CATALYTIC AND STRUCTURAL-PROPERTIES OF RUTHENIUM BIMETALLIC CATALYSTS- HYDROGENOLYSIS OF PROPANE AND N-BUTANE ON RU AL2O3 CATALYSTS MODIFIED BY A GROUP-14 ELEMENT/

Authors
Citation
Gc. Bond et Jc. Slaa, CATALYTIC AND STRUCTURAL-PROPERTIES OF RUTHENIUM BIMETALLIC CATALYSTS- HYDROGENOLYSIS OF PROPANE AND N-BUTANE ON RU AL2O3 CATALYSTS MODIFIED BY A GROUP-14 ELEMENT/, Journal of molecular catalysis. A, Chemical, 106(1-2), 1996, pp. 135-149
Citations number
18
Categorie Soggetti
Chemistry Physical
ISSN journal
13811169
Volume
106
Issue
1-2
Year of publication
1996
Pages
135 - 149
Database
ISI
SICI code
1381-1169(1996)106:1-2<135:CASORB>2.0.ZU;2-Q
Abstract
The addition of Ge as Ge(n)Bu(4) to H-covered Ru/Al2O3 (RuEC1) leads a fter in situ reduction at high temperature (HTR1; 758 K) to decreases in H-2 chemisorption capacity and even more marked falls in activity f or hydrogenolysis of propane and of n-butane. Changes in product selec tivities are slight, and all Ge-containing samples exhibit similar cha racteristics to the parent RuEC1, which is very highly dispersed. Alth ough loss of activity is chiefly due to encapsulation of the Ru-o part icles by amorphous GeOx species, these affect neighbouring active site s by decreasing the equilibrium constant for alkane dehydrogenation to the reactive species. This conclusion follows from determinations of the rate-dependence on H-2 pressure and mathematical modelling of the results. Similar behaviour is shown by the less well-dispersed RuEC3, where activity loss and selectivity changes are partly due to encapsul ation by GeOx of smaller particles: some evidence for selective blocki ng of Ru atoms in low coordination number sites by Sn species formed a nalogously is however obtained. H-2 pressure-dependence of the rate of n-butane hydrogenolysis was determined at four different temperatures with a GeOx-modified RuEC3, whence a true activation energy (50 kJ mo l(-1)) and an enthalpy change for the alkane dehydrogenation step were obtained. Oxidation and low-temperature reduction (O/LTR) of catalyst s previously subjected to HTR1 led to very large increases in rate, an d to changes in product selectivites, that suggested the creation of l arge, essentially pure, Ru particles; the modifier could not be wholly re-united with them by a second HTR. Ru/Al2O3 catalysts of the NI ser ies, prepared from inorganic precursors, showed greater dispersion in the presence of the modifier, the catalytic behaviour being in harmony with this observation.