Direct formation of LaFeO3/MCM−41 nanocomposite catalysts and their catalytic reactivity for conversion of isopropanol

Direct formation of 3–30% (w/w) LaFeO3/MCM−41, nanocomposite catalysts were performed by a sol−gel process, followed by calcination at 550 and 750 °C. The nanocomposites were characterized through different techniques including LAXRD, WAXRD, EDX, simultaneous TG−DTA, ATR−FTIR, nitrogen adsorption/de...

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Bibliographic Details
Published in:Materials chemistry and physics 2020-11, Vol.254, p.123412, Article 123412
Main Authors: Khalil, Kamal M.S., Elhamdy, Walaa A., Said, Abd-El-Aziz A.
Format: Article
Language:English
Subjects:
Acetone
Catalysts
Catalytic activity
Catalytic converters
Conversion
Dehydration
Dehydrogenation
Differential thermal analysis
Ferrites
Isopropanol
Lanthanum compounds
Mesoporous
Nanocomposites
Nanomaterials
Oxidation
Perovskite
Roasting
Selectivity
Sol-gel processes
Surface stability
Thermal stability
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Summary:Direct formation of 3–30% (w/w) LaFeO3/MCM−41, nanocomposite catalysts were performed by a sol−gel process, followed by calcination at 550 and 750 °C. The nanocomposites were characterized through different techniques including LAXRD, WAXRD, EDX, simultaneous TG−DTA, ATR−FTIR, nitrogen adsorption/desorption, and TEM. The nanocomposites featured high surface areas (up to 1000 m2/g) and enhanced thermal stability. The direct formation method led to nanodispersion and size confinement of LaFeO3 in MCM−41 mesopores. The nanocomposites showed very high catalytic activity for isopropanol conversion, whereas their parent materials (blank MCM-41 or bulk LaFeO3) were totally inactive under the same reaction conditions. Thus, nanocomposite catalysts with low loading ratios and low calcination temperature produced pure dehydration product (propene) with very high conversion and total selectivity. Nanocomposite catalysts with high loading ratios and high calcination temperature produced an appreciable amount of the dehydrogenation product (acetone) as well as the dehydration products. Moreover, high loading ratios at high reaction temperatures in air atmosphere led to the formation of oxidation products. The different reactivities of the nanocomposite catalysts were discussed and correlated to their nanostructure, in terms of enhancing of the mesoporous textures with surface acidity, oxidation ability and thermal stability. [Display omitted] •The method led to nanodispersion and size confinement of LaFeO3 in MCM-41 pores.•Catalytic products of isopropanol conversion were based on dispersion case of LaFeO3.•Low LaFeO3/MCM-41 w/w catalysts led to pure dehydration with 100% yield.•High LaFeO3/MCM-41 w/w catalysts calcined at high temperature led to oxidation.•The method can be generalized for different perovskites -type mixed metal oxides.
ISSN:0254-0584
1879-3312
DOI:10.1016/j.matchemphys.2020.123412