Pause for thought

It is fairly easy to see how a heterogeneous catalyst works. Two reacting gases, e.g. hydrogen and ethene, adsorb onto the surface of a transition metal such as nickel or palladium. This brings the two reactants close together and with the right orientation producing an alternative pathway with a lower activation energy than the uncatalysed reaction. Once the product has formed, it is then desorbed. It is less easy to find good examples of how homogeneous catalysts work. One that is often given (and I use in my Study Guide) is the reaction between peroxodisulfate(VI) ions and iodide ions, which is catalysed by iron(II) ions. It is thought that the Fe²⁺(aq) ions are oxidised to Fe³⁺(aq) ions and then back to Fe²⁺(aq) ions.

S₂O₈²⁻(aq) + 2Fe²⁺⁽aq) → 2SO₄²⁻(aq) + 2Fe³⁺(aq)

2I⁻(aq) + 2Fe³⁺(aq) → 2Fe²⁺(aq) + I₂(aq)

Although this shows that the oxidation state of the iron changes, it does not show any intermediate compound formation. One really good example to use is slightly esoteric as it involves a transition metal complex with a ligand that IB students will be unfamiliar with. This ligand is triphenylphosphine, P(C₆H₅)₃ – shortened to PPh₃. However the chemistry is easy to follow and students should recognise the phenyl functional group. The catalyst, chlorotris(triphenylphosphine)rhodium(I), is known as ‘Wilkinson’s compound’ named after Professor Sir Geoffrey Wilkinson (1921-1996) who discovered it and who went on to win the Nobel Prize in 1973 for his work on transition metal complexes. It has the formula RhCl(PPh₃)₃ and is a good homogeneous hydrogenation catalyst for alkenes.

Proposed mechanism for hydrogenation of an alkene catalysed by RhCl(PPh₃)₃

Chlorotris(triphenylphosphine)rhodium(I) is a square planar complex. The triphenylphosphine is analogous to ammonia so behaves as a neutral ligand. Students should be able to confirm that the oxidation state of rhodium in the compound is +1, as shown by its name. In solution hydrogen adds to the complex to form an octahedral complex. This is known as oxidative addition as the oxidation state of the rhodium has increased to +3. One of the triphenylphosphine ligands is now replaced by an alkene, which bonds via the pi electrons in the double bond. This brings the alkene close to the hydrogen atoms and it is thought that the rate-determining step is the addition of one of the hydrogen atoms to the alkene followed by the insertion of a triphenylphosphine molecule into the vacant site left by the hydrogen atom. The alkyl radical then reacts with the remaining hydrogen atom and leaves in a process known as reductive elimination to regenerate the original rhodium(I) compound.

Intermediates such as those shown above are obviously highly reactive so it is impossible to prove any suggested mechanism by isolating all the intermediates, although chemists have come up with several ingenious ways in which their presence can either be shown or inferred.