Electrostatic self-assembly of citrus based carbon nanosheets and MXene: Flexible film electrodes and patterned interdigital electrodes for all-solid supercapacitors

Lightweight, flexible, patterned, and environmentally friendly electronic devices should be developed to meet the requirements of future high-tech systems such as smart wearables, internet of things and smart cities. Herein, MXene and citrus-based carbon nanosheet composites (MX/CCNS) with excellent energy storage properties and cyclic stability are prepared via electrostatic self-assembly. MX/CCNS can be easily fabricated as flexible self-supporting electrodes by vacuum filtration and configured as ink for screen printing and large-scale contin-uous preparation of patterned electrodes. MX/CCNS film electrodes have high specific capacitance (up to 1825.6 mF/cm2 at a current density of 5 mA/cm2) and high cycling stability (99.82% capacity retention after 10,000 cycles). Meanwhile, MX/CCNS can be assembled into flexible all-solid-state and interdigital devices, all exhib-iting excellent capacitive performance. The capacitance (114.9 mF/cm2) and energy density (12.9 mu Wh/cm2) of the printed interdigital supercapacitors are competitive among MXene-based devices. MX/CCNS has great application prospects in scalable and sustainable production of next-generation wearable intelligent electronics.

Automated summary

To meet the demands of future high-tech systems, such as smart wearables, internet of things, and smart cities, lightweight, flexible, patterned, and environmentally friendly electronic devices need to be developed. MXene and citrus-based carbon nanosheet composites (MX/CCNS) are prepared via electrostatic self-assembly, showing excellent energy storage properties and cyclic stability. MX/CCNS can be easily fabricated into flexible self-supporting electrodes and ink for screen printing and large-scale continuous preparation of patterned electrodes. They exhibit high specific capacitance and cycling stability, making them ideal for scalable and sustainable production of next-generation wearable intelligent electronics.