Oxidative Reactivity of (N2S2)PdRX Complexes (R = Me, Cl; X = Me, Cl, Br): Involvement of Palladium(III) and Palladium(IV) Intermediates

A series of (N2S2)­PdRX complexes (N2S2 = 2,11-dithia[3.3]­(2,6)­pyridinophane; R = X = Me, 1; R = Me, X = Cl, 2; R = Me, X = Br, 3; R = X = Cl, 4) were synthesized, and their structural and electronic properties were investigated. X-ray crystal structures show that for the corresponding Pd­(II) complexes the N2S2 ligand adopts a κ2 conformation, with the pyridine N donors binding in the equatorial plane. Cyclic voltammetry (CV) studies suggest that the Pd­(III) oxidation state is accessible at moderate redox potentials. In situ EPR, ESI-MS, UV–vis, and low-temperature electrochemical studies were employed to detect the formation of Pd­(III) species during the oxidation of Pd­(II) precursors. In addition, the [(N2S2)­PdIVMe2]­(PF6)2 ([12+]­(PF6)2) complex was isolated by oxidation of 1 with 2 equiv of FcPF6, and its structural characterization reveals an octahedral Pd­(IV) center. The reversible PdIV/III redox couple for the Pd­(IV) species supports the observed formation of the Pd­(III)–dimethyl species upon chemical reduction of 12+. In addition, reactivity studies reveal ethane, MeCl, and MeBr elimination upon one-electron oxidation of 1 (as well as the one-electron reduction of 12+), 2, and 3, respectively. Mechanistic studies suggest the initial formation of a Pd­(III) species, followed by methyl group transfer/disproportionation and subsequent reductive elimination from a Pd­(IV) intermediate, although a halogen radical pathway cannot be completely excluded during C–halide bond formation. Interestingly, computational results suggest that the N2S2 ligand stabilizes to a greater extent the Pd­(IV) vs the Pd­(III) oxidation state, likely due to steric rather than electronic effects.