Wettability and sp2/sp3 ratio effects on supercapacitor performance of N-doped hydrogenated amorphous Carbon Nanofoam
| Title: | Wettability and sp2/sp3 ratio effects on supercapacitor performance of N-doped hydrogenated amorphous Carbon Nanofoam |
|---|---|
| Authors: | Ghosh, Subrata, Pagani, Giacomo, Macrelli, Andrea, Calloni, Alberto, Bussetti, Gianlorenzo, Lucotti, Andrea, Tommasini, Matteo, Suriano, Raffaella, Russo, Valeria, Jastrzkebska, Agnieszka M., Casiraghi, Cinzia, Bassi, Andrea Li, Casari, Carlo S. |
| Publication Year: | 2025 |
| Collection: | Condensed Matter Physics (Other) |
| Subject Terms: | Condensed Matter - Materials Science, Physics - Applied Physics |
| More Details: | Pulsed laser-deposited amorphous carbon nanofoams could be a potential candidate for electrochemical energy storage applications due to their properties such as ultralightweight, huge volumetric void fractions, and co-existence of sp, sp2 and sp3 carbon hybridization. It is known that the charge-storage of carbon nanostructures containing disordered sp2-domains is determined by the wettability, surface area, and porosity of carbon nanostructures. However, their charge-storage performance is limited to the areal capacitance of the order of a few mF/cm2. We enhanced the supercapacitor performance of nitrogen-doped amorphous carbon nanofoam by engineering its wettability and sp2-C/sp3-C ratio by vacuum annealing. The specific capacitance was enhanced around fifty times and the widened voltage of the device increased from 0.8 to 1.1 V compared to as-grown nanofoam. In addition, we examined for the first time the initial increase in specific capacitance of the aqueous symmetric supercapacitor with respect to the scan rate, employing in-situ measurements coupling Raman spectroscopy and electrochemistry. We attribute this effect, although observed in previous literatures but unexplained, to the electrochemical activation induced by structural changes during the charge storage performance. This optimization of pulsed laser-deposited carbon nanofoam may open an avenue for fabricating lightweight and porous nanostructures for advanced macro-to-micro-supercapacitor devices. Comment: 23 Pages including supporting materials, 10 Figures, 6 supporting figures, 4 supporting tables |
| Document Type: | Working Paper |
| Access URL: | http://arxiv.org/abs/2503.13264 |
| Accession Number: | edsarx.2503.13264 |
| Database: | arXiv |
| Description not available. |