Reductive Elimination Leading to C−C Bond Formation in Gold(III) Complexes: A Mechanistic and Computational Study

The factors affecting the rates of reductive C-C cross-coupling reactions in gold(III) aryls were studied using complexes that allow easy access to a series of electronically modified aryl ligands, as well as to gold methyl and vinyl complexes, using the pincer compounds (C^N^C)AuR (R = C6F5, CH=CMe2, Me and p-C6H4X, where X = OMe, F, H, But, Cl, CF3, or NO2) as starting materials (C^N^C = 2,6-(4′-ButC6H3)2pyridine dianion). Protodeauration followed by addition of 1 equiv. SMe2 leads to the quantitative generation of the thioether complexes [(C^N-CH)AuR(SMe2)]+. Upon addition of a second SMe2 pyridine is displaced, which triggers reductive aryl-R elimination. The rates for these cross-couplings increase in the sequence k(vinyl) > k(aryl) >> k(C6F5) > k(Me). Vinyl-aryl coupling is particularly fast, 1.15 × 10–3 L mol–1 s–1 at 221 K, while both C6F5 and Me couplings encountered higher barriers for the C-C bond forming step. Using P(p-tol)3 in place of SMe2 greatly accelerates C–C couplings. Computational modelling shows that in the C^N bonded compounds displacement of N by a donor L is required before the aryl ligands can adopt a conformation suitable for C-C bond formation, so that elimination takes place from a four-coordinate intermediate. C-C bond formation is rate limiting. In the non-chelating case, reductive C(sp2)-C(sp2) elimination from three-coordinate cations [(Ar1)(Ar2)AuL]+ is almost barrierless, particularly if L = phosphine.