Flexible And Transparent Capacitors Based On Gel-Type Natural Polymers

In this work, we study the capacitive properties of gel-type natural abundant polymers without any dopants, mainly commercial gelatin and agar in deionized water. Here, we propose a facile fabrication of flexible, transparent, and planar electrolytic capacitors using these gel-type and indium tin oxide thin films as electrodes deposited on poly(ethylene terephthalate) substrates. Through cyclic voltammetry and galvanostatic charge-discharge techniques, we found that the devices show a specific capacitance in the order of the millifarads per gram, a specific power of similar to 10 mW cm(-2), which is sufficient to active low-power devices, and a life cycle with nearly 100% efficiency after 1,000 cycles. We found that we do not need to add dopants that improve the ionic conductivity of the natural polyelectrolytes to obtain capacitances within the millifarads per gram. The flexibility of the capacitors was demonstrated by bending them, after which they exhibited the same electrochemical performance as the unbent devices. The optical transparency of the capacitors was measured by UV-V is spectroscopy showing a high transmittance in the visible region.