Methane Catalytic Combustion on Pd9/?-Al2O3 with Different Degrees of Pd Oxidation

: This research is focused on the analysis of adsorbed CH4 intermediates at oxidized Pd9 nanoparticles supported on ? -alumina. From first-principle density functional theory (DFT) calculations, several configurations, charge transfer and electronic density of states have been analyzed in order to d...

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Bibliographic Details
Published in:CHIMIA
Main Authors: Izabela Czekaj, Katarzyna A. Kacprzak, John Mantzaras
Format: Article in Journal/Newspaper
Language:German
English
French
Published: Swiss Chemical Society 2013
Subjects:
Alumina support
Dft
Metal-support interactions
Methane combustion
Palladium catalyst
Chemistry
QD1-999
Carbonic acid
Online Access:https://doi.org/10.2533/chimia.2013.271
https://doaj.org/article/4007eeb2f9a8427da43615b24d1f45f1
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Summary:: This research is focused on the analysis of adsorbed CH4 intermediates at oxidized Pd9 nanoparticles supported on ? -alumina. From first-principle density functional theory (DFT) calculations, several configurations, charge transfer and electronic density of states have been analyzed in order to determine feasible paths for the oxidation process. Furthermore methane oxidation cycles have been investigated on Pd nanoparticles with different degrees of oxidation. In case of low oxidized Pd nanoparticles, activation of methane is observed, whereby hydrogen from methane is adsorbed at one oxygen atom. This reaction is exothermic. In a subsequent step, two water molecules desorb. Additionally, a very interesting structural effect becomes evident; Pd-carbide formation, which is also an exothermic reaction. Furthermore, oxidation of such carbidized Pd-nanoparticles leads to CO2 formation, which is an endothermic reaction. One important result is that the support is involved in the CO2 formation. A different mechanism of methane oxidation was discovered for highly oxidized Pd nanoparticles. When the Pd nanoparticle is more strongly exposed to oxidative conditions, adsorption of methane is also possible, but it leads to carbonic acid production at the interface between the Pd nanoparticles and support. This process is endothermic.

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