Flexible supercapacitor electrodes based on real metal-like cellulose papers

• Published in: Nature communications Vol. 8; no. 1; pp. 536 - 11
• Main Authors: Ko, Yongmin, Kwon, Minseong, Bae, Wan Ki, Lee, Byeongyong, Lee, Seung Woo, Cho, Jinhan
• Format: Journal Article
• Language: English
• Published: England Nature Publishing Group 14.09.2017; Nature Publishing Group UK; Nature Portfolio
• Subjects: Accumulators; Assembly; Capacitance; Cellulose; Charge materials; Collectors; Contact resistance; Electrodes; Energy storage; Flux density; Implantation; Ligands; Maximum power; Metals; Nanoparticles; Organic chemistry; Supercapacitors; Wearable technology
• ISSN: 2041-1723; 2041-1723
• DOI: 10.1038/s41467-017-00550-3

The effective implantation of conductive and charge storage materials into flexible frames has been strongly demanded for the development of flexible supercapacitors. Here, we introduce metallic cellulose paper-based supercapacitor electrodes with excellent energy storage performance by minimizing the contact resistance between neighboring metal and/or metal oxide nanoparticles using an assembly approach, called ligand-mediated layer-by-layer assembly. This approach can convert the insulating paper to the highly porous metallic paper with large surface areas that can function as current collectors and nanoparticle reservoirs for supercapacitor electrodes. Moreover, we demonstrate that the alternating structure design of the metal and pseudocapacitive nanoparticles on the metallic papers can remarkably increase the areal capacitance and rate capability with a notable decrease in the internal resistance. The maximum power and energy density of the metallic paper-based supercapacitors are estimated to be 15.1 mW cm and 267.3 μWh cm , respectively, substantially outperforming the performance of conventional paper or textile-type supercapacitors.With ligand-mediated layer-by-layer assembly between metal nanoparticles and small organic molecules, the authors prepare metallic paper electrodes for supercapacitors with high power and energy densities. This approach could be extended to various electrodes for portable/wearable electronics.