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Long-Time Stability of Catalytic Coatings on the Basis of Nanoporous TiO2 under the Influence of Corona Discharge Plasma in Air

Published online by Cambridge University Press:  26 January 2016

Sergey Karabanov*
Affiliation:
Ryazan State Radio Engineering University 59/1 Gagarina St., Ryazan 390005, Russia
Dmitry Suvorov
Affiliation:
Ryazan State Radio Engineering University 59/1 Gagarina St., Ryazan 390005, Russia
Gennady Gololobov
Affiliation:
Ryazan State Radio Engineering University 59/1 Gagarina St., Ryazan 390005, Russia
Maria Klyagina
Affiliation:
Ryazan State Radio Engineering University 59/1 Gagarina St., Ryazan 390005, Russia
Vladimir Vasilyev
Affiliation:
Ryazan State Radio Engineering University 59/1 Gagarina St., Ryazan 390005, Russia
Nikolay Vereshchagin
Affiliation:
Ryazan State Radio Engineering University 59/1 Gagarina St., Ryazan 390005, Russia
Evgeny Slivkin
Affiliation:
Ryazan State Radio Engineering University 59/1 Gagarina St., Ryazan 390005, Russia
*
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Abstract

The present paper contains results of the experimental researches of structure properties of the catalytic coating based on the nanoporous TiO2 film affected by corona-discharge plasma in air atmosphere under atmospheric pressure in the test system of needle-plane electrodes. Coating of the plate electrode was found to influence insignificantly on the discharge current-voltage characteristic, however if there is a coating on the plane electrode surface, an offset is observed towards lower currents under constant voltage at the gap. Obtained data on the surface morphology change shows that under negative corona erosion of the nanoporous TiO2 coating surface is practically absent and under positive corona, decrease of the coating thickness is observed.

Type
Articles
Copyright
Copyright © Materials Research Society 2016 

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References

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