Your search keyword '"Prencipe I"' showing total 173 results

1. Measuring the structure and equation of state of polyethylene terephthalate at megabar pressures.

Author

Lütgert, J, Vorberger, J, Hartley, NJ, Voigt, K, Rödel, M, Schuster, AK, Benuzzi-Mounaix, A, Brown, S, Cowan, TE, Cunningham, E, Döppner, T, Falcone, RW, Fletcher, LB, Galtier, E, Glenzer, SH, Laso Garcia, A, Gericke, DO, Heimann, PA, Lee, HJ, McBride, EE, Pelka, A, Prencipe, I, Saunders, AM, Schölmerich, M, Schörner, M, Sun, P, Vinci, T, Ravasio, A, and Kraus, D

Abstract

We present structure and equation of state (EOS) measurements of biaxially orientated polyethylene terephthalate (PET, [Formula: see text], also called mylar) shock-compressed to ([Formula: see text]) GPa and ([Formula: see text]) K using in situ X-ray diffraction, Doppler velocimetry, and optical pyrometry. Comparing to density functional theory molecular dynamics (DFT-MD) simulations, we find a highly correlated liquid at conditions differing from predictions by some equations of state tables, which underlines the influence of complex chemical interactions in this regime. EOS calculations from ab initio DFT-MD simulations and shock Hugoniot measurements of density, pressure and temperature confirm the discrepancy to these tables and present an experimentally benchmarked correction to the description of PET as an exemplary material to represent the mixture of light elements at planetary interior conditions.

Published

2021

2. High-pressure chemistry of hydrocarbons relevant to planetary interiors and inertial confinement fusion

Author

Kraus, D., Hartley, N. J, Frydrych, S., Schuster, A. K, Rohatsch, K., Rödel, M., Cowan, T. E, Brown, S., Cunningham, E., van Driel, T., Fletcher, L. B, Galtier, E., Gamboa, E. J, Laso Garcia, A., Gericke, D. O, Granados, E., Heimann, P. A, Lee, H. J, MacDonald, M. J, MacKinnon, A. J, McBride, E. E, Nam, I., Neumayer, P., Pak, A., Pelka, A., Prencipe, I., Ravasio, A., Redmer, R., Saunders, A. M, Schölmerich, M., Schörner, M., Sun, P., Turner, S. J, Zettl, A., Falcone, R. W, Glenzer, S. H, T. Döppner, T., and Vorberger, J.

Published

2018

3. Visualizing plasmons and ultrafast kinetic instabilities in laser-driven solids using X-ray scattering

Author

(0009-0007-5067-7326) Ordyna, P., Bähtz, C., (0009-0004-2404-9412) Brambrink, E., (0000-0002-8258-3881) Bussmann, M., (0000-0002-7671-0901) Laso García, A., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Göde, S., Grenzer, J., (0000-0002-0051-8542) Gutt, C., Höppner, H., (0000-0003-1184-2097) Huang, L., Hübner, U., (0000-0001-6748-0422) Humphries, O. S., (0009-0005-6873-8292) Edward Marré, B., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0002-9933-3248) Miethlinger, T., (0000-0003-0868-4745) Nakatsutsumi, M., Öztürk, Ö., (0000-0002-3882-510X) Pan, X., (0009-0001-0047-1051) Paschke-Brühl, F.-L., (0009-0001-3308-5376) Pelka, A., (0000-0003-0931-1350) Prencipe, I., (0000-0003-1228-2263) Preston, T. R., (0000-0001-9587-404X) Randolph, L., (0000-0003-4400-1315) Schlenvoigt, H.-P., Schwinkendorf, J.-P., (0000-0002-7162-7500) Šmíd, M., (0000-0001-5007-1868) Starke, S., (0000-0002-4195-2038) Štefaníková, R., Thiessenhusen, E., (0000-0001-7986-3631) Toncian, T., (0000-0003-3926-409X) Zeil, K., (0000-0003-0390-7671) Schramm, U., (0000-0002-5845-000X) Cowan, T., (0000-0003-4861-5584) Kluge, T., (0009-0007-5067-7326) Ordyna, P., Bähtz, C., (0009-0004-2404-9412) Brambrink, E., (0000-0002-8258-3881) Bussmann, M., (0000-0002-7671-0901) Laso García, A., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Göde, S., Grenzer, J., (0000-0002-0051-8542) Gutt, C., Höppner, H., (0000-0003-1184-2097) Huang, L., Hübner, U., (0000-0001-6748-0422) Humphries, O. S., (0009-0005-6873-8292) Edward Marré, B., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0002-9933-3248) Miethlinger, T., (0000-0003-0868-4745) Nakatsutsumi, M., Öztürk, Ö., (0000-0002-3882-510X) Pan, X., (0009-0001-0047-1051) Paschke-Brühl, F.-L., (0009-0001-3308-5376) Pelka, A., (0000-0003-0931-1350) Prencipe, I., (0000-0003-1228-2263) Preston, T. R., (0000-0001-9587-404X) Randolph, L., (0000-0003-4400-1315) Schlenvoigt, H.-P., Schwinkendorf, J.-P., (0000-0002-7162-7500) Šmíd, M., (0000-0001-5007-1868) Starke, S., (0000-0002-4195-2038) Štefaníková, R., Thiessenhusen, E., (0000-0001-7986-3631) Toncian, T., (0000-0003-3926-409X) Zeil, K., (0000-0003-0390-7671) Schramm, U., (0000-0002-5845-000X) Cowan, T., and (0000-0003-4861-5584) Kluge, T.

Abstract

Ultra-intense lasers that ionize atoms and accelerate electrons in solids to near the speed of light can lead to kinetic instabilities that alter the laser absorption and subsequent electron transport, isochoric heating, and ion acceleration. These instabilities can be difficult to characterize, but X-ray scattering at keV photon energies allows for their visualization with femtosecond temporal resolution on the few nanometer mesoscale. Here, we perform such experiment on laser-driven flat silicon membranes that shows the development of structure with a dominant scale of 60 nm in the plane of the laser axis and laser polarization, and 95 nm in the vertical direction with a growth rate faster than 0.1 fs−1 . Combining the XFEL experiments with simulations provides a complete picture of the structural evolution of ultra-fast laser-induced plasma density development, indicating the excita- tion of plasmons and a filamentation instability. Particle-in-cell simulations confirm that these signals are due to an oblique two-stream filamentation instability. These findings provide new insight into ultra-fast instability and heating processes in solids under extreme conditions at the nanometer level with possible implications for laser particle acceleration, inertial confinement fusion, and laboratory astrophysics.

Published

2024

4. Absolute energy-dependent scintillating screen calibration for real-time detection of laser-accelerated proton bunches

Author

(0009-0004-0743-4087) Schilz, J. D., (0000-0001-8205-8422) Bodenstein, E., (0000-0002-9859-2408) Brack, F.-E., (0000-0003-0707-0856) Horst, F., (0000-0002-4626-0049) Irman, A., (0000-0002-0275-9892) Kroll, F., (0000-0003-4128-5498) Pawelke, J., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0002-2769-4749) Schöbel, S., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., (0000-0002-9556-0662) Metzkes-Ng, J., (0009-0004-0743-4087) Schilz, J. D., (0000-0001-8205-8422) Bodenstein, E., (0000-0002-9859-2408) Brack, F.-E., (0000-0003-0707-0856) Horst, F., (0000-0002-4626-0049) Irman, A., (0000-0002-0275-9892) Kroll, F., (0000-0003-4128-5498) Pawelke, J., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0002-2769-4749) Schöbel, S., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., and (0000-0002-9556-0662) Metzkes-Ng, J.

Abstract

Laser-plasma accelerators (LPAs) can deliver pico- to nanosecond long proton bunches, with ≥∼100 nC of charge dispersed over a broad energy spectrum. Increasing the repetition rates of today’s LPAs is a necessity for their practical application. This, however, creates a need for real-time proton bunch diagnostics. Scintillating screens are one detector solution, commonly applied in the field of electron LPAs for spatially resolved particle and radiation detection, yet their establishment for LPA proton detection is only slowly taking off. This is also due to the lack of available calibrations. In this paper, we present an absolute proton number calibration for the scintillating screen type DRZ High (Mitsubishi Chemical Corporation, Düsseldorf, Germany), one of the most sensitive screens according to calibrations for relativistic electrons and x-rays. For proton irradiation of the DRZ High screen, we find an increase in light yield of >60% compared to reference calibration data for relativistic electrons. The presented absolute light yield calibration shows an uncertainty of the proton number of 10% and can seamlessly be applied at other LPA facilities. Moreover, we investigate the scintillating screen light yield dependence on proton energy, since many types of scintillators (e.g., plastic, liquid, inorganic) show a reduced light yield for increased local energy deposition densities, an effect termed ionization quenching. The ionization quenching can reduce the light yield for low-energy protons by up to ∼20%. This work provides all necessary data for absolute spectral measurements of LPA protons with DRZ High scintillating screens, e.g., when these are used as detectors in the commonly available Thomson parabola spectrometers.

Published

2024

5. Data publication: Absolute energy-dependent scintillating screen calibration for real-time detection of laser-accelerated proton bunches

Author

(0009-0004-0743-4087) Schilz, J. D., (0000-0001-8205-8422) Bodenstein, E., (0000-0002-9859-2408) Brack, F.-E., (0000-0003-0707-0856) Horst, F., (0000-0002-4626-0049) Irman, A., (0000-0002-0275-9892) Kroll, F., (0000-0003-4128-5498) Pawelke, J., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0002-2769-4749) Schöbel, S., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., (0000-0002-9556-0662) Metzkes-Ng, J., (0009-0004-0743-4087) Schilz, J. D., (0000-0001-8205-8422) Bodenstein, E., (0000-0002-9859-2408) Brack, F.-E., (0000-0003-0707-0856) Horst, F., (0000-0002-4626-0049) Irman, A., (0000-0002-0275-9892) Kroll, F., (0000-0003-4128-5498) Pawelke, J., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0002-2769-4749) Schöbel, S., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., and (0000-0002-9556-0662) Metzkes-Ng, J.

Abstract

All necessary Data to recreate the published plots and images in the publication: "Absolute energy-dependent scintillating screen calibration for real-time detection of laser-accelerated proton bunches". Included are the raw scintillating screen images, the plotting data and Python Scripts used for calculations and plotting.

Published

2024

6. Laser-driven high-energy proton beams from cascaded acceleration regimes

Author

(0000-0002-3727-7017) Ziegler, T., Göthel, I., (0000-0002-6928-2048) Assenbaum, S., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0003-0420-3940) Dover, N. P., (0000-0002-6914-4083) Gaus, L., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-8143-0827) Nishiuchi, M., (0000-0003-0931-1350) Prencipe, I., (0000-0002-4738-6436) Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., (0000-0002-3727-7017) Ziegler, T., Göthel, I., (0000-0002-6928-2048) Assenbaum, S., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0003-0420-3940) Dover, N. P., (0000-0002-6914-4083) Gaus, L., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-8143-0827) Nishiuchi, M., (0000-0003-0931-1350) Prencipe, I., (0000-0002-4738-6436) Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0003-0390-7671) Schramm, U., and (0000-0003-3926-409X) Zeil, K.

Abstract

Laser-driven ion accelerators can deliver high-energy, high-peak current beams and are thus attracting attention as a compact alternative to conventional accelerators. However, achieving sufficiently high energy levels suitable for applications such as radiation therapy remains a challenge for laser-driven ion accelerators. Here we generate proton beams with a spectrally separated high-energy component of up to 150 MeV by irradiating solid-density plastic foil targets with ultrashort laser pulses from a repetitive petawatt laser. The preceding laser light heats the target, leading to the onset of relativistically induced transparency upon main pulse arrival. The laser peak then penetrates the initially opaque target and triggers proton acceleration through a cascade of different mechanisms, as revealed by three-dimensional particle-in-cell simulations. The transparency of the target can be used to identify the high-performance domain, making it a suitable feedback parameter for automated laser and target optimization to enhance stability of plasma accelerators in the future.

