Activated takovite catalysts for partial hydrogenation of ethyne, propyne, and propadiene

The gas-phase hydrogenation of ethyne, propyne, and propadiene was investigated over partially reduced Ni–Al mixed oxides derived from takovite, a hydrotalcite-type compound. The unique attributes of the hydrotalcite route leads to more active and selective catalysts compared to conventional Ni/Al 2...

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Bibliographic Details
Published in:Journal of catalysis 2008-10, Vol.259 (1), p.85-95
Main Authors: Abelló, Sònia, Verboekend, Danny, Bridier, Blaise, Pérez-Ramírez, Javier
Format: Article
Language:English
Subjects:
Alkene
Alkyne
Carbon deposits
Catalysis
Catalyst activation
Catalysts
Chemistry
Comparative studies
Crystallization
Diene
Exact sciences and technology
General and physical chemistry
Hydrotalcite
Nickel
Ni–Al oxides
Operando spectroscopy
Selective hydrogenation
Takovite
Theory of reactions, general kinetics. Catalysis. Nomenclature, chemical documentation, computer chemistry
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Summary:The gas-phase hydrogenation of ethyne, propyne, and propadiene was investigated over partially reduced Ni–Al mixed oxides derived from takovite, a hydrotalcite-type compound. The unique attributes of the hydrotalcite route leads to more active and selective catalysts compared to conventional Ni/Al 2O 3 prepared by impregnation. Tuning calcination and reduction conditions of the catalyst precursor is essential to optimize the hydrogenation performance. The best catalyst, calcined and reduced at 773 K, rendered stable propene yields up to ca. 65% and consisted of a Ni(Al)O x solid solution with 55% of the total bulk nickel in reduced form and surface enrichment by aluminum. Sintering of NiO and crystallization of NiAl 2O 4 at high calcination temperature induce lower activity. The alkyne or diene conversion increases with the percentage of metallic Ni in the samples, while an optimal degree of nickel reduction maximizes the monoalkene selectivity. Below the optimum, oligomer formation is favored and above the optimum, alkane production increases. A similar pattern was found for the H 2/HC ratio. The alkene selectivity experiences a dramatic increase in early stages of the reaction, which correlated with the build-up of C-containing species on the catalyst (sub-)surface. These selectivity-enhancing species are formed at specific reaction temperatures, highlighting the relevance of the testing procedure on assessing hydrogenation catalysts. The catalytic performance is strongly influenced by the hydrocarbon substrate. In contrast to propyne and propadiene, ethyne hydrogenation led to a C 2H 4 yield of only 6%.
ISSN:0021-9517
1090-2694
DOI:10.1016/j.jcat.2008.07.012