Abstract
The design of high‐energy‐density device electrodes has garnered significant attention but remains a challenging task. This study proposes an effective strategy for constructing a ternary composite material (WO3/V2O5/CC‐n, n = 1, 2, 3). Utilizing V2O5 as a precursor, a highly efficient electrode (WO3/V2O5/CC‐2) with a 3D nanowire structure is designed. The results demonstrate that the WO3/V2O5/CC‐2 electrode exhibits enhanced capacitive performance with a specific capacity (495.6 F g−1 at 1 A g−1) and remarkable electrochemical stability even after 5000 cycles. Furthermore, kinetics analysis reveals that the charge stored on the electrode is primarily attributed to surface capacitive effects and diffusion‐controlled insertion processes. This facile preparation method of the WO3/V2O5/CC‐2 electrode derived from WO3 and V2O5 holds excellent potential for constructing new‐generation electrochemical energy‐storage devices with superb capacitance performance.
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