Published

2024

7. Source Data: Laser-driven high-energy proton beams from cascaded acceleration regimes

Author

(0000-0002-3727-7017) Ziegler, T., Göthel, I., (0000-0002-6928-2048) Assenbaum, S., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0003-0420-3940) Dover, N. P., (0000-0002-6914-4083) Gaus, L., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-8143-0827) Nishiuchi, M., (0000-0003-0931-1350) Prencipe, I., (0000-0002-4738-6436) Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., (0000-0002-3727-7017) Ziegler, T., Göthel, I., (0000-0002-6928-2048) Assenbaum, S., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0003-0420-3940) Dover, N. P., (0000-0002-6914-4083) Gaus, L., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-8143-0827) Nishiuchi, M., (0000-0003-0931-1350) Prencipe, I., (0000-0002-4738-6436) Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0003-0390-7671) Schramm, U., and (0000-0003-3926-409X) Zeil, K.

Abstract

This dataset contains all source data used to generate figures and all other findings of the publication: "Laser-driven high-energy proton beams from cascaded acceleration regimes".

Published

2024

8. Absolute energy-dependent scintillating screen calibration for real-time detection of laser-accelerated proton bunches.

Author

Schilz, J. D., Bodenstein, E., Brack, F.-E., Horst, F., Irman, A., Kroll, F., Pawelke, J., Prencipe, I., Rehwald, M., Reimold, M., Schöbel, S., Schramm, U., Zeil, K., and Metzkes-Ng, J.

Abstract

Laser-plasma accelerators (LPAs) can deliver pico- to nanosecond long proton bunches with ≳100 nC of charge dispersed over a broad energy spectrum. Increasing the repetition rates of today's LPAs is a necessity for their practical application. This, however, creates a need for real-time proton bunch diagnostics. Scintillating screens are one detector solution commonly applied in the field of electron LPAs for spatially resolved particle and radiation detection. Yet their establishment for LPA proton detection is only slowly taking off, also due to the lack of available calibrations. In this paper, we present an absolute proton number calibration for the scintillating screen type DRZ High (Mitsubishi Chemical Corporation, Düsseldorf, Germany), one of the most sensitive screens according to calibrations for relativistic electrons and x rays. The presented absolute light yield calibration shows an uncertainty of the proton number of 10% and can seamlessly be applied at other LPA facilities. For proton irradiation of the DRZ High screen, we find an increase in light yield of > 60% compared to reference calibration data for relativistic electrons. Moreover, we investigate the scintillating screen light yield dependence on proton energy since many types of scintillators (e.g., plastic, liquid, and inorganic) show a reduced light yield for increased local energy deposition densities, an effect termed ionization quenching. The ionization quenching can reduce the light yield for low-energy protons by up to ∼20%. This work provides all necessary data for absolute spectral measurements of LPA protons with DRZ High scintillating screens, e.g., when used in the commonly applied Thomson parabola spectrometers. [ABSTRACT FROM AUTHOR]

Published

2024

9. Visualizing Ultrafast Kinetic Instabilities in Laser-Driven Solids using X-ray Scattering

Author

Ordyna, P., (0000-0002-8258-3881) Bussmann, M., (0000-0002-6914-4083) Gaus, L., Grenzer, J., Gutt, C., (0000-0003-1184-2097) Huang, L., (0000-0002-7671-0901) Laso García, A., (0000-0001-6994-2475) Garten, M., Höppner, H., Humpries, O., (0009-0005-6873-8292) Marre, B. E., (0000-0002-9556-0662) Metzkes-Ng, J., Nakatsutsumi, M., Öztürk, Ö., (0000-0002-3882-510X) Pan, X., (0009-0001-0047-1051) Paschke-Brühl, F.-L., Pelka, A., (0000-0003-0931-1350) Prencipe, I., Randolph, L., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0002-7162-7500) Smid, M., (0000-0002-4195-2038) Stefanikova, R., Thiessenhusen, E., (0000-0001-7986-3631) Toncian, T., (0000-0003-3926-409X) Zeil, K., (0000-0003-0390-7671) Schramm, U., (0000-0002-5845-000X) Cowan, T., (0000-0003-4861-5584) Kluge, T., Ordyna, P., (0000-0002-8258-3881) Bussmann, M., (0000-0002-6914-4083) Gaus, L., Grenzer, J., Gutt, C., (0000-0003-1184-2097) Huang, L., (0000-0002-7671-0901) Laso García, A., (0000-0001-6994-2475) Garten, M., Höppner, H., Humpries, O., (0009-0005-6873-8292) Marre, B. E., (0000-0002-9556-0662) Metzkes-Ng, J., Nakatsutsumi, M., Öztürk, Ö., (0000-0002-3882-510X) Pan, X., (0009-0001-0047-1051) Paschke-Brühl, F.-L., Pelka, A., (0000-0003-0931-1350) Prencipe, I., Randolph, L., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0002-7162-7500) Smid, M., (0000-0002-4195-2038) Stefanikova, R., Thiessenhusen, E., (0000-0001-7986-3631) Toncian, T., (0000-0003-3926-409X) Zeil, K., (0000-0003-0390-7671) Schramm, U., (0000-0002-5845-000X) Cowan, T., and (0000-0003-4861-5584) Kluge, T.

Abstract

Ultra-intense lasers that ionize and accelerate electrons in solids to near the speed of light can lead to kinetic instabilities that alter the laser absorption and subsequent electron transport, isochoric heating, and ion acceleration. These instabilities can be difficult to characterize, but a novel approach using X-ray scattering at keV energies allows for their visualization with femtosecond temporal resolution on the few nanometer mesoscale. Our experiments on laser-driven flat silicon membranes show the development of structure with a dominant scale of $~60\unit{nm}$ in the plane of the laser axis and laser polarization, and $~95\unit{nm}$ in the vertical direction with a growth rate faster than $0.1/\mathrm{fs}$. Combining the XFEL experiments with simulations provides a complete picture of the structural evolution of ultra-fast laser-induced instability development, indicating the excitation of surface plasmons and the growth of a new type of filamentation instability. These findings provide new insight into the ultra-fast instability processes in solids under extreme conditions at the nanometer level with important implications for inertial confinement fusion and laboratory astrophysics.

Published

2023

10. A novel multi-shot target platform for laser-driven laboratory astrophysics experiments

Author

(0000-0002-2767-9995) Perez-Martin, P., (0000-0003-0931-1350) Prencipe, I., Sobiella, M., Donat, F., Kang, N., He, Z., Liu, H., Ren, L., Xie, Z., Xiong, J., Zhang, Y., (0000-0002-9859-2408) Brack, F.-E., Cervenak, M., Gajdos, P., Hronova, L., Kaniz, K., Kozlová, M., (0000-0002-0275-9892) Kroll, F., (0000-0002-3882-510X) Pan, X., Schaumann, G., Singh, S., (0000-0002-7162-7500) Smid, M., Suzuki-Vidal, F., Zhang, P., Sun, J., Zhu, J., Krus, M., (0000-0001-5975-776X) Falk, K., (0000-0002-2767-9995) Perez-Martin, P., (0000-0003-0931-1350) Prencipe, I., Sobiella, M., Donat, F., Kang, N., He, Z., Liu, H., Ren, L., Xie, Z., Xiong, J., Zhang, Y., (0000-0002-9859-2408) Brack, F.-E., Cervenak, M., Gajdos, P., Hronova, L., Kaniz, K., Kozlová, M., (0000-0002-0275-9892) Kroll, F., (0000-0002-3882-510X) Pan, X., Schaumann, G., Singh, S., (0000-0002-7162-7500) Smid, M., Suzuki-Vidal, F., Zhang, P., Sun, J., Zhu, J., Krus, M., and (0000-0001-5975-776X) Falk, K.

Abstract

Anewapproach to target development for laboratory astrophysics experiments at high power laser facilities is presented. With the dawnofhighpowerlasers, laboratory astrophysics emerged as a field, bringing insight into physical processes in astrophysical objects, such as formation of stars. An important factor for success on these experiments is targetry. To date, targets have mainly relied on expensive and challenging microfabrication methods. The design presented incorporates replaceable machined parts which assemble into a structure that defines the experimental geometry. This can make targets cheaper and faster to manufacture, while maintaining robustness and reproducibility. The platform is intended for experiments on plasma flows, but it is flexible and may be adapted to the constraints of other experimental setups. Examples of targets used in experimental campaigns are shown, including a design for insertion in a high magnetic field coil. Experimental results are included demonstrating the performance of the targets.

Published

2023

11. Surpassing TNSA performance in laser proton acceleration in the relativistic transparency regime

Author

(0000-0002-3727-7017) Ziegler, T., (0000-0002-6928-2048) Assenbaum, S., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., Dover, N., Garten, M., Gaus, L., Göthel, I., Kiriyama, H., (0000-0003-4861-5584) Kluge, T., Kon, A., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., Nishuichi, M., (0000-0003-0931-1350) Prencipe, I., (0000-0002-4738-6436) Püschel, T., (0000-0001-6200-6406) Rehwald, M., Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., (0000-0002-3727-7017) Ziegler, T., (0000-0002-6928-2048) Assenbaum, S., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., Dover, N., Garten, M., Gaus, L., Göthel, I., Kiriyama, H., (0000-0003-4861-5584) Kluge, T., Kon, A., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., Nishuichi, M., (0000-0003-0931-1350) Prencipe, I., (0000-0002-4738-6436) Püschel, T., (0000-0001-6200-6406) Rehwald, M., Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0003-0390-7671) Schramm, U., and (0000-0003-3926-409X) Zeil, K.

Abstract

Exploiting the strong electromagnetic fields that can be supported by a plasma, high-power laser driven compact plasma accelerators enable generation of short, high-intensity pulses of high energy ions with special beam properties. These accelerators promise to expand the portfolio of conventional machines in many application areas. The maturation of laser driven ion accelerators from physics experiments to turn-key sources for these applications will rely on breakthroughs in both, generated beam parameters (kinetic energy, flux), as well as increased scrutiny on reproducibility, robustness and scalability to high repetition rate. Recent developments at the high-power laser facility DRACO-PW enabled the production of polychromatic proton beams with unprecedented stability [1]. This allowed the first in vivo radiobiological study to be conducted using a laser-driven proton source [2]. Yet, the ability to achieve energies beyond the 100 MeV frontier is essential for many applications and a matter of ongoing research, mainly addressed by exploring advanced acceleration schemes like the relativistically induced transparency regime. In this talk we report on experimental proton acceleration studies at the onset of relativistic transparency using linearly polarized laser pulses with peak intensities of 6x21 W/cm2 focused on thin, pre-expanded plastic foils. Combined hydrodynamic and 3D particle-in-cell simulations helped to identify the most promising target parameter range matched to the carefully measured prevailing laser contrast conditions. In a nutshell, the ultra-intense femtosecond pulse interaction induces large accelerating gradients and energy gain dominantly arising from significant space charge fields due to electron expulsion from the relativistic transparent target core followed by weaker post-acceleration in diffuse sheath fields at later times. A complex suite of particle and optical diagnostics allowed characterization of spatial and spectral proton beam

Published

2023

12. Evidence for Crystalline Structure in Dynamically-Compressed Polyethylene up to 200 GPa

Author

Hartley, N. J., Brown, S., Cowan, T. E., Cunningham, E., Döppner, T., Falcone, R. W., Fletcher, L. B., Frydrych, S., Galtier, E., Gamboa, E. J., Laso Garcia, A., Gericke, D. O., Glenzer, S. H., Granados, E., Heimann, P. A., Lee, H. J., MacDonald, M. J., MacKinnon, A. J., McBride, E. E., Nam, I., Neumayer, P., Pak, A., Pelka, A., Prencipe, I., Ravasio, A., Rödel, M., Rohatsch, K., Saunders, A. M., Schölmerich, M., Schörner, M., Schuster, A. K., Sun, P., van Driel, T., Vorberger, J., and Kraus, D.

