Abstract
An extensive characterization of [Ti(C22H18N2O6)]·H2O was performed by topological analysis according to Bader's quantum theory of atoms in molecules (QTAIM) from the experimentally (multipole model) and theoretically (DFT) determined electron density. To the best of our knowledge, this study is the first example of an experimental electronic structure of a coordination compound in which a peroxo anion is bonded to a 3d central atom. The titanium coordination polyhedron could be described as a deformed tetrahedral pyramid if the midpoint of the peroxide O-O bond (side-on mode) is considered to be in the quasi-apical position. According to the multipole model (MM) results, the titanium atom has a positive QTAIM charge of 2.05 e- which does not correspond to the formal Ti (IV) oxidation state. On the other hand, the peroxo oxygen atoms O(1) and O(2) have MM QTAIM charges of -0.27 and -0.12, respectively. This asymmetric charge density distribution on the peroxo oxygens is in agreement with the distorted orientation of the O2 moiety with respect to the titanium atom. Despite the fact that the overall MM charge of the O2 moiety is more remote from the formal -2 charge than from neutral O2, the O-O distance remains close to that in the peroxo O2 2- anion. In the case of DFT results, the titanium atom charge is also found to be close to +2, the O2 x- moiety charge is around -1, the optimized O-O distance is shorter by only ca 0.04 Å than the experimental value of 1.5005 (16) Å, and the DFT d-populations on titanium are found to be lower than the experimental MM value. This study is the first experimental electronic structure of a transition metal peroxo complex.
Highlights
All living organisms requiring molecular oxygen for life mediate four-electron reduction of oxygen to water (Valko et al, 2004)
By means of the charge density study presented here we proved that, in the title compounds, the O—O bonding electron density is significantly shifted towards the central titanium atom
The difference is that the valence shell charge concentration (VSCC) in peroxocomplexes is asymmetric with respect to the O—O bond and symmetric for the O2 molecule
Summary
All living organisms requiring molecular oxygen for life mediate four-electron reduction of oxygen to water (Valko et al, 2004). In the course of the reduction process, the energy formed is utilized by aerobic organisms maintaining life on the Earth. Molecular oxygen is in triplet ground state with two parallel unpaired electrons (S = 1) which represents the most stable oxygen form. The first step of the reduction cascade, representing reduction of molecular oxygen to superoxide radical anion is a rather unfavorable, endergonic reaction ($33000 J molÀ1) (Valko et al, 2005). The molecular oxygen biradical has two parallel electrons in antibonding orbitals and its reactions with organic molecules, in which all electrons are paired and in closed-shell systems, are spin forbidden.
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