S-alkylation-induced redox reactions leading to reversible sulfur-sulfur coupling in a pentamethylcyclopentadienyl ruthenium(III) thiolate-thioether system

Alkylation of [Cp*Ru ^III(tpdt)] (2) (Cp* = η ⁵-C ₅Me ₅, tpdt = η ³-S (CH ₂CH ₂S ^-) ₂) with MeI orMe ₃OBF ₄ resulted in the formation of a trans μ-η ¹-η ¹-S ₂ coupled species, [{Cp*Ru ^II} ₂{μ-η ⁶-(S(CH ₂) ₂S(CH ₂) ₂SMe) ₂}] ²⁺ (3) as the predominant product. With MeI the reaction also gave a small amount of [Cp*Ru ^II{η ³-S(CH ₂CH ₂SMe) ₂}]I, 4(I), but in the presence of acrylonitrile (AN), the products were 4(I) and [Cp*Ru ^II{η ³-S((CH ₂) ₂S) ₂(CH ₂CHCN)}] I, 5(I), of which the latter was the sole product from the reaction of 2 with AN in the presence of iodine. 2 was electrochemically easily oxidized in a one-electron process; its chemical oxidation with I ₂ led to the isolation of [{Cp*Ru ^II} ₂{μ-η ⁶- (S(CH ₂CH ₂S) ₂) ₂}](I ₃) ₂,6(I ₃) ₂, containing a cyclic Ru ^II(μ-S ₂) ₂Ru ^II core. A combination of electrochemical, EPR, UV-vis, and NMR experiments indicated that the solution phase chemistry of 3 is governed by its facile reversible dissociation into the mononuclear cation radical (3A). Based on this phenomenon were rationalized the pathways leading to the formation of the dinuclear species [{Cp*Ru ^II} ₂{μ-η ⁵-MeS(CH ₂) ₂-S(CH ₂) ₂SS(CH ₂) ₂S(CH ₂) ₂S}] ⁺ (7) from the interaction of 3 and 2, or of a mixture of 4(I) and 5(I) in the presence of MeI and AN, and of [Cp*Ru ^II{η ³-MeS(CH ₂) ₂S(CH ₂) ₂SSnBu ₃}] ⁺ (9) from reaction with tri(n-butyl)tin hydride. Electrochemical measurements indicated that the sodium naphthalide reduction of 3 to generate the mono-S-methylated derivative, [Cp*Ru ^II-{η ³- S(CH ₂) ₂S(CH ₂) ₂SMe}] (8), occurred through 3A. It is proposed that some of the transformations also involved internal electron transfers and nucleophilic displacements. The X-ray crystal structures of the complexes 3-9 are reported.