Your search keyword '"Sahle, Christoph"' showing total 6 results

1. Generating interstitial water within the persisting tetrahedral H-bond network explains density increase upon compressing liquid water.

Author

Förster, Mirko, Ukoji, Nnanna, Sahle, Christoph J., Niskanen, Johannes, Sakrowski, Robin, Surmeier, Göran, Weis, Christopher, Irifune, Tetsuo, Sho Imoto, Yavas, Hasan, Huotari, Simo, Marx, Dominik, Sternemann, Christian, and Tse, John S.

Subjects

X-ray scattering, RAMAN scattering, PORE water, MOLECULAR dynamics, EXCITATION spectrum

Abstract

Despite its ubiquitous nature, the atomic structure of water in its liquid state is still controversially debated. We use a combination of X-ray Raman scattering spectroscopy in conjunction with ab initio and path integral molecular dynamics simulations to study the local atomic and electronic structure of water under high pressure conditions. Systematically increasing fingerprints of non-hydrogen-bonded H2O molecules in the first hydration shell are identified in the experimental and computational oxygen K-edge excitation spectra. This provides evidence for a compaction mechanism in terms of a continuous collapse of the second hydration shell with increasing pressure via generation of interstitial water within locally tetrahedral hydrogen-bonding environments. [ABSTRACT FROM AUTHOR]

Published

2024

2. Deciphering the Origin of Interface‐Induced High Li and Na Ion Conductivity in Nanocomposite Solid Electrolytes Using X‐Ray Raman Spectroscopy.

Author

de Kort, Laura M., Lazemi, Masoud, Longo, Alessandro, Gulino, Valerio, Rodenburg, Henrik P., Blanchard, Didier, Sahle, Christoph, Sundermann, Martin, Gretarsson, Hlynur, van der Eerden, Ad M. J., Elnaggar, Hebatalla, de Groot, Frank M. F., and Ngene, Peter

Subjects

SOLID electrolytes, RAMAN spectroscopy, X-ray spectroscopy, INTERFACIAL reactions, RAMAN scattering, ORGANOLITHIUM compounds

Abstract

Solid‐state electrolytes (SSEs) with high ionic conductivities are crucial for safer and high‐capacity batteries. Interface effects in nanocomposites of SSEs and insulators can lead to profound increases in conductivity. Understanding the composition of the interface is crucial for tuning the conductivity of composite solid electrolytes. Herein, X‐ray Raman Scattering (XRS) spectroscopy is used for the first time to unravel the nature of the interface effects responsible for conductivity enhancements in nanocomposites of complex hydride‐based electrolytes (LiBH4, NaBH4, and NaNH2) and oxides. XRS probe of the Li, Na, and B local environments reveals that the interface consists of highly distorted/defected and structurally distinct phase(s) compared to the original compounds. Interestingly, nanocomposites with higher concentrations of the interface compounds exhibit higher conductivities. Clear differences are observed in the interface composition of SiO2‐ and Al2O3‐based nanocomposites, attributed to differences in the reactivity of their surface groups. These results demonstrate that interfacial reactions play a dominant role in conductivity enhancement in composite solid electrolytes. This work showcases the potential of XRS in investigating interface interactions, providing valuable insights into the often complex ion conductor/insulator interfaces, especially for systems containing light elements such as Li, B, and Na present in most SSEs and batteries. [ABSTRACT FROM AUTHOR]

Published

2024

3. Anomalous Impact of Mechanochemical Treatment on the Na‐ion Conductivity of Sodium Closo‐Carbadodecaborate Probed by X‐Ray Raman Scattering Spectroscopy.

Author

Gulino, Valerio, Longo, Alessandro, de Kort, Laura M., Rodenburg, Hendrik P., Murgia, Fabrizio, Brighi, Matteo, Černý, Radovan, Sahle, Christoph J., Sundermann, Martin, Gretarsson, Hlynur, de Groot, Frank, and Ngene, Peter

Subjects

IONIC conductivity, X-ray scattering, RAMAN scattering, RAMAN spectroscopy, IMPACT (Mechanics), AB-initio calculations

Abstract

Solid‐state sodium ion conductors are crucial for the next generation of all‐solid‐state sodium batteries with high capacity, low cost, and improved safety. Sodium closo‐carbadodecaborate (NaCB11H12) is an attractive Na‐ion conductor owing to its high thermal, electrochemical, and interfacial stability. Mechanical milling has recently been shown to increase conductivity by five orders of magnitude at room temperature, making it appealing for application in all‐solid‐state sodium batteries. Intriguingly, milling longer than 2 h led to a significant decrease in conductivity. In this study, X‐ray Raman scattering (XRS) spectroscopy is used to probe the origin of the anomalous impact of mechanical treatment on the ionic conductivity of NaCB11H12. The B, C, and Na K‐edge XRS spectra are successfully measured for the first time, and ab initio calculations are employed to interpret the results. The experimental and computational results reveal that the decrease in ionic conductivity upon prolonged milling is due to the increased proximity of Na to the CB11H12 cage, caused by severe distortion of the long‐range structure. Overall, this work demonstrates how the XRS technique, allowing investigation of low Z elements such as C and B in the bulk, can be used to acquire valuable information on the electronic structure of solid electrolytes and battery materials in general. [ABSTRACT FROM AUTHOR]

