Probing Transient Valence Orbital Changes with Picosecond Valence-to-Core X-ray Emission Spectroscopy

March, Anne Marie; Assefa, Tadesse; Boemer, Christina; Bressler, Christian; Britz, Alexander; Diez, Michael; Doumy, Gilles; Galler, Andreas; Harder, Manuel; Khakhulin, Dmitry; Németh, Zoltán; Pápai, Mátyás; Schulz, Sebastian; Southworth, Stephen H.; Yavaş, Hasan; Young, Linda; Gawełda, Wojciech; Vankó, György

doi:10.1021/acs.jpcc.6b12940

Cited by 28 publications

(23 citation statements)

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“…Comparative studies of vtc‐XES have been performed for different molecular complexes of first‐row transition metals such as titanium, 20–23 vanadium, 24 chromium, 25,26 manganese, 27–30 iron, 16,17 and cobalt 31 . Additionally, vtc‐XES has been applied to the study of 4d metals such as molybdenum 32 and niobium, 33 while groups at the Advanced Photon Source (APS) and the Linac Coherent Light Source (LCLS) extended vtc‐XES to the time domain by probing the dynamics of valence electrons in iron containing complexes 34–36 …”

Section: Introductionmentioning

confidence: 99%

“…31 Additionally, vtc-XES has been applied to the study of 4d metals such as molybdenum 32 and niobium, 33 while groups at the Advanced Photon Source (APS) and the Linac Coherent Light Source (LCLS) extended vtc-XES to the time domain by probing the dynamics of valence electrons in iron containing complexes. [34][35][36] To date, most vtc-XES measurements have been performed at high-brightness user facilities, such as synchrotrons, while a few groups have developed laboratory-based systems. [37][38][39][40][41][42][43][44] A constant in all previous vtc-XES measurements is the use of wavelength dispersive detection techniques, where specially designed gratings or crystals are used to spatially separate the different photon energies in the emission spectrum.…”

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Valence‐to‐core X‐ray emission spectroscopy of titanium compounds using energy dispersive detectors

et al. 2020

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X-ray emission spectroscopy (XES) of transition metal compounds is a powerful tool for investigating the spin and oxidation state of the metal centers. Valence-to-core (vtc) XES is of special interest, as it contains information on the ligand nature, hybridization, and protonation. To date, most vtc-XES studies have been performed with high-brightness sources, such as synchrotrons, due to the weak fluorescence lines from vtc transitions. Here, we present a systematic study of the vtc-XES for different titanium compounds in a laboratory setting using an X-ray tube source and energy dispersive microcalorimeter sensors. With a full-width at half-maximum energy resolution of approximately 4 eV at the Ti Kβ lines, we measure the XES features of different titanium compounds and compare our results for the vtc line shapes and energies to previously published and newly acquired synchrotron data as well as to new theoretical calculations. Finally, we report simulations of the feasibility of performing time-resolved vtc-XES studies with a laser-based plasma source in a laboratory setting. Our results show that microcalorimeter sensors can already perform high-quality measurements of vtc-XES features in a laboratory setting under static conditions and that dynamic measurements will be possible in the future after reasonable technological developments. 1 | INTRODUCTION Non-resonant X-ray emission spectroscopy (XES) is a powerful technique for the study of occupied electron orbitals in the valence shell with elemental selectivity and under in situ conditions. 1-8 In XES, X-ray photons with energy greater than the binding energy of an innershell electron produce core-hole vacancies. These core holes are quickly filled by the relaxation of less tightly bound electrons with concomitant X-ray fluorescence or

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Section: Introductionmentioning

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Valence‐to‐core X‐ray emission spectroscopy of titanium compounds using energy dispersive detectors

et al. 2020

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“…More challenging has been the use of iron, the first-row congener of ruthenium. An enormous number of low-spin (LS) Fe(II) complexes are known, including the thoroughly studied Fe(II) polypyridyl complexes [Fe(bpy)3] 2+ 6-8 and [Fe(terpy)2] 2+ [9][10][11][12] . Their absorption spectra are dominated by strong MLCT transitions in the visible regime, however, these Fe(II)-based complexes have been difficult to employ in solar energy conversion schemes 5 due primarily to the fact the MLCT states convert to lower-lying metal-centered ligand-field (LF) states on the ~100 fs timescale 8,[13][14][15][16] .…”

