High-valent metal oxo species are considered key intermediates in various industrial and biological catalytic processes. This project investigates the formation, reactivity and possible stabilization of high-valent metal oxo and metal-hydroxo species in novel molecular vanadium oxide clusters. Metal-functionalized vanadium oxides [M(L)V12O32X]n- (= {MV12}, M = transition metal, L = terminal ligand, X = halide-template) with a pre-formed metal binding site are used as suitable models for the generation and possible stabilization of high-valent metal species as their oxidative-catalytic activity has been shown previously. In particular, this project is focused on redox-active 3d-transition metals with multiple accessible redox-transitions (FeII, MnII, CoII) as potentially relevant models for industrial catalysts (e.g. Haber-Bosch process) as well as enzymes (e.g. cytochrome P450). In addition, selected 4d/5d metals (RuII, IrII) are employed as they can facilitate the isolation and structural characterization of high-valent oxo complexes. The binding mode of metal centres in {MV12} is fundamentally different to typical metal oxo ligands (often: nitrogen donors with trigonal coordination geometry), therefore new intermediates with a previously un-explored coordination behaviour and new reactivity can be expected. In the first step, the formation of high-valent species by reaction of existing {MV12} complexes with reactive ligands such as peroxides and azides as well as the activation of molecular oxygen by reduced {MV12} species is investigated. High-valent intermediates are characterized using experimental and theoretical methods to understand their electronic structure, binding modes and reactivity. Whenever possible, structural characterization using single-crystal X-ray diffraction will provide detailed insight into the binding situation. The reactivity of the high-valent species as well as their possible use as catalysts will be explored using synthetically important substrate oxidations, e.g. epoxidations, C-H-activations and hydroxylations. In situ stability studies will provide insight into possible cluster rearrangement or colloid formation. The project therefore provides access to a completely new compound class whose reactivity can be rationalized based on the intermediates formed and where reactivity can be tuned by chemical modification of the metal centres present.

DFG Programme Research Grants

Cooperation Partners Professor Dr. Timo Jacob; Professor Dr. Karsten Meyer; Professor Dr. Boris Mizaikoff