The mechanism of this
vinylation involves
organopalladium intermediates. The required palladium(0) compound is often generated
in situ from a palladium(II) precursor. For instance,
palladium(II) acetate is reduced by
triphenylphosphine to bis(triphenylphosphine)palladium(0) (
1) concomitant with oxidation of triphenylphosphine to
triphenylphosphine oxide. Step
A is an
oxidative addition in which palladium inserts itself in the aryl-bromide bond. The resulting palladium(II) complex then binds alkene (
3). In step
B the alkene inserts into the Pd-C bond in a
syn addition step. Step
C involves a
beta-hydride elimination (here the arrows are showing the opposite) with the formation of a new palladium - alkene π complex (
5). This complex is destroyed in the next step. The Pd(0) complex is regenerated by
reductive elimination of the palladium(II) compound by
potassium carbonate in the final step,
D. In the course of the reaction the carbonate is stoichiometrically consumed and palladium is truly a catalyst and used in catalytic amounts. A similar palladium cycle but with different scenes and actors is observed in the
Wacker process. This cycle is not limited to vinyl compounds, in the
Sonogashira coupling one of the reactants is an
alkyne and in the
Suzuki coupling the alkene is replaced by an aryl
boronic acid and in the
Stille reaction by an aryl
stannane. The cycle also extends to the other
group 10 element nickel for example in the
Negishi coupling between aryl halides and organozinc compounds. Platinum forms strong bonds with carbon and does not have a catalytic activity in this type of reaction. ==Stereoselectivity==