Unique multi-phase Co/Fe/CoFe2O4 by water–gas shift reaction, CO oxidation and enhanced supercapacitor performances

[Display omitted] •Unique multi-phase Co/Fe/CoFe2O4 was induced by water–gas shift reaction.•Co3O4/CoFe2O4 structures were prepared by thermal annealing and CO oxidation.•Co-rich Co/Fe/CoFe2O4 showed higher WGS reaction activity than the Fe-rich sample.•Co-rich Co/Fe/CoFe2O4 showed 4–20× superior su...

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Bibliographic Details
Published in:Journal of industrial and engineering chemistry (Seoul, Korea) 2016, 43(0), , pp.69-77
Main Authors: Lee, Seungwon, Kang, Jung-Soo, Leung, Kam Tong, Lee, Wondoo, Kim, Dongyun, Han, Seungyoon, Yoo, Wonjun, Yoon, Hee Jung, Nam, Kyusuk, Sohn, Youngku
Format: Article
Language:English
Subjects:
CO oxidation
Co/Fe/CoFe2O4
Multi crystal-phase
Supercapacitor
Water–gas shift reaction
화학공학
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Summary:[Display omitted] •Unique multi-phase Co/Fe/CoFe2O4 was induced by water–gas shift reaction.•Co3O4/CoFe2O4 structures were prepared by thermal annealing and CO oxidation.•Co-rich Co/Fe/CoFe2O4 showed higher WGS reaction activity than the Fe-rich sample.•Co-rich Co/Fe/CoFe2O4 showed 4–20× superior supercapacitor performance than the Fe-rich sample and Co–Fe oxides.•Fe-rich Co/Fe/CoFe2O4 showed 3× higher magnetization than the Co-rich sample. The design of bimetallic Co–Fe oxide structures has attracted considerable research attention in magnetic, electrochemical and catalyst materials. This paper reports the production of unique multi crystal-phase Co/Fe/CoFe2O4 by the water–gas shift reaction. The metallic Co and Fe lower the interfacial resistance, resulting in facial charge/ion transport and a dramatic enhancement in the specific capacitance. The multi-phase Co–Fe oxide structures are also found to be applicable to the water–gas shift reaction and CO oxidation. The unique water–gas shift reaction-induced method can be very useful to the design of highly efficient new multi crystal-phase nanostructures.
ISSN:1226-086X
1876-794X
DOI:10.1016/j.jiec.2016.07.049