Published

2024

4. High-resolution nonresonant x-ray Raman scattering study on rare earth phosphate nanoparticles

Author

Huotari, Simo, Suljoti, Edlira, Sahle, Christoph J., Raedel, Stephanie, Monaco, Giulio, de Groot, Frank M. F., Inorganic Chemistry and Catalysis, Sub Inorganic Chemistry and Catalysis, Inorganic Chemistry and Catalysis, Sub Inorganic Chemistry and Catalysis, and Department of Physics

Subjects

inelastic x-ray scattering, education, General Physics and Astronomy, x-ray Raman scattering, TRANSITIONS, 02 engineering and technology, 114 Physical sciences, 01 natural sciences, Spectral line, symbols.namesake, Physics and Astronomy (all), SYSTEMS, 0103 physical sciences, non-dipole, WATER, lanthanides, 010306 general physics, Multiplet, Physics, EXCITATIONS, rare earths, 021001 nanoscience & nanotechnology, Dipole, X-ray Raman scattering, Absorption edge, Others, symbols, Density functional theory, Atomic physics, 0210 nano-technology, Multipole expansion, Raman scattering

Abstract

We report high-resolution x-ray Raman scattering studies of high-order multipole spectra of rare earth $4d\to 4f$ excitations (the ${{N}_{4,5}}$ absorption edge) in nanoparticles of the phosphates LaPO4, CePO4, PrPO4, and NdPO4. We also present corresponding data for La $5p\to 5d$ excitations (the ${{O}_{2,3}}$ edge) in LaPO4. The results are compared with those from calculations by atomic multiplet theory and for the dipole contribution to the La $4d\to 4f$ transition from a calculation using time-dependent density functional theory (TDLDA). Agreement with the atomic multiplet calculations for the high-order multiplet spectra is remarkable in the case of the ${{N}_{4,5}}$ spectra. In contrast, we find that the shallow ${{O}_{2,3}}$ semicore excitations in LaPO4 manifest a relatively broad band and an apparent quenching of $5p$ spin-orbit splitting. The more sophisticated TDLDA, which has earlier been found to explain dipolar spectra well in Ba compounds, is less satisfactory here in the case of La.

Published

2015

5. Miniature diamond anvils for X-ray Raman scattering spectroscopy experiments at high pressure.

Author

Petitgirard, Sylvain, Spiekermann, Georg, Wilke, Max, Weis, Christopher, Sternemann, Christian, and Sahle, Christoph

Subjects

DIAMONDS, ANVILS, X-rays, RAMAN scattering, HIGH pressure chemistry, SPECTRUM analysis

Abstract

X-ray Raman scattering (XRS) spectroscopy is an inelastic scattering method that uses hard X-rays of the order of 10 keV to measure energy-loss spectra at absorption edges of light elements (Si, Mg, O etc.), with an energy resolution below 1 eV. The high-energy X-rays employed with this technique can penetrate thick or dense sample containers such as the diamond anvils employed in high-pressure cells. Here, we describe the use of custom-made conical miniature diamond anvils of less than 500 µm thickness which allow pressure generation of up to 70 GPa. This set-up overcomes the limitations of the XRS technique in very high-pressure measurements (>10 GPa) by drastically improving the signal-to-noise ratio. The conical shape of the base of the diamonds gives a 70° opening angle, enabling measurements in both low- and high-angle scattering geometry. This reduction of the diamond thickness to one-third of the classical diamond anvils considerably lowers the attenuation of the incoming and the scattered beams and thus enhances the signal-to-noise ratio significantly. A further improvement of the signal-to-background ratio is obtained by a recess of ∼20 µm that is milled in the culet of the miniature anvils. This recess increases the sample scattering volume by a factor of three at a pressure of 60 GPa. Examples of X-ray Raman spectra collected at the O K-edge and Si L-edge in SiO2 glass at high pressures up to 47 GPa demonstrate the significant improvement and potential for spectroscopic studies of low- Z elements at high pressure. [ABSTRACT FROM AUTHOR]

Published

2017

6. Bulk sensitive determination of the Fe3+/FeTot-ratio in minerals by Fe L2/3-edge X-ray Raman scattering.

Author

Nyrow, Alexander, Sternemann, Christian, Tse, John S., Weis, Christopher, Sahle, Christoph J., Mende, Kolja, Wieland, D. C. Florian, Cerantola, Valerio, Gordon, Robert A., Spiekermann, Georg, Regier, Tom, Wilke, Max, and Tolan, Metin

Subjects

IRON spectra, RAMAN scattering, IRON analysis, OXIDATION states, MOSSBAUER spectroscopy, CIRCULAR dichroism

Abstract

We present the first measurements of the iron L2/3-edge of the compounds FeO, Fe2O3, and Fe3O4 at ambient pressure and of FeCO3 at high pressures of 2.4 and 40 GPa using a diamond anvil cell by X-ray Raman scattering spectroscopy, a bulk sensitive probe of soft X-ray absorption edges making use of hard X-rays. We show that the spectral shape of the Fe L2/3-edge can be analyzed quantitatively to reveal the oxidation state of iron in matter. Consequently, in situ X-ray Raman scattering spectroscopy at the iron L-edge at high pressure and temperature opens exciting perspectives to characterize the local coordination, oxidation, and spin state of iron at high pressure and temperature, conditions that are of relevance for e.g. geological sciences or chemical processing. [ABSTRACT FROM AUTHOR]

Published

2016