Received July 8, 2005

Abstract:

The formation of ruthenium amidophosphine complexes was accomplished by the addition of [P₂N₂]Li₂(Diox) (where P₂N₂ is PhP(CH₂SiMe₂NSiMe₂CH₂)₂PPh and Diox is 1,4-dioxane) to [RuCl₂(cod)]_x to generate [P₂N₂]Ru(cod), or to RuCl₂(PPh₃)₃ to generate [P₂NNH]Ru(C₆H₄PPh₂). In the former complex, the Ru(II) center is in an octahedral environment perched above the P₂N₂ macrocycle having two formally anionic amido donors; in the latter complex, there is only one amido ligand with the other as an amine donor where the proton originates from the cyclometalated triphenylphosphine group. Reaction of the tridentate amidophosphine ligand precursor [NPN]Li₂(THF)₂ (where NPN is PhP(CH₂SiMe₂NPh)₂) with [RuCl₂(cod)]_x results in the formation of two diastereomeric complexes of the formula [NPNH]Ru(³:²-C₈H₁₁), wherein the cyclooctadiene ligand has been deprotonated by the ancillary ligand to generate a cyclooctadienyl unit. These Ru(II) complexes are five-coordinate with a bidentate PN ligand and a dangling amine unit. The diastereomers are in equilibrium, as shown by variable-temperature NMR studies. The fluxional process that interconverts diastereomers involves proton transfer from the dangling amine arm to the amido unit, a process that equilibrates the two ends of the tridentate NPN ligand on the chemical time scale. Deprotonation of the amine arm by MN(SiMe₃)₂ generates a series of ruthenate complexes of the formula [M(THF)]([NPN]Ru(³:²-C₈H₁₁)), where M = Li or Na. Addition of Me₃SiCl results in the formation of new diastereomers that contain silylated dangling arms, and these diastereomers do not interconvert.

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