Transition metal sulfides promotion effect

The importance of edge planes also arises in the industrially important promoted transition metal sulfide catalyst systems. It has been known for many years that the presence of a second metal such as Co or Ni to a M0S2 or WS2 catalyst leads to promotion (an increase in activity for HDS or hydrogenation in excess of the activity of the individual components) ( ). Promotion effects can easily be observed in supported or unsupported catalysts. The supported catalysts are currently the most important industrial catalysts, but the unsupported catalysts are easier to characterize and study. Unsupported, promoted catalysts have been prepared by many different methods, but one convenient way of preparing these catalysts is by applying the nonaqueous precipitation method described above. For example, for Co/Mo, appropriate mixtures of C0CI2 MoCl are reacted with Li2S in ethyl acetate ... 

Crystal structure plays a secondary role in catalysis by the Transition Metal Sulfides. As the periodic trends for HDS of the binary sulfides shows the dominant effect is which transition metal is present in the reaction, this transition metal takes on the structure and stoichiometry of the phase which is most stable in the sulfur containing catalytic environment. The unsupported promoted catalyst systems can be grouped into "synergic" pairs of sulfides. Because these pairs are related to the basic periodic trends of the binary Transition Metal Sulfides through average heats of formation. 

The promotion of bulk binary sulfide is limited exclusively to the promotion of molybdenum and tungsten by the first-row transition metal. The effect of the structural promotion (creating more of the same sites) is always coupled to the electronic promotion (creating more active sites). One ap-... 

Evidence for the intermediacy of a-arylpalladium acetate complexes c was provided by the isolation of their trinuclear dialkyl sulfide adducts [11]. The two following steps, insertion of the alkene 4 and )8-hydride elimination, correspond to the classical Mizoroki-Heck reaction pathway. The resulting palladium(0) species, which is likely to be stabilized in the form of a hydridopalladium carboxylate e, is then reoxidized by molecular oxygen to the initial palladium(II) acetate (a) under liberation of water. The precise mechanism of this reoxidation is not yet fully understood, but it seems that, at elevated oxygen pressures, it is not rate-determining even in the absence of promoters. Mechanistic studies by Jacobs and coworkers [10] indicate that the beneficial effect of adding transition metal salts, originally intended to facilitate this oxidation step, in fact arises from an acceleration... 

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