Superior rate capability of high mass loading supercapacitors fabricated with carbon recovered from methane cracking
Date published
2023-07-27
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MDPI
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Article
ISSN
2304-6740
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Citation
Baptista J, Shacklock J, Shaban M, et al., (2023) Superior rate capability of high mass loading supercapacitors fabricated with carbon recovered from methane cracking, Inorganics, Volume 11, Issue 8, July 2023, Article Number 316
Abstract
High mass loading (ca. 30 mg/cm2) electrodes were prepared with carbon recovered from catalytic methane cracking (MC). As-fabricated supercapacitors displayed 74% of capacitance retention from 6 mA/cm2 to 60 mA/cm2 and a Ragone plot’s slope of −7 Wh/kW (compared to 42% and −31 Wh/kW, respectively, for high mass loading devices fabricated with commercial carbon). The high-rate capability of the MC-recovered carbon is attributed to the presence of carbon black and carbon nanotubes produced during the reaction, which likely increased the electronic and ionic conductivity within the electrode. These results suggest that the by-product of this hydrogen generation route might be a suitable active material for supercapacitors.
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Github
Keywords
supercapacitors, carbon nanotubes, porous nanocarbon-based electrodes, methane cracking, rate capability, electrochemistry, electrochemical impedance spectroscopy
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Attribution 4.0 International
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Funder/s
Engineering and Physical Sciences Research Council (EPSRC): EP/R023662/1; EP/S023909/1