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Isobutane dehydrogenation on Pt-Sn/SiO{sub 2} catalysts: Effect of preparation variables and regeneration treatments

Journal Article · · Journal of Catalysis
; ;  [1]
  1. Univ. of Oklahoma, Norman, OK (United States); and others
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The dehydrogenation of isobutane was studied under severely deactivating conditions, i.e., high temperatures and in the absence of added H{sub 2}, over silica-supported Pt-Sn catalysts. Several preparation methods were investigated. It was found that the impregnation method employed has a strong influence on the degree of Pt-Sn interaction and the fraction of Pt that remains unalloyed after the calcination and reduction process. The co-impregnation methods investigated were significantly superior to the sequential method. It was found that it is important to minimize the amount of unalloyed Pt left on the catalyst because this fraction rapidly forms coke and deactivates. At the same time, the fraction of unalloyed Pt, rather than the one alloyed with Sn, is responsible for most of the CO and hydrogen adsorbed at room temperature in typical chemisorption measurements. As a consequence, the TOF values based on this type of measurements are in error because they are not related to the density of sites that are responsible for long term activity. It was also found that the high-temperature reduction/oxidation treatments usually employed to regenerate spent catalysts can have a detrimental effect on the activity and selectivity of the Pt-Sn/SiO{sub 2} catalysts. It is postulated that such thermal treatments lead to the disruption of the Pt-Sn alloys causing an increase in the fraction of unalloyed surface Pt. As a result, the rates of coke formation and deactivation drastically increase. The monometallic (Pt only) catalysts are also affected by the high-temperature reduction/oxidation processes. The oxidation treatment results in an increased rate of coke formation and deactivation, while the regeneration process results in a much smaller effect. This difference may be due to carbon residues left on the surface. 37 refs., 17 figs., 3 tabs.
OSTI ID:
543386
Journal Information:
Journal of Catalysis, Journal Name: Journal of Catalysis Journal Issue: 1 Vol. 168; ISSN 0021-9517; ISSN JCTLA5
Country of Publication:
United States
Language:
English

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Related Subjects

02 PETROLEUM
2-METHYLPROPANE
36 MATERIALS SCIENCE
CALCINATION
CATALYSTS
CATALYTIC EFFECTS
CHEMISORPTION
COKING
DEACTIVATION
DEHYDROGENATION
FUEL ADDITIVES
IMPREGNATION
OXIDATION
PLATINUM
SILICA
SYNTHESIS
TEMPERATURE DEPENDENCE
TIN