the electrically conductive Te component, the RGO framework, and the distinctive hole morphology of the nanorods. Moreover, a hybrid system using activated carbon (AC) because the anode (NFT@RGO//AC) achieves an vitality density of 61.11 Wh/kg and retains 89.85% of its capability over 10000 cycles, underscoring the promise of NFT@RGO for next-generation supercapacitors. These findings place the designed nanomaterial as a superb candidate for high-performance vitality storage programs.
