Formation of the Active Surface of the FeCrAl Catalyst under Electric Current Heating Conditions

An effect of heat treatment conditions (convective, resistive heating) was considered on the composition and surface properties of FeCrAl wire used as a catalyst for methane decomposition. It was shown that resistive heating is a more effective method for activating the FeCrAl wire catalyst, which p...

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Veröffentlicht in:Russian journal of applied chemistry 2020-12, Vol.93 (12), p.1920-1925
Hauptverfasser: Raiskaya, E. A., Belskaya, O. B., Ivlev, K. E.
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container_issue 12
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container_title Russian journal of applied chemistry
container_volume 93
creator Raiskaya, E. A.
Belskaya, O. B.
Ivlev, K. E.
description An effect of heat treatment conditions (convective, resistive heating) was considered on the composition and surface properties of FeCrAl wire used as a catalyst for methane decomposition. It was shown that resistive heating is a more effective method for activating the FeCrAl wire catalyst, which promotes the dispersion of iron-enriched particles over the surface and an increase in the number of catalytically active sites. The use of resistive heating allows reducing the catalyst pretreatment time to 10 min.
doi_str_mv 10.1134/S1070427220120149
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subjects Catalysis
Catalysts
Chemistry
Chemistry and Materials Science
Chemistry/Food Science
Heat treatment
Industrial Chemistry/Chemical Engineering
Pretreatment
Surface properties
Wire
title Formation of the Active Surface of the FeCrAl Catalyst under Electric Current Heating Conditions
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