Published

2019

13. Recovery of release cloud from laser shock-loaded graphite and hydrocarbon targets: in search of diamonds

Author

Schuster, A K, primary, Voigt, K, additional, Klemmed, B, additional, Hartley, N J, additional, Lütgert, J, additional, Zhang, M, additional, Bähtz, C, additional, Benad, A, additional, Brabetz, C, additional, Cowan, T, additional, Döppner, T, additional, Erb, D J, additional, Eychmüller, A, additional, Facsko, S, additional, Falcone, R W, additional, Fletcher, L B, additional, Frydrych, S, additional, Ganzenmüller, G C, additional, Gericke, D O, additional, Glenzer, S H, additional, Grenzer, J, additional, Helbig, U, additional, Hiermaier, S, additional, Hübner, R, additional, Laso Garcia, A, additional, Lee, H J, additional, MacDonald, M J, additional, McBride, E E, additional, Neumayer, P, additional, Pak, A, additional, Pelka, A, additional, Prencipe, I, additional, Prosvetov, A, additional, Rack, A, additional, Ravasio, A, additional, Redmer, R, additional, Reemts, D, additional, Rödel, M, additional, Schoelmerich, M, additional, Schumacher, D, additional, Tomut, M, additional, Turner, S J, additional, Saunders, A M, additional, Sun, P, additional, Vorberger, J, additional, Zettl, A, additional, and Kraus, D, additional

Published

2022

14. Recovery of release cloud from laser shock-loaded graphite and hydrocarbon targets: in search of diamonds

Author

Schuster, A. K., Voigt, K., Klemmed, B., Hartley, N. J., Lütgert, J., Zhang, M., Bähtz, C., Benad, A., Brabetz, C., Cowan, T., Döppner, T., Erb, D. J., Eychmüller, A., Facsko, S., Falcone, R. W., Fletcher, L. B., Frydrych, S., Ganzenmüller, G. C., Gericke, D. O., Glenzer, S. H., Grenzer, J., Helbig, U., Hiermaier, S., Hübner, R., Laso Garcia, A., Lee, H. J., MacDonald, M. J., McBride, E. E., Neumayer, P., Pak, A., Pelka, A., Prencipe, I., Prosvetov, A., Rack, A., Ravasio, A., Redmer, R., Reemts, D., Rödel, M., Schoelmerich, M., Schumacher, D., Tomut, M., Turner, S. J., Saunders, A. M., Sun, P., Vorberger, J., Zettl, A., Kraus, D., Schuster, A. K., Voigt, K., Klemmed, B., Hartley, N. J., Lütgert, J., Zhang, M., Bähtz, C., Benad, A., Brabetz, C., Cowan, T., Döppner, T., Erb, D. J., Eychmüller, A., Facsko, S., Falcone, R. W., Fletcher, L. B., Frydrych, S., Ganzenmüller, G. C., Gericke, D. O., Glenzer, S. H., Grenzer, J., Helbig, U., Hiermaier, S., Hübner, R., Laso Garcia, A., Lee, H. J., MacDonald, M. J., McBride, E. E., Neumayer, P., Pak, A., Pelka, A., Prencipe, I., Prosvetov, A., Rack, A., Ravasio, A., Redmer, R., Reemts, D., Rödel, M., Schoelmerich, M., Schumacher, D., Tomut, M., Turner, S. J., Saunders, A. M., Sun, P., Vorberger, J., Zettl, A., and Kraus, D.

Abstract

This work presents first insights into the dynamics of free-surface release clouds from dynamically compressed polystyrene and pyrolytic graphite at pressures up to 200 GPa, where they transform into diamond or lonsdaleite, respectively. These ejecta clouds are released into either vacuum or various types of catcher systems, and are monitored with high-speed recordings (frame rates up to 10 MHz). Molecular dynamics simulations are used to give insights to the rate of diamond preservation throughout the free expansion and the catcher impact process, highlighting the challenges of diamond retrieval. Raman spectroscopy data show graphitic signatures on a catcher plate confirming that the shock-compressed PS is transformed. First electron microscopy analyses of solid catcher plates yield an outstanding number of different spherical-like objects in the size range between ten(s) up to hundreds of nanometres, which are one type of two potential diamond candidates identified. The origin of some objects can unambiguously be assigned, while the history of others remains speculative.

Published

2022

15. Investigation of laser reflectivity and transmissivity of laser-plasma interaction with thin foil targets

Author

(0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-3727-7017) Ziegler, T., (0000-0003-1739-0159) Bernert, C., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Göthel, I., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., Vescovi Pinochet, M. A., (0000-0003-3926-409X) Zeil, K., (0000-0003-0390-7671) Schramm, U., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-3727-7017) Ziegler, T., (0000-0003-1739-0159) Bernert, C., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Göthel, I., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., Vescovi Pinochet, M. A., (0000-0003-3926-409X) Zeil, K., and (0000-0003-0390-7671) Schramm, U.

Abstract

Ion acceleration by compact laser-plasma sources promises a variety of applications ranging from medical relevance to fusion experiments.Reaching the required beam quality parameters for those applications demands a very high level of understanding and control over the laserplasma interaction process. Central components in this context are the absorption of the electromagnetic laser field by the plasma and the quality of the resulting acceleration field structure. Measuring and analyzing unabsorbed light - as transmitted and/or specularly reflected parts - thus allows insight into properties of the underlying laser-plasma interaction. We experimentally investigate these interactions for high and low-contrast laser pulses with thin solid density foil targets at the Draco PW laser system (HZDR). The results of spectral, spatial, and energy analysis of transmitted and reflected light indicate changes in the plasma interaction and will be presented.

Published

2022

16. Commissioning and First User Experiments with ReLaX and XFEL Beam

Author

(0000-0002-7671-0901) Laso García, A., Arefiev, A., Kemp, A., Allen, C. H., Bähtz, C., Nagler, B., Palmer, C. A. J., Murphy, C. D., Spindloe, C., Brown, C. R. D., Neely, D., (0000-0002-6350-4180) Kraus, D., Marley, E., Hartouni, E. P., Fiuza, F., Grim, G. P., Cochran, G. E., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0931-1350) Prencipe, I., Williams, J., Green, J., Eggert, J. H., (0000-0003-3926-409X) Zeil, K., Lancaster, K. L., Divol, L., (0000-0002-6914-4083) Gaus, L., (0000-0003-1184-2097) Huang, L., Schoelmerich, M., (0000-0001-6200-6406) Rehwald, M., Oliver, M., Rödel, M., Macdonald, M., (0000-0002-7162-7500) Smid, M., Makita, M., Nakatsutsumi, M., (0000-0001-6748-0422) Humphries, O. S., Neumayer, P. B., Mabey, P., Shepherd, R. L., Gray, R., Wilks, S. C., Le Pape, S., Kerr, S. M., Glenzer, S. H., Funk, S., Gales, S. G., (0000-0002-5845-000X) Cowan, T., White, T. G., (0000-0003-4861-5584) Kluge, T., Doeppner, T., (0000-0001-7986-3631) Toncian, T., Zastrau, U., (0000-0003-0390-7671) Schramm, U., Ping, Y., He, Z., Höppner, H., Pelka, A., (0000-0002-7671-0901) Laso García, A., Arefiev, A., Kemp, A., Allen, C. H., Bähtz, C., Nagler, B., Palmer, C. A. J., Murphy, C. D., Spindloe, C., Brown, C. R. D., Neely, D., (0000-0002-6350-4180) Kraus, D., Marley, E., Hartouni, E. P., Fiuza, F., Grim, G. P., Cochran, G. E., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0931-1350) Prencipe, I., Williams, J., Green, J., Eggert, J. H., (0000-0003-3926-409X) Zeil, K., Lancaster, K. L., Divol, L., (0000-0002-6914-4083) Gaus, L., (0000-0003-1184-2097) Huang, L., Schoelmerich, M., (0000-0001-6200-6406) Rehwald, M., Oliver, M., Rödel, M., Macdonald, M., (0000-0002-7162-7500) Smid, M., Makita, M., Nakatsutsumi, M., (0000-0001-6748-0422) Humphries, O. S., Neumayer, P. B., Mabey, P., Shepherd, R. L., Gray, R., Wilks, S. C., Le Pape, S., Kerr, S. M., Glenzer, S. H., Funk, S., Gales, S. G., (0000-0002-5845-000X) Cowan, T., White, T. G., (0000-0003-4861-5584) Kluge, T., Doeppner, T., (0000-0001-7986-3631) Toncian, T., Zastrau, U., (0000-0003-0390-7671) Schramm, U., Ping, Y., He, Z., Höppner, H., and Pelka, A.

Abstract

In this presentation we provide an overview of the commissioning and first user experiment of ReLaX in combination with the XFEL beam. We will introduce the setup and laser parameters. We will show the established standard setup combining small-angle x-ray scattering (SAXS), phase-contrast imaging (PCI) and spectroscopy techniques. Finally we will show examples of the data obtained in the interaction of the ReLaX laser with targets of interested for the short-pulse laser community.

Published

2022

17. Characterization of low-density rear-driven collisional plasma jets from thin foil targets

Author

(0000-0002-2767-9995) Perez-Martin, P., (0000-0002-7162-7500) Smid, M., Hronová, L., (0000-0001-6079-1260) Bouffetier, V., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-6460-4685) Cagas, P., Červenák, M., Gajdos, P., He, Z., (0000-0001-7016-0729) Holec, M., (0000-0001-7504-8947) Kagan, G., Kaniz, K., Kozlová, M., (0000-0002-0275-9892) Kroll, F., Liu, H., Pan, X., (0000-0003-0931-1350) Prencipe, I., (0000-0002-7631-6883) Schaumann, G., Singh, S., Sobiella, M., (0000-0002-0712-1097) Srinivasan, B., Stafford, J., Xie, Z., Xiong, J., (0000-0002-7792-4960) Suzuki-Vidal, F., Krůs, M., Ren, L., Kang, N., (0000-0001-5975-776X) Falk, K., (0000-0002-2767-9995) Perez-Martin, P., (0000-0002-7162-7500) Smid, M., Hronová, L., (0000-0001-6079-1260) Bouffetier, V., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-6460-4685) Cagas, P., Červenák, M., Gajdos, P., He, Z., (0000-0001-7016-0729) Holec, M., (0000-0001-7504-8947) Kagan, G., Kaniz, K., Kozlová, M., (0000-0002-0275-9892) Kroll, F., Liu, H., Pan, X., (0000-0003-0931-1350) Prencipe, I., (0000-0002-7631-6883) Schaumann, G., Singh, S., Sobiella, M., (0000-0002-0712-1097) Srinivasan, B., Stafford, J., Xie, Z., Xiong, J., (0000-0002-7792-4960) Suzuki-Vidal, F., Krůs, M., Ren, L., Kang, N., and (0000-0001-5975-776X) Falk, K.

