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Study of Nanoporous Carbon Fabrics for Rechargeable Energy Storage Capacitors

Published online by Cambridge University Press:  21 May 2018

Sergey M. Karabanov*
Affiliation:
Ryazan State Radio Engineering University, 59/1 Gagarina St., Ryazan 390005, Russia
Vladimir G. Litvinov
Affiliation:
Ryazan State Radio Engineering University, 59/1 Gagarina St., Ryazan 390005, Russia
Nikolay B. Rybin
Affiliation:
Ryazan State Radio Engineering University, 59/1 Gagarina St., Ryazan 390005, Russia
Evgeniy V. Slivkin
Affiliation:
Ryazan State Radio Engineering University, 59/1 Gagarina St., Ryazan 390005, Russia
Vladimir V. Oreshkin
Affiliation:
Ryazan State Radio Engineering University, 59/1 Gagarina St., Ryazan 390005, Russia
Dmitriy V. Suvorov
Affiliation:
Ryazan State Radio Engineering University, 59/1 Gagarina St., Ryazan 390005, Russia
*
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Abstract

In this work, we present the results of investigation of the nanoporous material – carbon fabrics, which is used as electrodes in rechargeable energy storage capacitors (ultracapacitors). The impurity composition in the fabrics, the influence of thermal annealing conditions on the impurity concentration is studied. The performed studies resulted in determination of the investigated carbon material structure, determination of impurity composition of carbon material and change of impurity content depending on thermal treatment in vacuum at different temperatures and time intervals. The optimum temperature range for the treatment of carbon fabrics in vacuum that is important for its application in energy storage devices is found.

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Articles
Copyright
Copyright © Materials Research Society 2018 

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References

REFERENCES

Conway, B., Electrochemical supercapacitors. (Klawer Academic Plenum Publishers, New York, 1999), p. 698.CrossRefGoogle Scholar
Ultracapacitors (2006). Available at:http://www.hybridcars.com/ultracapacitors (accessed 01 March 2018)Google Scholar
Karabanov, S.M. and Kukhmistrov, Y.V., Electronnaya promyshlennost, 6, 72, (1994).Google Scholar
Karabanov, Sergey, Suvorov, Dmitriy, Karabanov, Andrey, Tarabrin, Dmitry, Slivkin, Evgeniy and Gololobov, Gennadiy, in Mathematical Modeling of Stand-alone PV Power Systems with the Use of Hybrid Energy Storage Units based on Ultra Capacitor, (31st Europ. Photovolt. Solar Energy Conf. Proc., Hamburg, Germany, 2015) pp. 23742377.Google Scholar
Karabanov, S.M., Suvorov, D.V., Kukhmistrov, Y.V. and Slivkin, E.V., in The Study of PV modules with electric double layer capacitors integrated in their structure, (28th Europ. Photovolt. Solar Energy Conf. Proc., Paris, France, 2013) pp. 511516.Google Scholar
Rychagov, A.Yu., Volfkovich, Yu.M., Elektrokhimicheskaya Energetika, 12 (4), 167 (2012).Google Scholar
Vervikishko, D.E., Correlation between the nanoporous carbon materials structure and functional characteristics of ultracapacitors on their basis, Thesis, JIHT RAS, Moscow, 2014.Google Scholar
Mikhalin, A.A., Study of capacitive and electrochemical properties of electrodes based on finely dispersed carbon in relation to their use in ultracapacitors and for capacitive water deionization, Thesis, IPCE RAS, Moscow, 2013.Google Scholar
Karabanov, S.M., Litvinov, V.G. and Karabanov, A.S., MRS Advances, 54 (2), 3255, (2017).CrossRefGoogle Scholar