Mössbauer Spectroscopy of the Spin-Coupled Fe<sup>3+</sup>−Fe<sup>2+</sup> Center of Reduced Uteroferrin

Rodriguez, Jorge H.; Ok, Hang Nam; Xia, Yao; Debrunner, Peter G.; Hinrichs, B. E.; Meyer, Terrance E.; Packard, Norman H.

doi:10.1021/jp9532529

Cited by 50 publications

(70 citation statements)

References 60 publications

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“…Thus, often, experimental ZFS parameters have been obtained but their formal relationship to the three-dimensional structure has remained unclear. 8,12,13 It is, therefore, highly desirable to implement accurate first-principle methods which allow a direct mapping of the ZFS parameters to their corresponding crystallographic structures. This in turn will provide a much needed link between spectroscopy and molecular structure.…”

Section: Theoretical Methodsmentioning

confidence: 99%

First-principle computation of zero-field splittings: Application to a high valent Fe(IV)-oxo model of nonheme iron proteins

Aquino

Rodriguez

2005

The Journal of Chemical Physics

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We report the computational implementation of a combined spin-density-functional theory and perturbation theory ͑SDFT-PT͒ methodology for the accurate calculation of zero-field splittings ͑ZFS͒ in complexes of the most diverse nature including metal centers in proteins. We have applied the SDFT-PT methodology to study the cation of the recently synthesized complex ͓Fe IV ͑O͒-͑TMC͒͑NCCH 3 ͔͒͑OTf͒ 2 , ͓J. Rohde et al., Science 299, 1037 ͑2003͔͒ which is an important structural and functional analog of high-valent intermediates in catalytic cycles of nonheme iron enzymes. The calculated value ͑D Theory = 28.67 cm −1 ͒ is in excellent agreement with the unusually large ZFS reported by experiment ͑D Exp =29±3 cm −1 ͒. The principal component D zz of the ZFS tensor is oriented along the Fe IV = oxo bond indicating that the oxo ligand dominates the electronic structure of the complex.

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Section: Theoretical Methodsmentioning

confidence: 99%

First-principle computation of zero-field splittings: Application to a high valent Fe(IV)-oxo model of nonheme iron proteins

Aquino

Rodriguez

2005

The Journal of Chemical Physics

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“…[24,30] Large electric quadrupole splittings of more than 1 mm s À1 are known to occur for Fe III 2 (m-oxo) dimers. [16,17,33,34] It is the asymmetry in 3d occupation due to the short covalent Fe ± oxo bond which gives rise to the large efg.…”

mentioning

confidence: 99%

The Molecular and Electronic Structure of Octahedral Tris(phenolato)iron(III) Complexes and Their Phenoxyl Radical Analogues: A Mössbauer and Resonance Raman Spectroscopic Study

et al. 1999

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Hexadentate macrocyclic ligands containing a 1,4,7-triazacyclononane backbone and three N-bound pendent-arm phenolates form extremely stable neutral complexes with Fe III Cl 3 . The octahedral complexes [Fe III L] undergo three reversible one-electron oxidation processes to yield the mono-and dications, [FeL] and [FeL] 2 , which are stable in solution for hours, whereas the trications, [FeL] 3 , are only stable in solution on the time scale of a cyclic voltammetric experiment. These oxidations are shown to be ligand-rather than metal-centered. Three coordinated phenoxyl radicals are formed successively as shown conclusively by Mössbauer spectroscopy. The neutral, mono-, di-, and tricationic species each contain an octahedral, high-spin ferric ion (S Fe 5 2), which is intramolecularly, antiferromagnetically coupled to the spin (S 1 2) of the bound phenoxyl ligands to yield an S t 2 ground state for the monocation, and an S t 3 2 ground state for the dications as shown by EPR spectroscopy. The vibrations of the coordinated phenolate are observed by resonance Raman (RR) spectroscopy by excitation in resonance with the phenolate-to-iron charge-transfer (CT) transition above 500 nm or, alternatively, of the coordinated phenoxyl by excitation in resonance with the intraligand p 3p* transition at about 410 nm. Use of 18 O isotopomers selectively labeled at the phenolic oxygen allowed the identification of the C À O stretching and Fe À O stretching and bending modes. It is shown that the substitution pattern of phenolates and phenoxyls in their respective ortho and para positions and the charge of the complexes have a pronounced influence on the vibrational modes observed.

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“…This does not necessarily indicate the formation of Fe IV ; the large g shifts owe their origin to level mixing of the ground state doublet with excited quadruplet due to competing exchange and ZFS, similar to what was found for 2. This situation resembles moderately strong coupled high-spin Fe III /Fe II dimers (S 1 ϭ 5 / 2 , S 2 ϭ 2) as found in the OH-bridged diiron cores of purpleacid phosphatases, methane monooxygenase, and related model compounds [10] where the g values span the large range 1.5Ϫ2. We achieved a quantitative interpretation of the g values of oxidized 2 from a corresponding spin-Hamiltonian approach based on the simplified coupling scheme shown in Scheme 3 by using Equation (1) into the oxidized system with S 2 ϭ S* ϭ S Fe ϩ S rad using spin projection techniques [11] : D 2 ϭ 2.13 cm…”

Section: X-band Epr Spectra Of Oxidized 1 Andmentioning

confidence: 53%

Exchange Interactions and Covalency in Dinuclear Complexes of Iron(III) and Gallium(III) Containing the Redox‐Noninnocent Ligand 1,2‐Bis(3,5‐di‐tert‐butyl‐2‐hydroxyphenyl)oxamide

et al. 2003

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Mössbauer Spectroscopy of the Spin-Coupled Fe³⁺−Fe²⁺ Center of Reduced Uteroferrin

Cited by 50 publications

References 60 publications

First-principle computation of zero-field splittings: Application to a high valent Fe(IV)-oxo model of nonheme iron proteins

First-principle computation of zero-field splittings: Application to a high valent Fe(IV)-oxo model of nonheme iron proteins

The Molecular and Electronic Structure of Octahedral Tris(phenolato)iron(III) Complexes and Their Phenoxyl Radical Analogues: A Mössbauer and Resonance Raman Spectroscopic Study

Exchange Interactions and Covalency in Dinuclear Complexes of Iron(III) and Gallium(III) Containing the Redox‐Noninnocent Ligand 1,2‐Bis(3,5‐di‐tert‐butyl‐2‐hydroxyphenyl)oxamide

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Mössbauer Spectroscopy of the Spin-Coupled Fe3+−Fe2+ Center of Reduced Uteroferrin

Cited by 50 publications

References 60 publications

First-principle computation of zero-field splittings: Application to a high valent Fe(IV)-oxo model of nonheme iron proteins

First-principle computation of zero-field splittings: Application to a high valent Fe(IV)-oxo model of nonheme iron proteins

The Molecular and Electronic Structure of Octahedral Tris(phenolato)iron(III) Complexes and Their Phenoxyl Radical Analogues: A Mössbauer and Resonance Raman Spectroscopic Study

Exchange Interactions and Covalency in Dinuclear Complexes of Iron(III) and Gallium(III) Containing the Redox‐Noninnocent Ligand 1,2‐Bis(3,5‐di‐tert‐butyl‐2‐hydroxyphenyl)oxamide

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Mössbauer Spectroscopy of the Spin-Coupled Fe³⁺−Fe²⁺ Center of Reduced Uteroferrin