Study of cobalt-iron mixed oxides and catalytic behavior for decomposition of hydrogen peroxide

•Pure Co-Fe spinel phases are obtained at low temperature (400 °C) by citrate method.•Relationship between catalytic activity and surface properties is observed.•Catalytic activity is related to the Co2+ sites and the surface oxygen vacancies.•Co-Fe mixed oxides are more resistant to leaching than s...

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Bibliographic Details
Published in:Molecular catalysis 2022-09, Vol.530, p.112639, Article 112639
Main Authors: Gómez-Largo, Paula M., Miranda, Carlos D., Villagrán-Olivares, Alejandra C., López, Carlos A., Barbero, Bibiana P.
Format: Article
Language:English
Subjects:
Catalyst
Cobalt ferrite
Hydrogen peroxide decomposition
Iron cobaltite
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Summary:•Pure Co-Fe spinel phases are obtained at low temperature (400 °C) by citrate method.•Relationship between catalytic activity and surface properties is observed.•Catalytic activity is related to the Co2+ sites and the surface oxygen vacancies.•Co-Fe mixed oxides are more resistant to leaching than single oxides of Co or Fe. This work reports a comprehensive study on the iron incorporation in the lattice of cobalt-iron mixed oxides and its effect on physicochemical and catalytic properties. Catalysts with different Co:Fe molar ratio (Co:Fe = 2:1, 1:1, and 1:2) and different synthesis temperatures (400, 500, and 600 °C) were prepared by the citrate method. The catalysts were characterized by several techniques (TGA, DSC, FAAS, SEM-EDS, XPS, FTIR, XRD, Rietveld refinement, nitrogen sorptometry, and TPR) and the catalytic behavior was evaluated in terms of the H2O2 decomposition. The characterization results showed that Co-Fe mixed oxides with spinel structure were obtained. For the catalysts calcined at 400 °C, the iron incorporation in the Co3O4 lattice increased the unit cell size, induced the spinel partial inversion, increased the specific area, and affected the reducibility. The Co-Fe mixed oxides were slightly less active than Co3O4, but they showed greater leaching resistance under reaction conditions. The increase of the calcination temperature caused strong sintering and at 600 °C, CoFe2O4 segregated. The catalytic activity decreased with the increasing of calcination temperature and the leaching resistance did not improve. Thus, the catalyst with Co:Fe = 2:1 molar ratio calcined at 400 °C showed the best overall performance for H2O2 decomposition. [Display omitted]
ISSN:2468-8231
2468-8231
DOI:10.1016/j.mcat.2022.112639