Section: Introductionmentioning

confidence: 99%

Using Ultrafast X-ray Spectroscopy To Address Questions in Ligand-Field Theory: The Excited State Spin and Structure of [Fe(dcpp)₂]²⁺

et al. 2019

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“…In this study, we address the ambiguity in the average germanium CN in compressed amorphous GeO 2 by a new approach on the basis of measured and computed valenceto-core x-ray emission spectroscopy (VTC XES) spectra of compressed GeO 2 . VTC XES has been mostly applied to 3d transition metal molecular complexes, where it is known to provide insight into the spin state and the type of the bonding ligand [25][26][27][28][29][30][31][32][33][34]. There have been only a few studies on nonmolecular crystalline compounds [35][36][37][38][39].…”

Section: Introductionmentioning

confidence: 99%

Persistent Octahedral Coordination in Amorphous GeO2 Up to 100 GPa by Kβ′′
Spiekermann
¹
,
Harder
²
,
Gilmore
³

et al. 2019
Phys. Rev. X
20
2
25
0
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We measure valence-to-core x-ray emission spectra of compressed crystalline GeO 2 up to 56 GPa and of amorphous GeO 2 up to 100 GPa. In a novel approach, we extract the Ge coordination number and mean Ge-O distances from the emission energy and the intensity of the Kβ 00 emission line. The spectra of high-pressure polymorphs are calculated using the Bethe-Salpeter equation. Trends observed in the experimental and calculated spectra are found to match only when utilizing an octahedral model. The results reveal persistent octahedral Ge coordination with increasing distortion, similar to the compaction mechanism in the sequence of octahedrally coordinated crystalline GeO 2 high-pressure polymorphs.

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Probing Transient Valence Orbital Changes with Picosecond Valence-to-Core X-ray Emission Spectroscopy

Cited by 28 publications

References 43 publications

Valence‐to‐core X‐ray emission spectroscopy of titanium compounds using energy dispersive detectors

Valence‐to‐core X‐ray emission spectroscopy of titanium compounds using energy dispersive detectors

Using Ultrafast X-ray Spectroscopy To Address Questions in Ligand-Field Theory: The Excited State Spin and Structure of [Fe(dcpp)₂]²⁺

Persistent Octahedral Coordination in Amorphous GeO2 Up to 100 GPa by Kβ′′
Spiekermann
¹
,
Harder
²
,
Gilmore
³

et al. 2019
Phys. Rev. X
20
2
25
0
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Probing Transient Valence Orbital Changes with Picosecond Valence-to-Core X-ray Emission Spectroscopy

Cited by 28 publications

References 43 publications

Valence‐to‐core X‐ray emission spectroscopy of titanium compounds using energy dispersive detectors

Valence‐to‐core X‐ray emission spectroscopy of titanium compounds using energy dispersive detectors

Using Ultrafast X-ray Spectroscopy To Address Questions in Ligand-Field Theory: The Excited State Spin and Structure of [Fe(dcpp)2]2+

Persistent Octahedral Coordination in Amorphous GeO2 Up to 100 GPa by Kβ′′Spiekermann1, Harder2, Gilmore3 et al. 2019Phys. Rev. X202250View full textAdd to dashboardCite

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Using Ultrafast X-ray Spectroscopy To Address Questions in Ligand-Field Theory: The Excited State Spin and Structure of [Fe(dcpp)₂]²⁺

Persistent Octahedral Coordination in Amorphous GeO2 Up to 100 GPa by Kβ′′
Spiekermann
¹
,
Harder
²
,
Gilmore
³

et al. 2019
Phys. Rev. X
20
2
25
0
View full text Add to dashboard Cite