NMR Studies of a MnIII-hydroxo Adduct Reveal an Equilibrium between MnIII-hydroxo and μ-Oxodimanganese(III,III) Species.

The solution properties of MnIII-hydroxo and MnIII-methoxy complexes featuring N5 amide-containing ligands were investigated using 1H NMR spectroscopy. The 1H NMR spectrum for one of these complexes, the previously reported [MnIII(OH)(dpaq)](OTf) (dpaq = 2-[bis(pyridin-2-ylmethyl)]amino- N-quinolin-8-yl-acetamidate) shows hyperfine-shifted signals, as expected for this S = 2 MnIII-hydroxo adduct. However, the 1H NMR spectrum of [MnIII(OH)(dpaq)](OTf) also shows a large number of proton resonances in the diamagnetic region, suggesting the presence of multiple species in CD3CN solution. The majority of the signals in the diamagnetic region disappear when a small amount of water is added to a CH3CN solution of [MnIII(OH)(dpaq)](OTf). Electronic absorption and Mn K-edge X-ray absorption experiments support the formulation of this diamagnetic species as the μ-oxodimanganese(III,III) complex [MnIII2(μ-O)(dpaq)2)]2+. On the basis of these observations, we propose that the dissolution of [MnIII(OH)(dpaq)](OTf) in CD3CN results in the formation of mononuclear MnIII-hydroxo and dinuclear μ-oxodimanganese(III,III) species that are in equilibrium. The addition of a small amount of water is sufficient to shift this equilibrium in favor of the MnIII-hydroxo adduct. Surprisingly, electronic absorption experiments show that the conversion of [MnIII2(μ-O)(dpaq)2)]2+ to [MnIII(OH)(dpaq)]+ by added water is relatively slow. Because this dimer to monomer conversion is slower than TEMPOH oxidation by [MnIII(OH)(dpaq)]+, the previously observed TEMPOH oxidation rates for [MnIII(OH)(dpaq)]+ reflected both processes. Here, we report the bona fide TEMPOH oxidation rate for [MnIII(OH)(dpaq)]+, which is significantly faster than previously reported. 1H NMR spectra are also reported for the related [MnIII(OMe)(dpaq)]+ and [MnIII(OH)(dpaq2Me)]+ complexes. These spectra only show hyperfine-shifted signals, suggesting the presence of only mononuclear MnIII-methoxy and MnIII-hydroxo species in solution. Measurements of T1 relaxation times and proton peak integrations for [MnIII(OMe)(dpaq)]+ provide preliminary assignments for 1H NMR resonances.