Eric J. Klinker scite author profile

Nonheme oxoiron(IV) complexes of two pentadentate ligands, N4Py (N,N-bis(2-pyridylmethyl)-bis(2-pyridyl)methylamine) and Bn-tpen (N-benzyl-N,N',N'-tris(2-pyridylmethyl)-1,2-diaminoethane), have been generated and found to have spectroscopic properties similar to the closely related tetradentate TPA (tris(2-pyridylmethyl)amine) complex reported earlier. However, unlike the TPA complex, the pentadentate complexes have a considerable lifetime at room temperature. This greater thermal stability has allowed the hydroxylation of alkanes with C-H bonds as strong as 99.3 kcal/mol to be observed at room temperature. Furthermore, a large deuterium KIE value is found in the oxidation of ethylbenzene. These observations lend strong credence to postulated mechanisms of mononuclear nonheme iron enzymes that invoke the intermediacy of oxoiron(IV) species.

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Spectroscopic and Quantum Chemical Studies on Low-Spin Fe^IVO Complexes: Fe−O Bonding and Its Contributions to Reactivity

Decker

et al. 2007

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High valent Fe IV =O species are key intermediates in the catalytic cycles of many mononuclear nonheme iron enzymes and have been structurally defined in model systems. Variable temperature magnetic circular dichroism (VT-MCD) spectroscopy has been used to evaluate the electronic structures and in particular the Density Functional calculations were correlated to the data and support the experimental analysis. The strength and covalency of the Fe-O π-bond result in high oxygen character in the important frontier molecular orbitals (FMOs) for this reaction, the unoccupied β-spin d(xz/yz) orbitals, and activates these for electrophilic attack. An extension to biologically relevant Fe IV =O (S=2) enzyme intermediates shows that these can perform electrophilic attack reactions along the same mechanistic pathway (π-FMO pathway) with similar reactivity, but also have an additional reaction channel involving the unoccupied α-spin d(z 2 ) orbital (σ-FMO pathway).These studies experimentally probe the FMOs involved in the reactivity of Fe IV =O (S=1) model complexes resulting in a detailed understanding of the Fe-O bond and its contributions to reactivity.

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Eric J. Klinker

Nonheme Fe^IVO Complexes That Can Oxidize the C−H Bonds of Cyclohexane at Room Temperature

Spectroscopic and Quantum Chemical Studies on Low-Spin Fe^IVO Complexes: Fe−O Bonding and Its Contributions to Reactivity

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Eric J. Klinker

Nonheme FeIVO Complexes That Can Oxidize the C−H Bonds of Cyclohexane at Room Temperature

Spectroscopic and Quantum Chemical Studies on Low-Spin FeIVO Complexes: Fe−O Bonding and Its Contributions to Reactivity

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Nonheme Fe^IVO Complexes That Can Oxidize the C−H Bonds of Cyclohexane at Room Temperature

Spectroscopic and Quantum Chemical Studies on Low-Spin Fe^IVO Complexes: Fe−O Bonding and Its Contributions to Reactivity