Abstract
Ionic liquid (IL) electrolytes have enormous potential for the development of high energy density supercapacitors (SCs) owing to their wide potential windows, but ILs are plagued by sluggish ionic diffusion due to their high viscosity and large ion size. Exploiting superwettable electrodes possessing high compatibility with IL electrolytes remains challenging. Inspired by the biological characteristics observed in nature, a unique film electrode with a Monstera leaf-like nanostructure is synthesized and used to overcome the aforementioned bottleneck. Similar to the pores in Monstera leaves that allow the permeation of air and water vapor, the film electrode is based on porous g-C3N4 nanosheets (~1 nm thick) as ion-accessible “highway” channels, allowing ultrafast diffusion of IL ions. The film exhibits a high diffusion coefficient (3.68 × 10−10 m2 s−1), low activation energy (0.078 mJ mol−1) and extraordinary wettability in the IL electrolyte, indicating its superior IL ion dynamics. As a proof of concept, flexible ionogel SCs (FISCs) with tailorability and editability are fabricated, which exhibit a high energy density (10.5 mWh cm−3), high-power density, remarkable rate capability, and long-term durability, outperforming previously reported FISCs. Importantly, these FISCs can be effectively charged by harvesting sustainable power sources, particularly the rarely studied wind power, for practical applications.
Highlights
With the rapid development of portable and wearable electronics, developing lightweight, reliable, and flexible energy-storage devices is a critical challenge[1,2]
Because the energy density of SCs is proportional to the square of the working voltage, the amount of energy stored in SCs mainly depends on the stability of the applied electrolyte over the Correspondence: Chao Yan or Zhenyu Sun or Jong-Hyun Ahn 1School of Materials Science and Engineering, Jiangsu University of Science and Technology, 212003 Zhenjiang, China 2State Key Laboratory of Organic-Inorganic Composites, Beijing University of Chemical Technology, 100029 Beijing, China Full list of author information is available at the end of the article
The large ion size and high viscosity of ionic liquid (IL) electrolytes always lead to poor compatibility with the electrode, resulting in sluggish ionic diffusion, which affects the electrochemical kinetics of FISCs10,11
Summary
With the rapid development of portable and wearable electronics, developing lightweight, reliable, and flexible energy-storage devices is a critical challenge[1,2]. Because the energy density of SCs is proportional to the square of the working voltage, the amount of energy stored in SCs mainly depends on the stability of the applied electrolyte over the voltage range[6,7,8]. Owing to their wide potential window (>2.5 V), nonvolatility, nonflammability, and high thermal/chemical stability, flexible ionogel SCs (FISCs) based on ionic liquid (IL) electrolytes have great promise for achieving a high energy density but are safe and have a wide usage temperature range in portable and wearable electronics[9].
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