Combining Valence-to-Core X-ray Emission and Cu K-edge X-ray Absorption Spectroscopies to Experimentally Assess Oxidation State in Organometallic Cu(I)/(II)/(III) Complexes

A series of organometallic copper complexes in formal oxidation states ranging from +1 to +3 have been characterized by a combination of Cu K-edge X-ray absorption (XAS) and Cu K beta valence-to-core X-ray emission spectroscopies (VtC XES). Each formal oxidation state exhibits distinctly different XAS and VtC XES transition energies due to the differences in the Cu Z(eff), concomitant with changes in physical oxidation state from +1 to +2 to +3. Herein, we demonstrate the sensitivity of XAS and VtC XES to the physical oxidation states of a series of N-heterocyclic carbene (NHC) ligated organocopper complexes. We then extend these methods to the study of the [Cu(CF3)(4)](-) ion. Complemented by computational methods, the observed spectral transitions are correlated with the electronic structure of the complexes and the Cu Z(eff). These calculations demonstrate that a contraction of the Cu 1s orbitals to deeper binding energy upon oxidation of the Cu center manifests spectroscopically as a stepped increase in the energy of both XAS and K beta(2,5) emission features with increasing formal oxidation state within the [Cun+(NHC2)](n+) series. The newly synthesized Cu(III) cation [Cu-III(NHC4)](3+) exhibits spectroscopic features and an electronic structure remarkably similar to [Cu(CF3)(4)](-), supporting a physical oxidation state assignment of low-spin d(8) Cu(III) for [Cu(CF3)(4)](-). Combining XAS and VtC XES further demonstrates the necessity of combining multiple spectroscopies when investigating the electronic structures of highly covalent copper complexes, providing a template for future investigations into both synthetic and biological metal centers.

Automated summary

A combination of Cu K-edge X-ray absorption and Cu K beta valence-to-core X-ray emission spectroscopies can be used to characterize the formal oxidation states of organometallic copper complexes. These methods are crucial for investigating the electronic structures of highly covalent copper complexes.