Abstract

Magnetized low density, collisional plasma jets are found in astrophysical systems, such as accretion discs or polars, and they also show potential as a platform to study transport properties in astrophysical plasmas. However, no systematic study of their properties has been conducted yet. Through experiments in kilojoule laser facilities, we aim to benchmark a range of rear-driven jets from foils of different thicknesses and materials. We studied free propagation of jets, their collisions with a static object and the collisions between two counterpropagating jets. The setup was also placed inside a split pair coil, which provides an external magnetic field of 5-10 T. A streak camera was used to track jet velocity and density was measured with 4-frame interferometry and x-ray radiography. The results can be used to plan experiments with focus on specific jet properties, as well as providing a benchmark for hydrodynamic codes. The data on collisions and magnetized jets provides insight into compression waves and the effects of strong external magnetic fields, which are used for the study of transport properties of plasmas.

Published

2022

18. Modeling of magnetized astrophysical objects through the study of magnetized rear-driven plasma jets from thin foil targets

Author

(0000-0002-2767-9995) Perez-Martin, P., (0000-0002-7162-7500) Smid, M., Hronová, L., (0000-0001-6079-1260) Bouffetier, V., (0000-0001-8071-3083) Bott, A., (0000-0002-9859-2408) Brack, F.-E., Červenák, M., Donat, F., Gajdoš, P., (0000-0003-4757-9972) Kozlová, M., (0000-0002-0275-9892) Kroll, F., (0000-0002-5834-1161) Manuel, M., (0000-0002-3882-510X) Pan, X., (0000-0003-0931-1350) Prencipe, I., Singh, S., Sobiella, M., (0000-0002-8595-3139) Krus, M., (0000-0001-5975-776X) Falk, K., (0000-0002-2767-9995) Perez-Martin, P., (0000-0002-7162-7500) Smid, M., Hronová, L., (0000-0001-6079-1260) Bouffetier, V., (0000-0001-8071-3083) Bott, A., (0000-0002-9859-2408) Brack, F.-E., Červenák, M., Donat, F., Gajdoš, P., (0000-0003-4757-9972) Kozlová, M., (0000-0002-0275-9892) Kroll, F., (0000-0002-5834-1161) Manuel, M., (0000-0002-3882-510X) Pan, X., (0000-0003-0931-1350) Prencipe, I., Singh, S., Sobiella, M., (0000-0002-8595-3139) Krus, M., and (0000-0001-5975-776X) Falk, K.

Abstract

Plasma jets can be found in astrophysical systems (Accretion disks[1][2], Polars [3] or Young Stellar Objects [4]), but they are also useful as a platform to study plasma properties and transport effects. On a experiment at the PALS facility, we have studied the formation and propagation of rear-driven, collisional plasma jets from different foil thicknesses and materials when subject to an intense external magnetic field. Magnetic fields were generated using a pair of Helmholtz coils that provide 5-10 T in the direction perpendicular to the jet propagation. The diagnostics used were the streaked optical self-emission as a measurement of jet velocity, and 4-frame interferometry as a measurement of the jet density. With the right scaling factors, this data can help model the accretion of matter into magnetized astrophysical systems, such as the surface of Young Stellar Objects, as well as the role that instabilities play in this process [4]. The work was supported by the Helmholtz Association under Grant No. VH-NG-1338 [1] G. Revet et al., Science Advances 3, 11 (2017) [2] Kulkarni, A. K. & Romanova, M. M. , Monthly Notices RAS 386, (2008) [3] E. Falize, et al., Astrophysics and Space Science 336, 81 (2011) [4] Burdonov, K. et al., A&A 657, A112 (2022)

Published

2022

19. Experimental study of Relativistic High Harmonic Generation with a PW level short pulse laser system

Author

(0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-6928-2048) Assenbaum, S., Meric, T., (0000-0002-0275-9892) Kroll, F., (0000-0001-6200-6406) Rehwald, M., (0000-0002-4195-2038) Stefanikova, R., (0000-0002-4738-6436) Püschel, T., (0000-0003-0931-1350) Prencipe, I., (0000-0002-0638-6990) Kraft, S., (0000-0003-3926-409X) Zeil, K., (0000-0003-0390-7671) Schramm, U., (0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-6928-2048) Assenbaum, S., Meric, T., (0000-0002-0275-9892) Kroll, F., (0000-0001-6200-6406) Rehwald, M., (0000-0002-4195-2038) Stefanikova, R., (0000-0002-4738-6436) Püschel, T., (0000-0003-0931-1350) Prencipe, I., (0000-0002-0638-6990) Kraft, S., (0000-0003-3926-409X) Zeil, K., and (0000-0003-0390-7671) Schramm, U.

Abstract

Surface High harmonic generation (SHHG) arising from the interaction of high and ultra- high intensity lasers with solid density targets has been extensively studied during recent years. Besides being a promising source for applications on ultrafast science, the sensitivity of SHHG mechanisms with respect to changes of pump laser parameters or target pre-plasma conditions makes the harmonic spectrum a useful diagnostic to gain insight into the interaction between the laser and the target front surface where, in case of a solid density target, most of the energy absorption between laser and target takes place. In the present work, the first measurements of high harmonic spectra on the Draco PW laser system at HZDR are presented. Most measurements were done using a single plasma mirror system, achieving a contrast of 10-7 at -1ps for a 5.4x1021W/cm2, 30fs 800nm pulse. XUV spectra were measured for a wide range of different target materials (plastic, metal, glass), thicknesses; from bulk SiO2 substrates to few tens of nm foils where relativistic transparency starts to occur; as well as different laser energies (a0~7-50). The spectral range of the spectrometer (53nm to ~17nm, 15th to 47th harmonic, limited by the filtering) allowed us to measure changes in SHHG along the spectrum for different interaction conditions. These measurements were carried in parallel with proton acceleration experiments, aiming at using the harmonic generation as a gauge for the laser-plasma interaction at different interaction regimes, and to our knowledge constitute one of the first measurements of relativistic surface harmonics with a PW short pulse laser.

Published

2022

20. Calorimeter with Bayesian unfolding of spectra of high-flux broadband X-rays

Author

(0000-0002-7671-0901) Laso García, A., Hannasch, A., Molodtsova, M., (0000-0002-6486-353X) Ferrari, A., (0000-0001-9129-4208) Couperus Cabadağ, J. P., Downer, M. C., (0000-0002-4626-0049) Irman, A., (0000-0002-0638-6990) Kraft, S., (0000-0002-9556-0662) Metzkes-Ng, J., Naumann, L., (0000-0003-0931-1350) Prencipe, I., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., Zgadzaj, R., (0000-0002-3727-7017) Ziegler, T., (0000-0002-5845-000X) Cowan, T., (0000-0002-7671-0901) Laso García, A., Hannasch, A., Molodtsova, M., (0000-0002-6486-353X) Ferrari, A., (0000-0001-9129-4208) Couperus Cabadağ, J. P., Downer, M. C., (0000-0002-4626-0049) Irman, A., (0000-0002-0638-6990) Kraft, S., (0000-0002-9556-0662) Metzkes-Ng, J., Naumann, L., (0000-0003-0931-1350) Prencipe, I., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., Zgadzaj, R., (0000-0002-3727-7017) Ziegler, T., and (0000-0002-5845-000X) Cowan, T.

Abstract

We report the development of a multipurpose differential X-ray calorimeter with a broad energy bandwidth. The absorber architecture is combined with a Bayesian unfolding algorithm to unfold high-energy X-ray spectra generated in high-intensity laser-matter interactions. Particularly, we show how to extract absolute energy spectra and how our unfolding algorithm can reconstruct features not included in the initial guess. The performance of the calorimeter is evaluated via Monte Carlo generated data. The method accuracy to reconstruct electron temperatures from bremsstrahlung is shown to be 5 % for electron temperatures from 1 MeV to 50 MeV. We study bremsstrahlung generated in solid target interaction showing an electron temperature of 0.56±0.04MeV for a 700 µm Ti titanium target and 0.53±0.03MeV for a 50 µm target. We investigate bremsstrahlung from a target irradiated by laser wakefield accelerated electrons showing an endpoint energy of 551 ± 5 MeV, inverse Compton generated X-rays with a peak energy of 1.1 MeV and calibrated radioactive sources. The total energy range covered by all these sources ranges from 10 keV to 551 MeV.

Published

2022

21. Combined Phase Contrast Imaging and Small-Angle X-Ray Scattering Diagnostic of Relativistic Plasmas at the High Energy Density Instrument at European XFEL

Author

(0000-0002-7671-0901) Laso García, A., Arefiev, A., Kemp, A., Allen, C. H., Bähtz, C., Nagler, B., Palmer, C. A. J., Murphy, C. D., Spindloe, C., Brown, C. R. D., Neely, D., (0000-0002-6350-4180) Kraus, D., Marley, E., Hartouni, E. P., Fiuza, F., Grim, G. P., Cochran, G. E., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0931-1350) Prencipe, I., Williams, J., Green, J., Eggert, J. H., (0000-0003-3926-409X) Zeil, K., Lancaster, K. L., Divol, L., (0000-0002-6914-4083) Gaus, L., (0000-0003-1184-2097) Huang, L., Schoelmerich, M., (0000-0001-6200-6406) Rehwald, M., Oliver, M., Rödel, M., Macdonald, M., (0000-0002-7162-7500) Smid, M., Makita, M., Nakatsutsumi, M., (0000-0001-6748-0422) Humphries, O. S., Neumayer, P. B., Mabey, P., Shepherd, R. L., Gray, R., Wilks, S. C., Le Pape, S., Kerr, S. M., Glenzer, S. H., Funk, S., Gales, S. G., (0000-0002-5845-000X) Cowan, T., White, T. G., (0000-0003-4861-5584) Kluge, T., Doeppner, T., (0000-0001-7986-3631) Toncian, T., Zastrau, U., (0000-0003-0390-7671) Schramm, U., Ping, Y., He, Z., Höppner, H., Pelka, A., (0000-0002-7671-0901) Laso García, A., Arefiev, A., Kemp, A., Allen, C. H., Bähtz, C., Nagler, B., Palmer, C. A. J., Murphy, C. D., Spindloe, C., Brown, C. R. D., Neely, D., (0000-0002-6350-4180) Kraus, D., Marley, E., Hartouni, E. P., Fiuza, F., Grim, G. P., Cochran, G. E., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0931-1350) Prencipe, I., Williams, J., Green, J., Eggert, J. H., (0000-0003-3926-409X) Zeil, K., Lancaster, K. L., Divol, L., (0000-0002-6914-4083) Gaus, L., (0000-0003-1184-2097) Huang, L., Schoelmerich, M., (0000-0001-6200-6406) Rehwald, M., Oliver, M., Rödel, M., Macdonald, M., (0000-0002-7162-7500) Smid, M., Makita, M., Nakatsutsumi, M., (0000-0001-6748-0422) Humphries, O. S., Neumayer, P. B., Mabey, P., Shepherd, R. L., Gray, R., Wilks, S. C., Le Pape, S., Kerr, S. M., Glenzer, S. H., Funk, S., Gales, S. G., (0000-0002-5845-000X) Cowan, T., White, T. G., (0000-0003-4861-5584) Kluge, T., Doeppner, T., (0000-0001-7986-3631) Toncian, T., Zastrau, U., (0000-0003-0390-7671) Schramm, U., Ping, Y., He, Z., Höppner, H., and Pelka, A.

