Effect of surface segregation on the catalytic activity of alloys: CO hydrogenation on Pd–Ni(111) surface

A semi-empirical model has been presented for studying the effect of surface segregation and local environment on the catalytic activity of the PdNi(111) surface for CO hydrogenation. Large Pd segregation to the surface has been found to affect the activation barrier for dissociation of molecules on...

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Published inJournal of molecular catalysis. A, Chemical Vol. 129; no. 2; pp. 233 - 240
Main Authors Khanra, B.C., Bertolini, J.C., Rousset, J.L.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 06.03.1998
Elsevier
Subjects
Activation energy for dissociation
Carbon monoxide
Catalysis
Catalytic reactions
Chemistry
Exact sciences and technology
General and physical chemistry
Methanol
Segregation
Theory of reactions, general kinetics. Catalysis. Nomenclature, chemical documentation, computer chemistry
Carbon monoxide
Segregation
Activation energy for dissociation
Methanol
Catalytic reaction
Surface segregation
Theoretical study
Crystal face
Hydrogenation
Heterogeneous catalysis
Copper Alloys
Transition metal Alloys
Semiempirical method
Nickel Alloys
Platinum Alloys
Activation energy
Catalyst
Binary alloy
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Summary:A semi-empirical model has been presented for studying the effect of surface segregation and local environment on the catalytic activity of the PdNi(111) surface for CO hydrogenation. Large Pd segregation to the surface has been found to affect the activation barrier for dissociation of molecules on the surface. It also affects the activation barriers for different reaction steps in the CO hydrogenation process to form methanol on the Pd–Ni surface. It is argued that for the Pd–Ni system, hydrogenation of the adsorbed HCO s species is the rate-limiting step. It has then been shown that an addition of even 5 at% of Pd in bulk Ni may increase the activity by as much as four orders of magnitude. So far as the local environmental effect is concerned, it is found that the most active centres for the HCO s hydrogenation step are the centre hollow sites having three-fold symmetry with 3 Pd atoms as nearest neighbours followed by centre hollow sites with two Pd atoms and one Ni atom as nearest neighbours.
ISSN:1381-1169
1873-314X
DOI:10.1016/S1381-1169(97)00150-7