Published on April 2020 | Material science, electrochemistry, electrocatalysis
Transparent flexible supercapacitors are crucial for the progress of high-tech modern transparent wearable electronic gadgets. Thus, fabricating high opto-electrochemical performance electrodes is crucial for the development of high energy density transparent flexible supercapacitors. Herein, direct growth of battery-type ternary nickel-cobalt sulfide (NiCoS) nanosheets on Cu@Ni NFs network transparent electrode forming a seamless Cu@Ni@NiCoS NFs core-shell electrode structured is reported to boost the energy density of transparent supercapacitors. The core Cu@Ni nanofibers network electrode exhibited both excellent electro-optical performance (sheet resistance~12.19 /sq at ~89 % transmittance) and high mechanical flexibility. NiCoS thin nanosheets shell offer high porosity, abundant active sites, and large electrode-electrolyte contact area, thus facilitating the fast diffusion of electrolytes into active materials. The Cu@Ni@NiCoS NFs core-shell electrode demonstrated remarkable high opto-electrochemical performance (transparency of ~76.83%, an areal capacity of 6.94 A h/cm2, and high rate capability) and excellent mechanical properties. Finally, a transparent flexible symmetric supercapacitor device (SSC device) assembled by employing Cu@Ni@NiCoS NFs as both electrodes demonstrates an outstanding energy density of 0.48 W h/cm2 at a power density of 11.15 W/cm2 with device transparency of ~65 %.
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