Abstract

The High Energy Density (HED) instrument at the European XFEL provides a platform to study hot and warm dense matter. The Helmholtz International Beamline for Extreme Fields (HiBEF) is a User Consortium supplying HED with two laser systems (the high-intensity ReLaX laser, by Amplitude Technologies, and the high-energy Dipole-100X laser, by STFC), Diamond Anvil Cells setup and high-pulsed magnetic fields. These tools in combination with the XFEL beam enable the investigation of relativistic laser plasmas, strong-field QED phenomena, high-pressure astro- and planetary physics as well as magnetic phenomena in condensed matter. The successful commissioning of the ultra-short pulse high-intensity ReLaX laser, provides new unique opportunities in the plasma and high-field physics fields [1]. ReLaX is a double CPA Ti:Sa laser capable of delivering up to 300 TW pulses on target. In the first commissioning phase, 100 TW pulses were used, reaching intensities up to 1020 W/cm2. Small-Angle X-Ray Scattering (SAXS) without the need of a beamstop was first commissioned at HED in September 2019. Two highly annealed pyrolytic graphite (HAPG) crystals were used to reflect the SAXS photons onto a detector while allowing the main XFEL beam to go through [2]. In April and May 2021, Small Angle X-Ray Scattering and Phase Contrast Imaging (PCI) were simultaneously demonstrated in pump-probe experiments at HED in a community experiment involving 15 institutions from all over the world. In this talk we will present the preliminary results of this community experiment probing ultrafast phenomena in a wide array of target configurations: hole boring in wires, shockwave generation in CH blocks, buried heating of a wire inside a CH medium, foam ionization and collective effects in heated foils. [1] A. Laso Garcia, H. Hoeppner, A. Pelka et al., “ReLaX: the HiBEF high-intensity short-pulse laser driver for relativistic laser-matter interaction and strong-field science at the HED instrument at Eu

Published

2022

22. Towards High-Field Experiments in Existing and Upcoming Laser Facilities

Author

(0000-0002-7671-0901) Laso García, A., (0000-0001-7986-3631) Toncian, T., Habibi, M., (0000-0003-0931-1350) Prencipe, I., Rinderknecht, H. G., Wei, M. S., Bruhaug, G., Arefiev, A., Wang, T., Doria, D., Crăciun, V., Ghenuche, P., Năstasă, V., Cernăianu, M., Dreghici, D.-B., Talposi, A.-M., Quevedo, H., Ditmire, T., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0002-7162-7500) Smid, M., (0000-0002-5845-000X) Cowan, T., (0000-0002-7671-0901) Laso García, A., (0000-0001-7986-3631) Toncian, T., Habibi, M., (0000-0003-0931-1350) Prencipe, I., Rinderknecht, H. G., Wei, M. S., Bruhaug, G., Arefiev, A., Wang, T., Doria, D., Crăciun, V., Ghenuche, P., Năstasă, V., Cernăianu, M., Dreghici, D.-B., Talposi, A.-M., Quevedo, H., Ditmire, T., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0002-7162-7500) Smid, M., and (0000-0002-5845-000X) Cowan, T.

Abstract

The Helmholtz International Beamline for Extreme Fields is a user consortium providing drivers for high-energy density and high-field science at the HED station of EuXFEL. This presentation will give an overview of the current implementation and commissioning results as well as future plans and exemplary science cases. In parallel, new exciting opportunities for high-field science are opening with the first user call at the ELI facilities. Here, we will discuss first results on Megatesla magnetic field generation in overdense plasmas. We will also discuss future plans to exploit the high intensities, up to 10 PW, to be delivered at ELI-NP.

Published

2022

23. Foam Targets as Extreme Magnetic Field Drivers

Author

(0000-0002-7671-0901) Laso García, A., (0000-0001-7986-3631) Toncian, T., Habibi, M., (0000-0003-0931-1350) Prencipe, I., (0000-0002-5845-000X) Cowan, T., Rinderknecht, H. G., Wei, M. S., Bruhaug, G., Arefiev, A., Wang, T., Doria, D., Crăciun, V., Ghenuche, P., Năstasă, V., (0000-0002-7671-0901) Laso García, A., (0000-0001-7986-3631) Toncian, T., Habibi, M., (0000-0003-0931-1350) Prencipe, I., (0000-0002-5845-000X) Cowan, T., Rinderknecht, H. G., Wei, M. S., Bruhaug, G., Arefiev, A., Wang, T., Doria, D., Crăciun, V., Ghenuche, P., and Năstasă, V.

Abstract

Structured foam targets are of great interest for the laser-plasma community. Recent studies have shown how low density foams could be used to generate extreme magnetic fields in the MegaTesla range. A result of the interaction of the fields with the accelerated electrons in the foam is a large increase in the electron kinetic energy, and the generation of bright flashes of synchrotron radiation in the MeV range. In this talk we introduce experimental results obtained at HED/HiBEF at the European XFEL on the structural changes and homogenization of the foam during the laser interaction. Then we will show results on synchrotron emission at Texas Petawatt. Finally we will provide an overview of our roadmap towards implementing foam experiments at the 10 PW level at ELI-NP

Published

2022

24. Data publication: Calorimeter with Bayesian unfolding of spectra of high-flux broadband X-rays

Author

(0000-0002-7671-0901) Laso García, A., Hannasch, A., Molodtsova, M., (0000-0002-6486-353X) Ferrari, A., (0000-0001-9129-4208) Couperus Cabadağ, J. P., Downer, M. C., (0000-0002-4626-0049) Irman, A., (0000-0002-0638-6990) Kraft, S., (0000-0002-9556-0662) Metzkes-Ng, J., Naumann, L., (0000-0003-0931-1350) Prencipe, I., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., Zgadzaj, R., (0000-0002-3727-7017) Ziegler, T., (0000-0002-5845-000X) Cowan, T., (0000-0002-7671-0901) Laso García, A., Hannasch, A., Molodtsova, M., (0000-0002-6486-353X) Ferrari, A., (0000-0001-9129-4208) Couperus Cabadağ, J. P., Downer, M. C., (0000-0002-4626-0049) Irman, A., (0000-0002-0638-6990) Kraft, S., (0000-0002-9556-0662) Metzkes-Ng, J., Naumann, L., (0000-0003-0931-1350) Prencipe, I., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., Zgadzaj, R., (0000-0002-3727-7017) Ziegler, T., and (0000-0002-5845-000X) Cowan, T.

Abstract

Data for the publication: Calorimeter with Bayesian unfolding of spectra of high-flux broadband X-rays Containing: - Raw datasets - Source code for extracting calibrated energy information from datasets - Source code for simulations - Source code for unfolding of spectra

Published

2022

25. Calorimeter with Bayesian unfolding of spectra of high-flux broadband x rays

Author

Laso Garcia, A., primary, Hannasch, A., additional, Molodtsova, M., additional, Ferrari, A., additional, Couperus Cadabağ, J. P., additional, Downer, M. C., additional, Irman, A., additional, Kraft, S. D., additional, Metzkes-Ng, J., additional, Naumann, L., additional, Prencipe, I., additional, Schramm, U., additional, Zeil, K., additional, Zgadzaj, R., additional, Ziegler, T., additional, and Cowan, T. E., additional

Published

2022

26. Experimental study of Relativistic High Harmonic Generation with a PW level short pulse laser system

Author

Vescovi Pinochet, M. A., Umlandt, M. E. P., Assenbaum, S., Meric, T., Kroll, F., Rehwald, M., Stefanikova, R., Püschel, T., Prencipe, I., Kraft, S., Zeil, K., and Schramm, U.

Subjects

High Power Laser, Laser Proton acceleration, High Harmonic Generation

Abstract

Surface High harmonic generation (SHHG) arising from the interaction of high and ultra- high intensity lasers with solid density targets has been extensively studied during recent years. Besides being a promising source for applications on ultrafast science, the sensitivity of SHHG mechanisms with respect to changes of pump laser parameters or target pre-plasma conditions makes the harmonic spectrum a useful diagnostic to gain insight into the interaction between the laser and the target front surface where, in case of a solid density target, most of the energy absorption between laser and target takes place. In the present work, the first measurements of high harmonic spectra on the Draco PW laser system at HZDR are presented. Most measurements were done using a single plasma mirror system, achieving a contrast of 10-7 at -1ps for a 5.4x1021W/cm2, 30fs 800nm pulse. XUV spectra were measured for a wide range of different target materials (plastic, metal, glass), thicknesses; from bulk SiO2 substrates to few tens of nm foils where relativistic transparency starts to occur; as well as different laser energies (a0~7-50). The spectral range of the spectrometer (53nm to ~17nm, 15th to 47th harmonic, limited by the filtering) allowed us to measure changes in SHHG along the spectrum for different interaction conditions. These measurements were carried in parallel with proton acceleration experiments, aiming at using the harmonic generation as a gauge for the laser-plasma interaction at different interaction regimes, and to our knowledge constitute one of the first measurements of relativistic surface harmonics with a PW short pulse laser.

Published

2022

27. Study of x-ray emission from proton acceleration targets at Draco PW laser facility

Author

Stefanikova, R., Pan, X., Meckel, N., Smid, M., Schlenvoigt, H.-P., Prencipe, I., Kozlová, M., Gaus, L., Umlandt, M. E. P., Vescovi Pinochet, M. A., Reimold, M., Ziegler, T., Kroll, F., Kraft, S., Schramm, U., Zeil, K., Metzkes-Ng, J., and Falk, K.

Subjects

x-ray spectroscopy, laser-produced plasma, laser-plasma ion acceleration, characteristic emission lines

Abstract

Laser plasma-based ion accelerators are very promising candidates for many applications. In order to ensure the reliability of such accelerators a comprehensive set of diagnostics is required. X-ray emission spectroscopy allows us to directly measure the plasma conditions of the laser-plasma interaction and also provides information about the hot electron population through the cold K-α emission production. Here, we present preliminary results from two new x-ray spectrometers used to study interaction regimes relevant for laser-driven ion acceleration at ultra-short pulse PW-class laser facility. We acquired the emission spectra from flat Ti targets for a range of target thicknesses and laser energies. Additionally, artificial laser pre-pulses were added to alter the laser absorption efficiency.

Published

2022

28. Characterization of low-density rear-driven collisional plasma jets from thin foil targets

Author

Perez-Martin, P., Smid, M., Hronová, L., Bouffetier, V., Brack, F.-E., Cagas, P., Červenák, M., Gajdos, P., He, Z., Holec, M., Kagan, G., Kaniz, K., Kozlová, M., Kroll, F., Liu, H., Pan, X., Prencipe, I., Schaumann, G., Singh, S., Sobiella, M., Srinivasan, B., Stafford, J., Xie, Z., Xiong, J., Suzuki-Vidal, F., Krůs, M., Ren, L., Kang, N., and Falk, K.

Subjects

Laboratory astrophysics, Interferometry, Magnetized plasma, High magnetic fields, Plasma flows

Abstract

Magnetized low density, collisional plasma jets are found in astrophysical systems, such as accretion discs or polars, and they also show potential as a platform to study transport properties in astrophysical plasmas. However, no systematic study of their properties has been conducted yet. Through experiments in kilojoule laser facilities, we aim to benchmark a range of rear-driven jets from foils of different thicknesses and materials. We studied free propagation of jets, their collisions with a static object and the collisions between two counterpropagating jets. The setup was also placed inside a split pair coil, which provides an external magnetic field of 5-10 T. A streak camera was used to track jet velocity and density was measured with 4-frame interferometry and x-ray radiography. The results can be used to plan experiments with focus on specific jet properties, as well as providing a benchmark for hydrodynamic codes. The data on collisions and magnetized jets provides insight into compression waves and the effects of strong external magnetic fields, which are used for the study of transport properties of plasmas.

Published

2022

29. Data publication: Calorimeter with Bayesian unfolding of spectra of high-flux broadband X-rays

Author

Laso García, A., Hannasch, A., Molodtsova, M., Ferrari, A., Couperus Cabadağ, J. P., Downer, M. C., Irman, A., Kraft, S., Metzkes-Ng, J., Naumann, L., Prencipe, I., Schramm, U., Zeil, K., Zgadzaj, R., Ziegler, T., and Cowan, T.

