Tortuosity of mesoporous alumina catalyst supports: Influence of the pore network organization

Tortuosity of mesoporous alumina catalyst supports: Influence of the pore network organization

Inverse liquid chromatography experiments were performed on five mesoporous alumina catalyst supports with similar porosity and different pore size distributions. By varying the size of the molecular tracer, it was shown that the diffusion regime in our conditions is molecular diffusion. Hindered di...

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Bibliographic Details
Published in:Microporous and mesoporous materials Vol. 248; pp. 91 - 98
Main Authors: Kolitcheff, Svetan, Jolimaitre, Elsa, Hugon, Antoine, Verstraete, Jan, Carrette, Pierre-Louis, Tayakout-Fayolle, Mélaz
Format: Journal Article
Language:English
Published: Elsevier Inc 01-08-2017
Elsevier
Subjects:
Alumina support
Catalysis
Chemical Sciences
Internal diffusional limitations
Inverse liquid chromatography
Material chemistry
Pore network
Pore size distribution
Tortuosity
Pore network
Internal diffusional limitations
Inverse liquid chromatography
Tortuosity
Pore size distribution
Alumina support
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Summary:Inverse liquid chromatography experiments were performed on five mesoporous alumina catalyst supports with similar porosity and different pore size distributions. By varying the size of the molecular tracer, it was shown that the diffusion regime in our conditions is molecular diffusion. Hindered diffusion was not observed even for squalane, a C30 molecule. Using the slope of the Van Deemter equation, the tortuosity of each alumina support was determined. The results are in disagreement with literature correlations: although all alumina supports had similar total porosities, the measured tortuosity values are really different and much higher than those predicted by these theoretical models. This discrepancy has been resolved by assuming a two–level pore network organization, whose characteristics can be entirely estimated from a classical nitrogen adsorption isotherm. This simple methodology allows to evaluate the mass transfer in mesoporous alumina supports knowing their textural properties, which is an important issue for the design and optimization of numerous catalytic processes. [Display omitted] •Diffusion properties of several alumina catalyst supports having the same porosity but different textural properties.•Tortuosities of alumina catalyst supports estimated from Inverse Liquid Chromatography experiments differ.•Different levels of the porous organization in the alumina catalyst support.•Decomposition of BJH pore size distribution in order to obtain porous volumes of hierarchical levels.
ISSN:1387-1811
1873-3093
DOI:10.1016/j.micromeso.2017.04.010