Synthetic, X-ray diffraction, electrochemical, and density functional theoretical studies of (indenyl)ruthenium complexes containing dithiolate ligands

Halide substitution of the complexes [(Ind)Ru(L₂)X] {Ind = η⁵-C₉H₇. 1: (L₂) = dppf [1,1′-bis(diphenylphosphanyl)ferrocene], X = Cl; 2: (L₂) = dppm [1,1′-bis(diphenylphosphanyl)methane], X = Cl; and 18: (L₂) = (CO)₂, X = I} with the 1,1-dithiolates ^-S ₂CNR₂ (dialkyl dithiocarbamates for R = Me, Et, and C ₅H₁₀), S₂COR (alkyl xanthates for R = Et and iPr), and ^-S₂PR₂ (dithiophosphinates for R = Et and Ph) showed that the lability of the indenyl ligand is influenced by the nature of both the coligand and the incoming dithiolate, as well as the solvent. In addition to dithiolate derivatives, the reactions also produced the hydride species [(Ind)Ru(diphos)H] in solvent- and stoichiometry-dependent yields. The observed dependence of lability of Ind on (L₂) follows the order, dppf < dppm ≈ (CO)₂, in agreement with the electron-donor capability of L₂, as well as the estimation of lowest activation energy for the η⁵ → η³ ring slippage process in the series of complexes [(Ind)Ru(L)₂(S₂COMe)] (L = PMeH₂, PH₃, CO) for L = CO. The computational study also indicated an indenyl lability order for dithiolate substitution (dithiocarbamate > xanthate), in agreement with experimental findings. The dissociation of the indenyl ligand in chloro substitution of 1 by ^-S ₂CNEt₂ was found to be exhaustive in a polar solvent like MeOH, but only partial in CH₂Cl₂. Cyclic voltammetry experiments indicated that [(Ind)Ru(dppf)(η¹-S₂COiPr)] (10) and [(Ind)Ru(dppf)(η¹-S₂PPh₂)] (13) can be oxidized in one-electron chemical irreversible or chemical reversible processes, respectively (at a scan rate of 100 mV/s), at about 0 V versus Fc/Fc⁺. Complex 13 underwent additional one-electron oxidation processes at +0.5 and +0.8 V versus Fc/Fc⁺. The new complexes have all been characterized spectroscopically, and some (four containing the indenyl ligand and three of the non-indenyl type) by X-ray diffraction as well.