Sulfur Poisoning of a Pt/BaK-LTL catalyst: A catalytic and structural study using hydrogen chemisorption and x-ray absorption spectroscopy

The sulfur poisoning of a Pt/BaK-LTL catalyst has been studied with X-ray absorption spectroscopy and hydrogen chemisorption. The fresh catalyst contained highly dispersed platinum inside the zeolite pores. EXAFS analysis determined a Pt-Pt coordination number of 3.7, suggesting an average platinum...

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Bibliographic Details
Published inJournal of catalysis Vol. 138; no. 2; pp. 675 - 685
Main Authors Vaarkamp, M., Miller, J.T., Modica, F.S., Lane, G.S., Koningsberger, D.C.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier Inc 01.12.1992
Elsevier
Subjects
Catalysis
Catalysts: preparations and properties
Chemistry
Exact sciences and technology
General and physical chemistry
Theory of reactions, general kinetics. Catalysis. Nomenclature, chemical documentation, computer chemistry
Barium Ions
Hydrogen
Saturated compound
Potassium Ions
Supported catalyst
Molecular sieve
Characterization
Platinum
Hexane
Ion exchange
Sulfur
Modified material
Chemisorption
Catalyst poisoning
Catalytic reaction
Hydrocarbon
Aliphatic compound
Transition metal
Zeolite
Experimental study
EXAFS spectrometry
Heterogeneous catalysis
Chemical conversion
Impregnation
Preparation
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Summary:The sulfur poisoning of a Pt/BaK-LTL catalyst has been studied with X-ray absorption spectroscopy and hydrogen chemisorption. The fresh catalyst contained highly dispersed platinum inside the zeolite pores. EXAFS analysis determined a Pt-Pt coordination number of 3.7, suggesting an average platinum cluster size of 5 or 6 atoms, consistent with the TEM and chemisorption data (H/Pt = 1.4). The catalyst was poisoned with H 2S until the dehydrocyclization activity of n-hexane decreased to 30% of fresh activity. The first-shell PtPt coordination number increased to 5.5, indicating a growth of the average platinum cluster size to 13 atoms. Hydrogen chemisorption measurements of the poisoned catalyst show a decrease in the H/Pt value to 1.0. The EXAFS data also provide evidence for the presence of sulfur adsorbed on the surface of the platinum particles with a PtS bond distance of 2.27 Å. The high sensitivity of the Pt/LTL catalyst to poisoning by very low levels of sulfur is attributed to the loss of active platinum surface by adsorption of sulfur and the growth of the platinum clusters. Much of the available platinum surface was found to be capable of chemisorbing hydrogen, but with no activity for dehydrocyclization. Growth of the platinum particle was sufficient to block the pore. In the sulfur-poisoned catalyst, only the sulfur-free platinum atoms exposed through the pore windows remain active. The evidence suggests the location of the sulfur was at or near the metal-zeolite interface. Since both high activity and selectivity require extremely small platinum particles, regeneration of sulfur-poisoned catalysts will require removal of the adsorpted sulfur and restoration of the original particle size.
ISSN:0021-9517
1090-2694
DOI:10.1016/0021-9517(92)90315-9