Your search keyword '"Hartley, N. J."' showing total 3 results

1. Demonstration of an x-ray Raman spectroscopy setup to study warm dense carbon at the high energy density instrument of European XFEL.

Author

Voigt, K., Zhang, M., Ramakrishna, K., Amouretti, A., Appel, K., Brambrink, E., Cerantola, V., Chekrygina, D., Döppner, T., Falcone, R. W., Falk, K., Fletcher, L. B., Gericke, D. O., Göde, S., Harmand, M., Hartley, N. J., Hau-Riege, S. P., Huang, L. G., Humphries, O. S., and Lokamani, M.

Subjects

RAMAN spectroscopy, X-ray spectroscopy, ENERGY density, SCIENTIFIC apparatus & instruments, MOLECULAR dynamics, FREE electron lasers

Abstract

We present a proof-of-principle study demonstrating x-ray Raman Spectroscopy (XRS) from carbon samples at ambient conditions in conjunction with other common diagnostics to study warm dense matter, performed at the high energy density scientific instrument of the European x-ray Free Electron Laser (European XFEL). We obtain sufficient spectral resolution to identify the local structure and chemical bonding of diamond and graphite samples, using highly annealed pyrolytic graphite spectrometers. Due to the high crystal reflectivity and XFEL brightness, we obtain signal strengths that will enable accurate XRS measurements in upcoming pump–probe experiments with a high repetition-rate, where the samples will be pumped with high-power lasers. Molecular dynamics simulations based on density functional theory together with XRS simulations demonstrate the potential of this technique and show predictions for high-energy-density conditions. Our setup allows simultaneous implementation of several different diagnostic methods to reduce ambiguities in the analysis of the experimental results, which, for warm dense matter, often relies on simplifying model assumptions. The promising capabilities demonstrated here provide unprecedented insights into chemical and structural dynamics in warm dense matter states of light elements, including conditions similar to the interiors of planets, low-mass stars, and other celestial bodies. [ABSTRACT FROM AUTHOR]

Published

2021

2. Spatio-temporal coherence of free-electron laser radiation in the extreme ultraviolet determined by a Michelson interferometer.

Author

Hilbert, V., Rödel, C., Brenner, G., Döppner, T., Düsterer, S., Dziarzhytski, S., Fletcher, L., Förster, E., Glenzer, S. H., Harmand, M., Hartley, N. J., Kazak, L., Komar, D., Laarmann, T., Lee, H. J., Ma, T., Nakatsutsumi, M., Przystawik, A., Redlin, H., and Skruszewicz, S.

Subjects

FREE electron lasers, LASER beams, SPATIOTEMPORAL processes, ULTRAVIOLET radiation, MICHELSON interferometer

Abstract

A key feature of extreme ultraviolet (XUV) radiation from free-electron lasers (FELs) is its spatial and temporal coherence. We measured the spatio-temporal coherence properties of monochromat-ized FEL pulses at 13.5 nm using a Michelson interferometer. A temporal coherence time of (59±8) fs has been determined, which is in good agreement with the spectral bandwidth given by the monochromator. Moreover, the spatial coherence in vertical direction amounts to about 15% of the beam diameter and about 12% in horizontal direction. The feasibility of measuring spatio-temporal coherence properties of XUV FEL radiation using interferometric techniques advances machine operation and experimental studies significantly. [ABSTRACT FROM AUTHOR]

Published

2014

3. Using Diffuse Scattering to Observe X-Ray-Driven Nonthermal Melting.

Author

Hartley, N. J., Grenzer, J., Huang, L., Inubushi, Y., Kamimura, N., Katagiri, K., Kodama, R., Kon, A., Lu, W., Makita, M., Matsuoka, T., Nakajima, S., Ozaki, N., Pikuz, T., Rode, A. V., Sagae, D., Schuster, A. K., Tono, K., Voigt, K., and Vorberger, J.

Subjects

*FREE electron lasers, *IONIC structure, *LIQUID silicon, *MELTING

Abstract

We present results from the SPring-8 Angstrom Compact free electron LAser facility, where we used a high intensity (∼1020  W/cm²) x-ray pump x-ray probe scheme to observe changes in the ionic structure of silicon induced by x-ray heating of the electrons. By avoiding Laue spots in the scattering signal from a single crystalline sample, we observe a rapid rise in diffuse scattering and a transition to a disordered, liquidlike state with a structure significantly different from liquid silicon. The disordering occurs within 100 fs of irradiation, a timescale that agrees well with first principles simulations, and is faster than that predicted by purely inertial behavior, suggesting that both the phase change and disordered state reached are dominated by Coulomb forces. This method is capable of observing liquid scattering without masking signal from the ambient solid, allowing the liquid structure to be measured throughout and beyond the phase change. [ABSTRACT FROM AUTHOR]

Published

2021