Prediction of Iron K-Edge Absorption Spectra Using Time-Dependent Density Functional Theory

DeBeer, Serena; Petrenko, Taras; Neese, Frank

doi:10.1021/jp803174m

Cited by 254 publications

(330 citation statements)

References 45 publications

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“…The well-defined absorption feature clearly visible in all spectra is characteristic of the Fe K-edge and is known to arise from the 1s -> 3d transition. 19 The superimposition of the pre-edge of the sample and reference signals bring to an analogous result coming from the comparison between the edge positions ( fig.1). Noticeably, both the shape and the position of the pre-edge of the experimental data are in agreement to the signal of Fe 3+ and don't fit the Fe 2+ signal.…”

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confidence: 76%

Structure of the FeBTC Metal–Organic Framework: A Model Based on the Local Environment Study

et al. 2015

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The local environment of iron in FeBTC, a metal organic framework commercially known as Basolite F300, is investigated combining XANES and EXAFS studies of the iron Kedge. The building block of the FeBTC can be described as an iron acetate moiety. Dehydration induces a change in the coordination of the first shell while preserving the network. We propose that the local structure around Fe atoms does not undergo a rearrangement, thus leading to the formation of an open site. The analysis conveys that the FeBTC is a disordered network of locally ordered blocks.

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confidence: 76%

Structure of the FeBTC Metal–Organic Framework: A Model Based on the Local Environment Study

et al. 2015

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“…In addition, the present analysis enables us to quantify the magnitude of the heme doming in the unligated form (deoxyMb). Finally, the electronic structure is investigated using the pre-edge structures, analysed with time-dependent density functional theory (TD-DFT), 61,62 implemented within the ORCA quantum chemistry package. 63,64 We find that these features are predominantly 1s -d s and 1s -d p À p ligand * transitions, while 1s -d p transitions also weakly contribute for MbO 2 , metMb and deoxyMb.…”

Section: Introductionmentioning

confidence: 99%

Probing the electronic and geometric structure of ferric and ferrous myoglobins in physiological solutions by Fe K-edge absorption spectroscopy

Lima

Penfold

Veen

et al. 2014

Phys. Chem. Chem. Phys.

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We present an iron K-edge X-ray absorption study of carboxymyoglobin (MbCO), nitrosylmyoglobin (MbNO), oxymyoglobin (MbO 2 ), cyanomyoglobin (MbCN), aquomet myoglobin (metMb) and unligated myoglobin (deoxyMb) in physiological media. The analysis of the XANES region is performed using the full-multiple scattering formalism, implemented within the MXAN package. This reveals trends within the heme structure, absent from previous crystallographic and X-ray absorption analysis. In particular, the iron-nitrogen bond lengths in the porphyrin ring converge to a common value of about 2 Å, except for deoxyMb whose bigger value is due to the doming of the heme. The trends of the Fe-N e (His93) bond length is found to be consistent with the effect of ligand binding to the iron, with the exception of MbNO, which is explained in terms of the repulsive trans effect. We derive a high resolution description of the relative geometry of the ligands with respect to the heme and quantify the magnitude of the heme doming in the deoxyMb form. Finally, time-dependent density functional theory is used to simulate the pre-edge spectra and is found to be in good agreement with the experiment. The XAS spectra typically exhibit one pre-edge feature which arises from transitions into the unoccupied d s and d p À p ligand * orbitals. 1s -d p transitions contribute weakly for MbO 2 , metMb and deoxyMb.However, despite this strong Fe d contribution these transitions are found to be dominated by the dipole (1s -4p) moment due to the low symmetry of the heme environment.

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“…Details on the Computational Methodology are given in the corresponding section below. We note that an empirical, methoddependent constant shift has to be applied in order to align the calculated spectra with experiment [32,33]. Here, a consistent shift has been applied to all spectra calculated with the same method, even though different types of complexes (e.g., with different charge states) might require a different shift [33,34].…”

Section: Interpretation Of Cu K-edge Xas Spectra: Copper Ammine Modelmentioning

confidence: 99%

Revisiting the Dependence of Cu K-Edge X-Ray Absorption Spectra on Oxidation State and Coordination Environment

Rudolph¹,

Jacob²

2018

Preprint

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X-ray absorption spectroscopy (XAS) at the Cu K-edge is an important tool for probing the properties of copper centers in transition metal chemistry and catalysis.However, the interpretation of experimental XAS spectra requires a detailed understanding of the dependence of spectroscopic features on the local geometric and electronic structure, which can be established by theoretical X-ray spectroscopy.Here, we present a systematic computational study of the Cu K-edge XAS spectra of selected Cu complexes based on time-dependent density-functional theory in combination with a molecular orbital analysis of the relevant transitions. For a series of Cu ammine model complexes as well as a comprehensive test set of 12 Cu(I) and 5 Cu(II) complexes, we revisit the dependence of the pre-edge region in Cu K-edge XAS spectra on oxidation state and coordination geometry. While our calculations confirm earlier experimental assignments, we can also reveal additional signatures of the ligand orbitals and identify the underlying orbital interactions.The comprehensive picture provided by this study will provide a reliable basis for the interpretation of in situ Cu K-edge XAS spectra of catalytic intermediates.2

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Prediction of Iron K-Edge Absorption Spectra Using Time-Dependent Density Functional Theory

Cited by 254 publications

References 45 publications

Structure of the FeBTC Metal–Organic Framework: A Model Based on the Local Environment Study

Structure of the FeBTC Metal–Organic Framework: A Model Based on the Local Environment Study

Probing the electronic and geometric structure of ferric and ferrous myoglobins in physiological solutions by Fe K-edge absorption spectroscopy

Revisiting the Dependence of Cu K-Edge X-Ray Absorption Spectra on Oxidation State and Coordination Environment

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