Subjects

ComputingMethodologies_PATTERNRECOGNITION, Bremsstrahlung, Astrophysics::High Energy Astrophysical Phenomena, X-rays, MathematicsofComputing_NUMERICALANALYSIS, Technique and instrumentation, Relativistic laser plasmas

Abstract

Data for the publication: Calorimeter with Bayesian unfolding of spectra of high-flux broadband X-rays Containing: - Raw datasets - Source code for extracting calibrated energy information from datasets - Source code for simulations - Source code for unfolding of spectra

Published

2022

30. Investigation of laser reflectivity and transmissivity of laser-plasma interaction with thin foil targets

Author

Umlandt, M. E. P., Ziegler, T., Bernert, C., Garten, M., Gaus, L., Göthel, I., Kluge, T., Kraft, S., Kroll, F., Metzkes-Ng, J., Prencipe, I., Rehwald, M., Reimold, M., Schlenvoigt, H.-P., Vescovi Pinochet, M. A., Zeil, K., and Schramm, U.

Subjects

laser proton acceleration, laser plasma, high power laser

Abstract

Ion acceleration by compact laser-plasma sources promises a variety of applications ranging from medical relevance to fusion experiments.Reaching the required beam quality parameters for those applications demands a very high level of understanding and control over the laserplasma interaction process. Central components in this context are the absorption of the electromagnetic laser field by the plasma and the quality of the resulting acceleration field structure. Measuring and analyzing unabsorbed light - as transmitted and/or specularly reflected parts - thus allows insight into properties of the underlying laser-plasma interaction. We experimentally investigate these interactions for high and low-contrast laser pulses with thin solid density foil targets at the Draco PW laser system (HZDR). The results of spectral, spatial, and energy analysis of transmitted and reflected light indicate changes in the plasma interaction and will be presented.

Published

2022

31. Commissioning and First User Experiments with ReLaX and XFEL Beam

Author

Laso García, A., Arefiev, A., Kemp, A., Allen, C. H., Bähtz, C., Nagler, B., Palmer, C. A. J., Murphy, C. D., Spindloe, C., Brown, C. R. D., Neely, D., Kraus, D., Marley, E., Hartouni, E. P., Fiuza, F., Grim, G. P., Cochran, G. E., Schlenvoigt, H.-P., Prencipe, I., Williams, J., Green, J., Eggert, J. H., Zeil, K., Lancaster, K. L., Divol, L., Gaus, L., Huang, L., Schoelmerich, M., Rehwald, M., Oliver, M., Rödel, M., Macdonald, M., Smid, M., Makita, M., Nakatsutsumi, M., Humphries, O. S., Neumayer, P. B., Mabey, P., Shepherd, R. L., Gray, R., Wilks, S. C., Le Pape, S., Kerr, S. M., Glenzer, S. H., Funk, S., Gales, S. G., Cowan, T., White, T. G., Kluge, T., Doeppner, T., Toncian, T., Zastrau, U., Schramm, U., Ping, Y., He, Z., Höppner, H., and Pelka, A.

Subjects

XFEL, PCI, SAXS, Laser-plasma, HiBEF

Abstract

In this presentation we provide an overview of the commissioning and first user experiment of ReLaX in combination with the XFEL beam. We will introduce the setup and laser parameters. We will show the established standard setup combining small-angle x-ray scattering (SAXS), phase-contrast imaging (PCI) and spectroscopy techniques. Finally we will show examples of the data obtained in the interaction of the ReLaX laser with targets of interested for the short-pulse laser community.

Published

2022

32. Modeling of magnetized astrophysical objects through the study of magnetized rear-driven plasma jets from thin foil targets

Author

Perez-Martin, P., Smid, M., Hronová, L., Bouffetier, V., Bott, A., Brack, F.-E., Červenák, M., Donat, F., Gajdoš, P., Kozlová, M., Kroll, F., Manuel, M., Pan, X., Prencipe, I., Singh, S., Sobiella, M., Krus, M., and Falk, K.

Subjects

Laboratory astrophysics, Magnetized plasma, High magnetic fields, Young Stellar Objects, Plasma flows, Magnetosphere physics

Abstract

Plasma jets can be found in astrophysical systems (Accretion disks[1][2], Polars [3] or Young Stellar Objects [4]), but they are also useful as a platform to study plasma properties and transport effects. On a experiment at the PALS facility, we have studied the formation and propagation of rear-driven, collisional plasma jets from different foil thicknesses and materials when subject to an intense external magnetic field. Magnetic fields were generated using a pair of Helmholtz coils that provide 5-10 T in the direction perpendicular to the jet propagation. The diagnostics used were the streaked optical self-emission as a measurement of jet velocity, and 4-frame interferometry as a measurement of the jet density. With the right scaling factors, this data can help model the accretion of matter into magnetized astrophysical systems, such as the surface of Young Stellar Objects, as well as the role that instabilities play in this process [4]. The work was supported by the Helmholtz Association under Grant No. VH-NG-1338 [1] G. Revet et al., Science Advances 3, 11 (2017) [2] Kulkarni, A. K. & Romanova, M. M. , Monthly Notices RAS 386, (2008) [3] E. Falize, et al., Astrophysics and Space Science 336, 81 (2011) [4] Burdonov, K. et al., A&A 657, A112 (2022)

Published

2022

33. Publisher's Note: "Absolute energy-dependent scintillating screen calibration for real-time detection of laser-accelerated proton bunches" [Rev. Sci. Instrum. 95, 073303 (2024)].

Author

Schilz, J. D., Bodenstein, E., Brack, F.-E., Horst, F., Irman, A., Kroll, F., Pawelke, J., Prencipe, I., Rehwald, M., Reimold, M., Schöbel, S., Schramm, U., Zeil, K., and Metzkes-Ng, J.

Subjects

INTERNET publishing, APOLOGIZING, PROTONS, CALIBRATION, PUBLISHING

Abstract

This article was originally published online on 26 July 2024 with missing affiliations for several authors. All author affiliations appear correctly above. AIP Publishing apologizes for the errors. All online versions of the article were corrected on 31 July 2024; the article is correct as it appears in the printed version of the journal.By J. D. Schilz; E. Bodenstein; F.-E. Brack; F. Horst; A. Irman; F. Kroll; J. Pawelke; I. Prencipe; M. Rehwald; M. Reimold; S. Schöbel; U. Schramm; K. Zeil and J. Metzkes-NgReported by Author; Author; Author; Author; Author; Author; Author; Author; Author; Author; Author; Author; Author; Author [Extracted from the article]

Published

2024

34. Targets for pump probe experiments at upcoming XFEL facilities

Author

Kluge, T., Gaus, L., Prencipe, I., Schlenvoigt, H.-P., Schramm, U., and Cowan, T.

Abstract

Targets for pump probe experiments at upcoming XFEL facilities

Published

2021

35. Probing ultrafast laser plasma processes inside solids with resonant small angle X-ray scattering

Author

Gaus, L., Bischoff, L., Bussmann, M., Cunningham, E., Curry, C. B., E, Juncheng, Galtier, E., Gauthier, M., Laso García, A., Garten, M., Glenzer, S., Grenzer, J., Gutt, C., Hartley, N., Huang, L., Hübner, U., Kraus, D., Lee, H. J., McBride, E. E., Metzkes-Ng, J., Nagler, B., Nakatsutsumi, M., Nikl, J., Ota, M., Pelka, A., Prencipe, I., Randolph, L., Rödel, M., Sakawa, Y., Schlenvoigt, H.-P., Smid, M., Treffert, F., Voigt, K., Zeil, K., Cowan, T., Schramm, U., and Kluge, T.

Abstract

Extreme states of matter exist throughout the universe e.g. inside planetary cores, stars or astrophysical jets. Such conditions can be generated in the laboratory in the interaction of powerful lasers with solids. Yet, the measurement of the subsequent plasma dynamics with regard to density, temperature and ionization is a major experimental challenge. However, ultra-short X-ray pulses provided by X-ray free electron lasers (XFELs) allow for dedicated studies, which are highly relevant to study laboratory astrophysics, laser-fusion research or laser-plasma-based particle acceleration. Here, we report on experiments that employ a novel ultrafast method, which allows to simultaneously access temperature, ionization state and nanometer scale expansion dynamics in high-intensity laser-driven solid-density plasmas with a single X-ray detector. Using this method, we gain access to the expansion dynamics of a buried layer in compound samples, and we measure opacity changes arising from bound-bound resonance transitions in highly ionized copper. The presence of highly ionized copper leads to a temperature estimate of at least 2 million Kelvin already after the first 100 femtoseconds following the high-intensity laser irradiation. More specifically, we make use of asymmetries in small-angle X-ray scattering (SAXS) patterns, which arise from different spatial distributions of absorption and scattering cross sections in nanostructured grating samples when we tune an XFEL to atomic resonant energies of copper. Thereby, changes in asymmetry can be connected with the evolution of the plasma expansion and ionization dynamics. The potential of XFEL-based resonant SAXS to obtain three-dimensional ultrafast, nanoscopic information on density and opacity may offer a unique path for the characterization of dynamic processes in High Energy Density plasmas.

Published

2021

36. Measuring the structure and equation of state of polyethylene terephthalate at megabar pressures

Author

Lütgert, B. J., Vorberger, J., Hartley, N., Voigt, K., Rödel, M., Schuster, A., Brown, S., Cowan, T., Cunningham, E., Döppner, T., Falcone, R. W., Fletcher, L. B., Galtier, E., Glenzer, S. H., Laso García, A., Gericke, D. O., Heimann, P. A., Lee, H. J., Mcbride, E. E., Pelka, A., Prencipe, I., Ravasio, A., Saunders, A. M., Schölmerich, M., SchÖrner, M., Sun, P., and Kraus, D.

Abstract

We present structure measurements of biaxially orientated polyethylene terephthalate (PET, (C10H8O4)n , also called mylar) shock-compressed to (155+/-20) GPa and (6000+/-1000) K using in situ X-ray diffraction. Comparing to density functional theory molecular dynamics simulations, we find a highly correlated liquid that exhibits a temperature signficantly lower than predicted by some equation-of-state tables, which underlines the influence of complex chemical interactions in this regime. Indeed, at the inferred temperature and pressure, formation of nanodiamonds may be expected as recently observed in polystyrene at similar conditions. While some hints of diamond formation from PET are visible in the diffraction data, the strong liquid correlations prevent a conclusive statement as to whether diamonds are formed inside the sample volume.

Published

2021

37. Dataset: Measuring the structure and equation of state of polyethylene terephthalate at megabar pressures

Author

Lütgert, B. J., Vorberger, J., Hartley, N., Voigt, K., Rödel, M., Schuster, A., Benuzzi-Mounaix, A., Brown, S., Cowan, T., Cunningham, E., Döppner, T., Falcone, R. W., Fletcher, L. B., Galtier, E., Glenzer, S. H., Laso García, A., Gericke, D. O., Heimann, P. A., Lee, H. J., McBride, E. E., Pelka, A., Prencipe, I., Saunders, A. M., Schölmerich, M., Schörner, M., Sun, P., Vinci, T., Ravasio, A., and Kraus, D.

Abstract

This repository contains raw-data related to our publication "Measuring the structure and equation of state of polyethylene terephthalate at megabar pressures". The XRD data in the "LCLS" folder is accompanied with a "calibration.poni" file that provides information about the experiment's geometry and can be used in pyFAI (GitHub page) or Dioptas (GitHub page) to integrate the two-dimensional data azimuthally. Integrated XRD data after background-subtraction and filter-corrections is presented in Fig. 2 and 3 of the manuscript while 2D data of run 215 is used in Fig. 1. The "shotlist.csv" file contains information about the relative X-ray to drive-laser timing, shot-type and X-ray energy for the individual events. VISAR, SOP and reflectivity measurements can be found in the "LULI" directory. 2ω-VISAR and SOP datasets of shot 08 are displayed as inserts in Fig. 5 (the first after performing a ghost-fringe subtraction). "shotlist.csv" provides additional parameters. The DFTMD folder contains the results of our density functional theory molecular dynamics simulation. In the "XRD" subdirectory, "wrofk_mylar_chomd*.dat" files can be found in which the quantities to calculate the lineouts in Fig. 3 and 4 are saved for given temperatures, pressures and densities. The header of those files is given in "header.txt" and additional information about the conditions and settings for individual calculations can be obtained from "param_mylar_md.txt". The dataset for the Hugoniot curve from our DFT-MD equation-of-state (which is plotted in Fig. 5) is provided in the "Hugoniot" sub-folder.

