Insights into the Induced Ultrafast Electron Delocalization in Fe(CO)<sub>5</sub> Using Dark Channel Fluorescence Yield X‐Ray Absorption

Stalinski, Tom; Aziz, Emad F.

doi:10.1002/cphc.201100243

Cited by 11 publications

(19 citation statements)

References 43 publications

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“…So far, the lifetime broadening of conventional K‐edge XAS experiments limits their applicability for probing the LUMO states. On the other hand, in L‐edge XAS3 a more intense 2p→nd transition can be used,4 but because of the use of low‐energy radiation, in situ studies of catalytic reactions are not possible with this technique. Therefore, a hard X‐ray technique with a better resolution of the final d‐states than in conventional XAS is required to probe the electronic structure of catalysts in situ.…”

Section: Methodsmentioning

confidence: 99%

Probing the Electronic Structure of Substituted Ferrocenes with High‐Resolution XANES Spectroscopy

Atkins

Jacob

Bauer

2012

Chemistry A European J

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Bridging the gap: High energy resolution fluorescence detected X‐ray absorption near edge structure (HERFD‐XANES) in combination with TD‐DFT calculations makes it possible to probe the electronic structure of substituted ferrocene compounds and to make the influence of substituents visible. This opens the door to in situ HERFD‐XANES studies of catalytic mechanisms in transition‐metal chemistry (see figure).

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Section: Methodsmentioning

confidence: 99%

Probing the Electronic Structure of Substituted Ferrocenes with High‐Resolution XANES Spectroscopy

Atkins

Jacob

Bauer

2012

Chemistry A European J

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“…In the context of "dark channel fluorescence yield" Aziz et al interpreted this orbital mixing as supportive for the assertion of ultrafast electron transfer from the metal d-orbitals to the solvent as deduced from the metal-ion L-edge spectra (21). This electron transfer would occur during the core-hole lifetime of core-excited state in the metal-ion: As the electron excited upon x-ray absorption would have transferred to the solvent, the corresponding fluorescence decay channel would be quenched leaving a dip in the metal-ion L-edge spectrum (21)(22)(23)(24). It was claimed that the transfer would be the more efficient and correspondingly the dip would be the deeper, the stronger the orbital overlap between the metal d-orbitals and the solvent orbitals would be.…”

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confidence: 99%

“…They found features in the total fluorescence yield (TFY) spectra when scanning the L-edges of 3d transition metal ions and complexes in solution at high concentration that dip below the fluorescence background of the solvent. It was claimed that this could be used as a new tool to study charge transfer to solvent effects (21)(22)(23)(24). The dips where attributed, first, to ultrafast electron transfer from the metal d-orbitals to the solvent (21)(22)(23)(24) and, second, to a competition of solute and solvent fluorescence (25).…”

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“…It was claimed that this could be used as a new tool to study charge transfer to solvent effects (21)(22)(23)(24). The dips where attributed, first, to ultrafast electron transfer from the metal d-orbitals to the solvent (21)(22)(23)(24) and, second, to a competition of solute and solvent fluorescence (25). Earlier, Näslund et al proposed strong orbital mixing between the 3d orbitals of Fe ions solvated in water based on an analysis of the O K-edge absorption spectrum of aqueous solutions (26) without making a connection to any charge transfer.…”

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Dissecting Local Atomic and Intermolecular Interactions of Transition-Metal Ions in Solution with Selective X-ray Spectroscopy

