Applications for CO 2 ‐Activated Carbon Monoliths: II . EDLC Electrodes

The use of high‐density carbon monoliths ( CM ) for preparing supercapacitor electrodes is analyzed. The starting CM s, produced by ATMI Co, were treated as follows: (1) under a N 2 flow at 1073 K to modify the carbon surface chemistry and (2) activated with CO 2 at the same temperature, using diffe...

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Veröffentlicht in:International journal of applied ceramic technology 2015-11, Vol.12 (S3)
Hauptverfasser: Kunowsky, Mirko, Linares‐Solano, Ángel, Garcia‐Gomez, Alejandra, Barranco, Violeta, Rojo, José María, Carruthers, James Donald
Format: Artikel
Sprache:eng
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Zusammenfassung:The use of high‐density carbon monoliths ( CM ) for preparing supercapacitor electrodes is analyzed. The starting CM s, produced by ATMI Co, were treated as follows: (1) under a N 2 flow at 1073 K to modify the carbon surface chemistry and (2) activated with CO 2 at the same temperature, using different activation times, to increase their porosity. Electrochemical measurements were performed on disks of 1–2 mm thickness which are suitable for direct use in practical devices. Two‐ and three‐electrode cells were used with 2 M H 2 SO 4 solution as electrolyte. The contents of surface oxygen groups were measured by temperature‐programmed desorption ( TPD ) and X‐ray photoelectron spectroscopy ( XPS ). The porosity of the starting monolith is increased by physical activation with CO 2 , the BET surface area increasing from 957 to 1684 m 2 /g. Upon heat treatments, both, the high density (1.2 g/cm 3 ), as well as the high amount of surface oxygen groups (2411 μmol CO/g) of the starting monolith are reduced; however, the densities of the treated monoliths remain higher than values reported for other porous carbon monoliths. The performance of the CM s as supercapacitor electrodes show as follows: (1) high specific and exceptionally high volumetric capacitances (up to 292 F/g and 342 F/cm 3 , respectively) due to their appropriate structure, porosity, and density, (2) a long and stable cyclability, (3) a decrease of power density with disk thickness, and (4) a decrease of pseudocapacitance with activation time.
ISSN:1546-542X
1744-7402
DOI:10.1111/ijac.12360