Published

2021

38. Data publication: Efficient laser-driven proton and Bremsstrahlung generation from cluster-assembled foam targets

Author

Prencipe, I., Metzkes-Ng, J., Pazzaglia, A., Bernert, C., Dellasega, D., Fedeli, L., Formenti, A., Garten, M., Kluge, T., Kraft, S., Laso García, A., Maffini, A., Obst-Hübl, L., Rehwald, M., Sobiella, M., Zeil, K., Schramm, U., Cowan, T., and Passoni, M.

Subjects

foam targets, laser-driven ion acceleration, TNSA, laser-driven Bremsstrahlung generation, near-critical density plasma, nanostructured targets

Abstract

Archiving of raw and results data and scripts as describef in the associated paper

Published

2021

39. Preliminary results from the x-ray spectrometers at Draco PW laser facility

Author

Stefanikova, R., Pan, X., Smid, M., Schlenvoigt, H.-P., Prencipe, I., Gaus, L., Umlandt, M. E. P., Vescovi Pinochet, M. A., Reimold, M., Ziegler, T., Kroll, F., Kraft, S., Schramm, U., Zeil, K., Metzkes-Ng, J., and Falk, K.

Subjects

laser-produced plasma, x-ray spectrometer, characteristic emission lines

Abstract

A large amount of complex processes within laser-produced plasmas put a huge demand for precise diagnostics methods. For example, x-ray emission spectroscopy can be used to study atomic physics and plasma conditions. Here, we introduce two new x-ray spectrometers installed in the Ion acceleration lab at the Draco PW laser facility. Availability of such diagnostics at the Draco PW Ti:sapphire 30 fs laser system (i.e. ultra-short pulse system) allows not only for studying unique plasma conditions driving the ion acceleration, but also exploring new possibilities for x-ray backlighters suitable for high energy density experiments. Both spectrometers are utilized for acquisition of Ti spectral lines, but offer different spectral resolution and range. Quartz crystal spectrometer has wider spectral range, including Ti K-α and He-α emission lines in the spectrum, whereas Ge crystal spectrometer focuses on K-α emission lines and offers 1D spatial imaging. We present first results demonstrating the capabilities of both spectrometers. The first spectroscopic measurements include the emission spectra measurements from flat Ti targets used for proton acceleration calibration and optimization with and without laser pre-pulse and the use of structured targets for enhanced x-ray emission as well as tailoring of the electron spectra for optimization of the proton acceleration process.

Published

2021

40. Resonant SAXS data used in publication: 'Probing ultrafast laser plasma processes inside solids with resonant small angle X-ray scattering'

Author

Gaus, L., Bischoff, L., Bussmann, M., Cunningham, E., Curry, C. B., E, Juncheng, Galtier, E., Gauthier, M., Laso García, A., Garten, M., Glenzer, S., Grenzer, J., Gutt, C., Hartley, N., Huang, L., Hübner, U., Kraus, D., Lee, H. J., McBride, E. E., Metzkes-Ng, J., Nagler, B., Nakatsutsumi, M., Nikl, J., Ota, M., Pelka, A., Prencipe, I., Randolph, L., Rödel, M., Sakawa, Y., Schlenvoigt, H.-P., Smid, M., Treffert, F., Voigt, K., Zeil, K., Cowan, T., Schramm, U., and Kluge, T.

Abstract

Resonant Small-angle x-ray scattering raw data obtained in measurements at MEC at LCLS and evalutation of the asymmetry in the scattering patterns. The data set is structured in case 1/Si-Cu-compound targets and case 2/Cu-only-targets as presented in the publication for on- and off-resonant XFEL probe energies.

Published

2021

41. Probing ultrafast laser plasma processes inside solids with resonant small angle X-ray scattering

Author

(0000-0002-6914-4083) Gaus, L., (0000-0003-3968-7498) Bischoff, L., (0000-0002-8258-3881) Bussmann, M., (0000-0002-0976-4416) Cunningham, E., (0000-0001-8756-181X) Curry, C. B., E, Juncheng, Galtier, E., (0000-0001-6608-9325) Gauthier, M., (0000-0002-7671-0901) Laso García, A., (0000-0001-6994-2475) Garten, M., (0000-0001-9112-0558) Glenzer, S., Grenzer, J., Gutt, C., Hartley, N., Huang, L., Hübner, U., (0000-0002-6350-4180) Kraus, D., Lee, H. J., McBride, E. E., (0000-0002-9556-0662) Metzkes-Ng, J., Nagler, B., (0000-0003-0868-4745) Nakatsutsumi, M., (0000-0003-0131-0628) Nikl, J., Ota, M., Pelka, A., (0000-0003-0931-1350) Prencipe, I., Randolph, L., Rödel, M., Sakawa, Y., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0002-7162-7500) Smid, M., (0000-0003-1277-4241) Treffert, F., Voigt, K., (0000-0003-3926-409X) Zeil, K., (0000-0002-5845-000X) Cowan, T., (0000-0003-0390-7671) Schramm, U., (0000-0003-4861-5584) Kluge, T., (0000-0002-6914-4083) Gaus, L., (0000-0003-3968-7498) Bischoff, L., (0000-0002-8258-3881) Bussmann, M., (0000-0002-0976-4416) Cunningham, E., (0000-0001-8756-181X) Curry, C. B., E, Juncheng, Galtier, E., (0000-0001-6608-9325) Gauthier, M., (0000-0002-7671-0901) Laso García, A., (0000-0001-6994-2475) Garten, M., (0000-0001-9112-0558) Glenzer, S., Grenzer, J., Gutt, C., Hartley, N., Huang, L., Hübner, U., (0000-0002-6350-4180) Kraus, D., Lee, H. J., McBride, E. E., (0000-0002-9556-0662) Metzkes-Ng, J., Nagler, B., (0000-0003-0868-4745) Nakatsutsumi, M., (0000-0003-0131-0628) Nikl, J., Ota, M., Pelka, A., (0000-0003-0931-1350) Prencipe, I., Randolph, L., Rödel, M., Sakawa, Y., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0002-7162-7500) Smid, M., (0000-0003-1277-4241) Treffert, F., Voigt, K., (0000-0003-3926-409X) Zeil, K., (0000-0002-5845-000X) Cowan, T., (0000-0003-0390-7671) Schramm, U., and (0000-0003-4861-5584) Kluge, T.

Abstract

Extreme states of matter exist throughout the universe e.g. inside planetary cores, stars or astrophysical jets. Such conditions can be generated in the laboratory in the interaction of powerful lasers with solids. Yet, the measurement of the subsequent plasma dynamics with regard to density, temperature and ionization is a major experimental challenge. However, ultra-short X-ray pulses provided by X-ray free electron lasers (XFELs) allow for dedicated studies, which are highly relevant to study laboratory astrophysics, laser-fusion research or laser-plasma-based particle acceleration. Here, we report on experiments that employ a novel ultrafast method, which allows to simultaneously access temperature, ionization state and nanometer scale expansion dynamics in high-intensity laser-driven solid-density plasmas with a single X-ray detector. Using this method, we gain access to the expansion dynamics of a buried layer in compound samples, and we measure opacity changes arising from bound-bound resonance transitions in highly ionized copper. The presence of highly ionized copper leads to a temperature estimate of at least 2 million Kelvin already after the first 100 femtoseconds following the high-intensity laser irradiation. More specifically, we make use of asymmetries in small-angle X-ray scattering (SAXS) patterns, which arise from different spatial distributions of absorption and scattering cross sections in nanostructured grating samples when we tune an XFEL to atomic resonant energies of copper. Thereby, changes in asymmetry can be connected with the evolution of the plasma expansion and ionization dynamics. The potential of XFEL-based resonant SAXS to obtain three-dimensional ultrafast, nanoscopic information on density and opacity may offer a unique path for the characterization of dynamic processes in High Energy Density plasmas.

Published

2021

42. Targets for pump probe experiments at upcoming XFEL facilities

Author

(0000-0003-4861-5584) Kluge, T., (0000-0002-6914-4083) Gaus, L., (0000-0003-0931-1350) Prencipe, I., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., (0000-0002-5845-000X) Cowan, T., (0000-0003-4861-5584) Kluge, T., (0000-0002-6914-4083) Gaus, L., (0000-0003-0931-1350) Prencipe, I., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., and (0000-0002-5845-000X) Cowan, T.

Abstract

Targets for pump probe experiments at upcoming XFEL facilities

Published

2021

43. Resonant SAXS data used in publication: 'Probing ultrafast laser plasma processes inside solids with resonant small angle X-ray scattering'

Author

(0000-0002-6914-4083) Gaus, L., (0000-0003-3968-7498) Bischoff, L., (0000-0002-8258-3881) Bussmann, M., (0000-0002-0976-4416) Cunningham, E., (0000-0001-8756-181X) Curry, C. B., E, Juncheng, Galtier, E., (0000-0001-6608-9325) Gauthier, M., (0000-0002-7671-0901) Laso García, A., (0000-0001-6994-2475) Garten, M., (0000-0001-9112-0558) Glenzer, S., Grenzer, J., Gutt, C., (0000-0002-6268-2436) Hartley, N., Huang, L., Hübner, U., (0000-0002-6350-4180) Kraus, D., Lee, H. J., McBride, E. E., (0000-0002-9556-0662) Metzkes-Ng, J., Nagler, B., (0000-0003-0868-4745) Nakatsutsumi, M., (0000-0003-0131-0628) Nikl, J., Ota, M., Pelka, A., (0000-0003-0931-1350) Prencipe, I., Randolph, L., Rödel, M., Sakawa, Y., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0002-7162-7500) Smid, M., (0000-0003-1277-4241) Treffert, F., Voigt, K., (0000-0003-3926-409X) Zeil, K., (0000-0002-5845-000X) Cowan, T., (0000-0003-0390-7671) Schramm, U., (0000-0003-4861-5584) Kluge, T., (0000-0002-6914-4083) Gaus, L., (0000-0003-3968-7498) Bischoff, L., (0000-0002-8258-3881) Bussmann, M., (0000-0002-0976-4416) Cunningham, E., (0000-0001-8756-181X) Curry, C. B., E, Juncheng, Galtier, E., (0000-0001-6608-9325) Gauthier, M., (0000-0002-7671-0901) Laso García, A., (0000-0001-6994-2475) Garten, M., (0000-0001-9112-0558) Glenzer, S., Grenzer, J., Gutt, C., (0000-0002-6268-2436) Hartley, N., Huang, L., Hübner, U., (0000-0002-6350-4180) Kraus, D., Lee, H. J., McBride, E. E., (0000-0002-9556-0662) Metzkes-Ng, J., Nagler, B., (0000-0003-0868-4745) Nakatsutsumi, M., (0000-0003-0131-0628) Nikl, J., Ota, M., Pelka, A., (0000-0003-0931-1350) Prencipe, I., Randolph, L., Rödel, M., Sakawa, Y., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0002-7162-7500) Smid, M., (0000-0003-1277-4241) Treffert, F., Voigt, K., (0000-0003-3926-409X) Zeil, K., (0000-0002-5845-000X) Cowan, T., (0000-0003-0390-7671) Schramm, U., and (0000-0003-4861-5584) Kluge, T.

