Double 1,2-Migration of Bromine and Silicon in Directed C–H Alkynylation Reactions with Silyl-Substituted Alkynyl Bromides through an Iridium Vinylidene Intermediate

The iridium­(III)-catalyzed C–H alkynylation of 2-acylimidazoles with alkynyl bromides, which was recently developed by our group, provides an efficient strategy for the construction of both C­(sp)–C­(sp2) and C­(sp)–C­(sp3) bonds. The mechanism for this reaction was extensively studied using density functional theory (DFT) calculations. The computed catalytic cycle is initiated by C–H activation, and the formed iridacycle undergoes a strain-controlled regioselective migratory insertion of an alkynyl bromide. The resulting α-bromovinyl iridium species is rapidly converted into a more stable iridium vinylidene intermediate by a 1,2-bromine migration, and the adjacent silyl group subsequently migrates to furnish a C–H-alkynylated product. The origin of the unique difference in reactivity with respect to the substituent on the alkynyl bromide is the 1,2-migration step, in which a silyl group can highly stabilize the transition state by the β-silicon effect.