Document Type
Article
Publication Date
1-16-2022
School
Polymer Science and Engineering
Abstract
Micro-supercapacitors are poised to serve as on-chip power sources for electronics. However, the challenge to simultaneously increase their power, energy, and lifetime demands new material combinations beyond current carbon-based systems. Here, we demonstrate that electro-deposition of an open-shell conjugated polymer with reduced graphene oxide achieves electrodes with capacitance up to 186 mF cm−2 (372 F cm−3). The extended delocalization within the open-shell polymer stabilizes redox states and facilitates a 3 V wide potential window, while the hierarchical electrode structure promotes ultrafast kinetics. The micro-supercapacitor shows a high power density of 227 mW cm−2 with an energy density of 10.5 μWh cm−2 and stability of 84% capacitance retention after 11,000 cycles. These attributes allow operation at 120 Hz for fast charging and alternating current (AC) line filtering applications, which may be suitable to replace bulky electrolytic capacitors or serve as high-endurance energy storage for wireless electronics.
Publication Title
Cell Reports Physical Science
Volume
3
Issue
3
Recommended Citation
Yao, L.,
Eedugurala, N.,
Mahalingavelar, P.,
Adams, D. J.,
Wang, K.,
Mayer, K. S.,
Azoulay, J. D.,
Ng, T. N.
(2022). Ultrafast High-Energy Micro-Supercapacitors Based On Open-Shell Polymer-Graphene Composites. Cell Reports Physical Science, 3(3).
Available at: https://aquila.usm.edu/fac_pubs/20593