Abstract

Resonant Small-angle x-ray scattering raw data obtained in measurements at MEC at LCLS and evalutation of the asymmetry in the scattering patterns. The data set is structured in case 1/Si-Cu-compound targets and case 2/Cu-only-targets as presented in the publication for on- and off-resonant XFEL probe energies.

Published

2021

44. Data publication: Efficient laser-driven proton and Bremsstrahlung generation from cluster-assembled foam targets

Author

(0000-0003-0931-1350) Prencipe, I., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-7486-2576) Pazzaglia, A., Bernert, C., (0000-0002-7389-9307) Dellasega, D., (0000-0002-7215-4178) Fedeli, L., (0000-0002-7887-9313) Formenti, A., (0000-0001-6994-2475) Garten, M., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-7671-0901) Laso García, A., (0000-0002-3388-5330) Maffini, A., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0001-6200-6406) Rehwald, M., Sobiella, M., (0000-0003-3926-409X) Zeil, K., (0000-0003-0390-7671) Schramm, U., (0000-0002-5845-000X) Cowan, T., (0000-0002-7844-3691) Passoni, M., (0000-0003-0931-1350) Prencipe, I., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-7486-2576) Pazzaglia, A., Bernert, C., (0000-0002-7389-9307) Dellasega, D., (0000-0002-7215-4178) Fedeli, L., (0000-0002-7887-9313) Formenti, A., (0000-0001-6994-2475) Garten, M., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-7671-0901) Laso García, A., (0000-0002-3388-5330) Maffini, A., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0001-6200-6406) Rehwald, M., Sobiella, M., (0000-0003-3926-409X) Zeil, K., (0000-0003-0390-7671) Schramm, U., (0000-0002-5845-000X) Cowan, T., and (0000-0002-7844-3691) Passoni, M.

Abstract

Archiving of raw and results data and scripts as describef in the associated paper

Published

2021

45. Dataset: Measuring the structure and equation of state of polyethylene terephthalate at megabar pressures

Author

(0000-0002-2593-573X) Lütgert, B. J., (0000-0001-5926-9192) Vorberger, J., (0000-0002-6268-2436) Hartley, N., Voigt, K., Rödel, M., (0000-0001-5489-5952) Schuster, A., Benuzzi-Mounaix, A., Brown, S., (0000-0002-5845-000X) Cowan, T., Cunningham, E., Döppner, T., Falcone, R. W., Fletcher, L. B., Galtier, E., Glenzer, S. H., (0000-0002-7671-0901) Laso García, A., Gericke, D. O., Heimann, P. A., Lee, H. J., McBride, E. E., Pelka, A., Prencipe, I., Saunders, A. M., Schölmerich, M., Schörner, M., Sun, P., Vinci, T., Ravasio, A., (0000-0002-6350-4180) Kraus, D., (0000-0002-2593-573X) Lütgert, B. J., (0000-0001-5926-9192) Vorberger, J., (0000-0002-6268-2436) Hartley, N., Voigt, K., Rödel, M., (0000-0001-5489-5952) Schuster, A., Benuzzi-Mounaix, A., Brown, S., (0000-0002-5845-000X) Cowan, T., Cunningham, E., Döppner, T., Falcone, R. W., Fletcher, L. B., Galtier, E., Glenzer, S. H., (0000-0002-7671-0901) Laso García, A., Gericke, D. O., Heimann, P. A., Lee, H. J., McBride, E. E., Pelka, A., Prencipe, I., Saunders, A. M., Schölmerich, M., Schörner, M., Sun, P., Vinci, T., Ravasio, A., and (0000-0002-6350-4180) Kraus, D.

Abstract

This repository contains raw-data related to our publication "Measuring the structure and equation of state of polyethylene terephthalate at megabar pressures". The XRD data in the "LCLS" folder is accompanied with a "calibration.poni" file that provides information about the experiment's geometry and can be used in GitHub page) to integrate the two-dimensional data azimuthally. Integrated XRD data after background-subtraction and filter-corrections is presented in Fig. 2 and 3 of the manuscript while 2D data of run 215 is used in Fig. 1. The "shotlist.csv" file contains information about the relative X-ray to drive-laser timing, shot-type and X-ray energy for the individual events. VISAR, SOP and reflectivity measurements can be found in the "LULI" directory. 2ω-VISAR and SOP datasets of shot 08 are displayed as inserts in Fig. 5 (the first after performing a ghost-fringe subtraction). "shotlist.csv" provides additional parameters. The DFTMD folder contains the results of our density functional theory molecular dynamics simulation. In the "XRD" subdirectory, "wrofk_mylar_chomd*.dat" files can be found in which the quantities to calculate the lineouts in Fig. 3 and 4 are saved for given temperatures, pressures and densities. The header of those files is given in "header.txt" and additional information about the conditions and settings for individual calculations can be obtained from "param_mylar_md.txt". The dataset for the Hugoniot curve from our DFT-MD equation-of-state (which is plotted in Fig. 5) is provided in the "Hugoniot" sub-folder.

Published

2021

46. Laser produced electromagnetic pulses: generation, detection and mitigation

Author

Consoli, F., Tikhonchuk, V. T., Bardon, M., Bradford, P., Carrol, D. C., Cikhardt, J., Cipriani, M., Clarke, R. J., Cowan, T. E., Danson, C. N., Angelis, R., Marco, M., Dubois, J.-L., Etchessahar, B., Laso Garcia, A., Hillier, D. I., Weiman, J., Kmetik, V., Krasa, J., Li, Y., Lubrano, F., McKenna, P., Metzkes-Ng, J., Poye, A., Prencipe, I., Raczka, P., Smith, R. A., Vrana, R., Woolsey, N. C., Zemaityte, E., Zhang, Y., Zhang, Z., Zielbauer, B., Neely, D., Honsa, A., Consoli, F., Tikhonchuk, V. T., Bardon, M., Bradford, P., Carrol, D. C., Cikhardt, J., Cipriani, M., Clarke, R. J., Cowan, T. E., Danson, C. N., Angelis, R., Marco, M., Dubois, J.-L., Etchessahar, B., Laso Garcia, A., Hillier, D. I., Weiman, J., Kmetik, V., Krasa, J., Li, Y., Lubrano, F., McKenna, P., Metzkes-Ng, J., Poye, A., Prencipe, I., Raczka, P., Smith, R. A., Vrana, R., Woolsey, N. C., Zemaityte, E., Zhang, Y., Zhang, Z., Zielbauer, B., Neely, D., and Honsa, A.

Abstract

This paper provides an up-to-date review of the problems related to the generation, detection and mitigation of strong electromagnetic pulses created in the interaction of high-power, high-energy laser pulses with different types of solid targets. It includes new experimental data obtained independently at several international laboratories. The mechanisms of electromagnetic field generation are analyzed and considered as a function of the intensity and the spectral range of emissions they produce. The major emphasis is put on the GHz frequency domain, which is the most damaging for electronics and may have important applications. The physics of electromagnetic emissions in other spectral domains, in particular THz and MHz, is also discussed. The theoretical models and numerical simulations are compared with the results of experimental measurements, with special attention to the methodology of measurements and complementary diagnostics. Understanding the underlying physical processes is the basis for developing techniques to mitigate the electromagnetic threat and to harness electromagnetic emissions, which may have promising applications.

Published

2020

47. Mirror to measure Small Angle X-ray Scattering signal in high energy density experiments

Author

(0000-0002-7162-7500) Smid, M., Bähtz, C., (0000-0002-7671-0901) Laso García, A., Göde, S., Grenzer, J., (0000-0003-4861-5584) Kluge, T., Konôpková, Z., Makita, M., Pelka, A., Prencipe, I., Preston, T., Rödel, M., (0000-0002-5845-000X) Cowan, T., (0000-0002-7162-7500) Smid, M., Bähtz, C., (0000-0002-7671-0901) Laso García, A., Göde, S., Grenzer, J., (0000-0003-4861-5584) Kluge, T., Konôpková, Z., Makita, M., Pelka, A., Prencipe, I., Preston, T., Rödel, M., and (0000-0002-5845-000X) Cowan, T.

Abstract

Small angle x-ray scattering (SAXS) is a well established technique to detect nanometer scale structure in matter. In typical setup, this diagnostics has an detector directly opened towards the scattering target. However, in a harsh environment of high intensity laser interaction, many high energetic particles and strong radiation are emerging from the laser target interaction. Such setup would therefore suffer a significant increase of noise due to this background which could eventually disable this measurement. In this paper, we present a novel tool consisting of mosaic graphite crystal which works as a mirror for the SAXS signal and allows to hide the detector behind proper shielding. This paper studies the performance of such mirror both by experiment at the European XFEL laboratory and by simulations.

Published

2020

48. Measurement of Diamond Nucleation Rates from Hydrocarbons at Conditions Comparable to the Interiors of Icy Giant Planets

Author

Schuster, A. K., Hartley, N. J., Vorberger, J., Döppner, T., Driel, T., Falcone, R. W., Fletcher, L. B., Frydrych, S., Galtier, E., Gamboa, E. J., Gericke, D. O., Glenzer, S. H., Granados, E., Macdonald, M. J., Mackinnon, A. J., Mcbride, E. E., Nam, I., Neumayer, P., Pak, A., Prencipe, I., Rohatsch, K., Saunders, A. M., Sun, P., Kraus, D., Schuster, A. K., Hartley, N. J., Vorberger, J., Döppner, T., Driel, T., Falcone, R. W., Fletcher, L. B., Frydrych, S., Galtier, E., Gamboa, E. J., Gericke, D. O., Glenzer, S. H., Granados, E., Macdonald, M. J., Mackinnon, A. J., Mcbride, E. E., Nam, I., Neumayer, P., Pak, A., Prencipe, I., Rohatsch, K., Saunders, A. M., Sun, P., and Kraus, D.

Abstract

We present measurements of the nucleation rate into a diamond lattice in dynamically compressed polystyrene obtained in a pump-probe experiment using a high energy laser system and in situ femtosecond X-ray diffraction. Different temperature-pressure conditions that occur in planetary interiors were probed. For a single shock reaching 70GPa and 3000K no diamond formation was observed while with a double shock driving polystyrene to pressures around 150GPa and temperatures around 5000K nucleation rates between 1029 m-3s-1 and 1034 m-3s-1 were recorded. These nucleation rates do not a agree with predictions of recent theoretical models for carbon-hydrogen mixtures by many orders of magnitude. Our data suggests that there is indeed significant diamond formation to be expected inside icy giant planets like Neptune and Uranus.

Published

2020

49. Mirror to measure small angle x-ray scattering signal in high energy density experiments

Author

Šmíd, M., primary, Baehtz, C., additional, Pelka, A., additional, Laso García, A., additional, Göde, S., additional, Grenzer, J., additional, Kluge, T., additional, Konopkova, Z., additional, Makita, M., additional, Prencipe, I., additional, Preston, T. R., additional, Rödel, M., additional, and Cowan, T. E., additional

Published

2020

50. Measurement of diamond nucleation rates from hydrocarbons at conditions comparable to the interiors of icy giant planets

Author

Schuster, A. K., primary, Hartley, N. J., additional, Vorberger, J., additional, Döppner, T., additional, van Driel, T., additional, Falcone, R. W., additional, Fletcher, L. B., additional, Frydrych, S., additional, Galtier, E., additional, Gamboa, E. J., additional, Gericke, D. O., additional, Glenzer, S. H., additional, Granados, E., additional, MacDonald, M. J., additional, MacKinnon, A. J., additional, McBride, E. E., additional, Nam, I., additional, Neumayer, P., additional, Pak, A., additional, Prencipe, I., additional, Voigt, K., additional, Saunders, A. M., additional, Sun, P., additional, and Kraus, D., additional

Published

2020