The
mechanism of the Ullmann-type reaction between potassium thioacetate
(KSAc) and iodobenzene (PhI) catalyzed by CuI associated with 1,10-phenanthroline
(phen) as a ligand was explored experimentally and computationally.
The study on C–S bond formation was investigated by UV–visible
spectrophotometry, cyclic voltammetry, mass spectrometry, and products
assessment from radical probes. The results indicate that under experimental
conditions the catalytically active species is [Cu(phen)(SAc)] regardless
of the copper source. An examination of the aryl halide activation
mechanism using radical probes was undertaken. No evidence of the
presence of radical species was found during the reaction process,
which is consistent with an oxidative addition cross-coupling pathway.
The different reaction pathways leading to the experimentally observed
reaction products were studied by DFT calculation. The oxidative addition–reductive
elimination mechanism via an unstable Cu<sup>III</sup> intermediate
is energetically more feasible than other possible mechanisms such
as single electron transfer, halogen atom transfer, and σ-bond
methatesis
