Reductive Elimination at an Ortho-Metalated Iridium(III) Hydride Bearing a Tripodal Tetraphosphorus Ligand

The synthesis of the novel C-3-symmetric tripodal, tetradentate ligand 1, bearing only phosphorus atoms as donor groups, is described, starting from commercially available o-tolyldiphenylphosphine, and its molecular structure has been determined by X-ray crystallographic analysis. Coordination to the cationic Ir-1 precursor [Ir(COE)(2)(acetone)(2)]PF6 led to a highly unsymmetrical species (90% yield) with four inequivalent phosphorus atoms, as evidenced by P-31 NMR spectroscopy. The corresponding H-1 NMR spectrum exhibited a pseudo doublet of quartets at delta -5.9 ppm with one large trans P-H coupling ((2)J(P-H) = 115.4 Hz) and a much smaller cis coupling ((2)J(P-H) = 10.8 Hz). X-ray crystallography confirmed the formation of complex 2, [Ir(H)(kappa P-5,P,P,P,C-1)]PF6, which is a rare example of a structurally characterized mononuclear Ir hydride species bearing an ortho-metalated phosphine ligand. This species does not react with hydride sources, but addition of 1 equiv of CF3COOH resulted in facile overall formal protonation of the Ir-C bond. DFT calculations support a pathway involving initial reductive elimination, forming the highly distorted four-coordinate species 2', followed by protonation at iridium to give the dicationic monohydride species 3, with an activation barrier Delta G(dagger) of 28.2 kcal mol(-1). Deuteration experiments support this mechanism. Reductive elimination can also be induced by reaction of 2 with carbon monoxide, yielding the monocationic carbonyl complex [Ir-1(CO)(1)]PF6 as the sole product.