Wernet

Kunnus

Schreck

et al. 2012

J. Phys. Chem. Lett.

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Determining covalent and charge-transfer contributions to bonding in solution has remained an experimental challenge. Here the quenching of fluorescence-decay channels as expressed in dips in the L-edge x-ray spectra of solvated 3d transition-metal ions and complexes was reported as a probe. With a full set of experimental and theoretical ab initio L-edge x-ray spectra of aqueous Cr 3+ including resonant inelastic x-ray scattering we address covalency and charge-transfer for this prototypical transition-metal ion in solution. We dissect local atomic effects from intermolecular interactions and quantify x-ray optical effects. We find no evidence for the asserted ultrafast charge-transfer to the solvent and show that the dips are readily explained by xray optical effects and local atomic state dependence of the fluorescence yield. Instead we find, besides ionic interactions, a covalent contribution to the bonding in the aqueous complex of ligand to metal charge transfer character. 3 TOC Graphic:KEYWORDS Charge transfer to solvent, dark channel fluorescence yield, inverse partial fluorescence yield, total fluorescence yield, resonant inelastic x-ray scattering, transition metal ion, aqueous solution. 4The transfer of charge from a solvated ion or molecular complex to the surrounding solvent is an elementary step in numerous reactions in nature and in technological processes. Understanding charge transfer to solvent effects in molecular systems is thus of primary importance and x-ray spectroscopy with its specificity to elemental and chemical sites promises to add a new suite of powerful tools for their investigation (1). Specifically, time-resolved x-ray spectroscopy (2-11) appears to be the most direct way of probing charge transfer initiated by a pump pulse and probed as a function of time by scanning the delay of a short x-ray probe pulse. However, such effects can proceed on the few-femtosecond time scale and it is currently very challenging to achieve a corresponding time-resolution in pump-probe x-ray spectroscopy experiments.Therefore, it has been attempted to make use of the core-hole lifetime of a few femtoseconds to study ultrafast charge transfer processes for various systems such as for adsorbates on surfaces (12-18), ice (19) and aqueous solutions (20). Using resonant soft x-ray spectroscopy a coreelectron is excited into an unoccupied state of the system and the probability for it to transfer to the surroundings during the few-femtosecond core-hole lifetime will influence the core-hole decay channels. The Auger decay signal is thus the stronger, the higher the probability for its transfer to the surrounding medium during the core-hole lifetime is (15,17,18).As core-excited states can decay via Auger-electron ejection or fluorescence, the question arises whether such ultrafast electron-transfer processes are observable in the fluorescence decay channel as well. This relates to the more general questions as to whether and how bonding and charge-transfer processes can be revealed by with x-ray sp...

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“…Such reduction of the L 3 intensity in TFY-XA spectra at the L-edge of 3-d transition metals in aqueous solution has recently been correlated with ultrafast charge-transfer processes to the solvent. [23][24][25] Orbital mixing leads to electron delocalization between the valence d-orbitals of the transition metal and the valence bands of the solvent molecules, quenching some of the metal X-ray fluorescence bands. 26 It was argued that electron delocalization which contributes to the non-radiative process is faster than L 3 core-hole life time (2 fs) 14 and slower than the L 2 one (0.7 fs), 14 affecting accordingly mainly the L 3 -edge.…”

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Ligand discrimination of myoglobin in solution: an iron L-edge X-ray absorption study of the active centre

et al. 2013

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Iron L-edge X-ray absorption spectra of the active centre of myoglobin in the met-form, in the reduced form and upon ligation to O2, CO, NO and CN are presented. The strength of ligation with the iron centre is finger-printed through the variation of the L3 : L2 intensity ratio. Charge Transfer Multiplet calculations are performed and give qualitative information about oxidation states as well as charge transfer.

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Insights into the Induced Ultrafast Electron Delocalization in Fe(CO)₅ Using Dark Channel Fluorescence Yield X‐Ray Absorption

Cited by 11 publications

References 43 publications

Probing the Electronic Structure of Substituted Ferrocenes with High‐Resolution XANES Spectroscopy

Probing the Electronic Structure of Substituted Ferrocenes with High‐Resolution XANES Spectroscopy

Dissecting Local Atomic and Intermolecular Interactions of Transition-Metal Ions in Solution with Selective X-ray Spectroscopy

Ligand discrimination of myoglobin in solution: an iron L-edge X-ray absorption study of the active centre

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Insights into the Induced Ultrafast Electron Delocalization in Fe(CO)5 Using Dark Channel Fluorescence Yield X‐Ray Absorption

Cited by 11 publications

References 43 publications

Probing the Electronic Structure of Substituted Ferrocenes with High‐Resolution XANES Spectroscopy

Probing the Electronic Structure of Substituted Ferrocenes with High‐Resolution XANES Spectroscopy

Dissecting Local Atomic and Intermolecular Interactions of Transition-Metal Ions in Solution with Selective X-ray Spectroscopy

Ligand discrimination of myoglobin in solution: an iron L-edge X-ray absorption study of the active centre

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Insights into the Induced Ultrafast Electron Delocalization in Fe(CO)₅ Using Dark Channel Fluorescence Yield X‐Ray Absorption