Metal/Ligand Proton Tautomerism Facilitates Dinuclear H Reductive Elimination.

Using the doubly protic bis-pyrazole-pyridine ligand (N(NN)), we have synthesized an octahedral Ir-H [HIr(κ-N(NN)(NN))(CO)(BuPy)] ([]) from an Ir starting material. This hydride was generated by adding sufficient electron density to the metal center such that it became the thermodynamically preferred site of protonation. It was observed via UV-vis spectroscopy that [] establishes a [BuPy] dependent equilibrium with a ligand protonated square-planar Ir [Ir(N(NN))(CO)] ([]). This example of metal/ligand proton tautomerism is unusual in that the position of the equilibrium can be controlled by the concentration of exogeneous ligand (i.e., BuPy). This equilibrium was shown to be key to the reactivity of the Ir-H; 2 equiv of [] release H, converting to the Ir dimer [[Ir(N(NN)(NN))(CO)(BuPy)]] ([]) under mild conditions (observable at room temperature). Mechanistic evidence is presented to support that this dinuclear reductive elimination occurs by tautomerization of the metal hydride [] to a ligand protonated species [], from which ligand dissociation is facile, generating []. Subsequent reaction of [] with [] allows for production of H and the Ir dimer []. The tautomerization between the metal-hydride and the ligand protonated species provides a low energy pathway for ligand dissociation, opening the needed coordination site. The ability to control the interconversion between a metal-hydride and a ligand-protonated congener using an exogeneous ligand introduces a new strategy for catalyst design with proton responsive ligands.