Your search keyword '"Gaus, L."' showing total 165 results

51. 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

52. Proton beam quality enhancement by spectral phase control of a PW-class laser system

Author

Ziegler, T., Albach, D., Bernert, C., Bock, S., Brack, F.-E., Cowan, T. E., Dover, N. P., Garten, M., Gaus, L., Gebhardt, R., Goethel, I., Helbig, U., Irman, A., Kiriyama, H., Kluge, T., Kon, A., Kraft, S., Kroll, F., Loeser, M., Metzkes-Ng, J., Obst-Huebl, L., Püschel, T., Rehwald, M., Schlenvoigt, H.-P., Schramm, U., and Zeil, K.

Abstract

This repository contains the experimental raw data, the analyzed data and corresponding scripts as well as figures for the "Proton beam quality enhancement by spectral phase control of a PW-class laser system" publication. https://doi.org/10.1038/s41598-021-86547-x

Published

2021

53. Synthetic probing of ionization dynamics in the solid density plasmas driven by relativistic laser pulses using resonant SAXS

Author

Huang, L. G., Kluge, T., Gaus, L., Schlenvoigt, H.-P., and Cowan, T. E.

Abstract

Understanding the ionization dynamics is fundamentally important in the interaction of a relativistic laser pulse with a solid density target. In this talk, firstly we present the particle-in-cell (PIC) simulations with various collisional ionization and potential models, showing the target heating, magnetic instabiltiy and plasma resistivity are highly model-dependent \cite{Huang2016,Huang2017}. Secondly, we propose to probe the evolution of ionic density at specific bound-bound resonances by scanning the XFEL photon energy via established SAXS method, which is cable to access the spatial–temporal resolution down to few nanometers and femtoseconds simultaneously. The plasma opacity plays a key role of the XFEL absorption, which in turn affects the resonant SAXS pattern contributed by the imaginary part of ionic scattering form factor\cite{Kluge2016}. We present the calculation of plasma opacity using the atomic collisional-radiative code SCFLY and further simulate the synthetic resonant SAXS imaging pattern which shows strong asymmetric feature. Our recently performed experiment reveals the connection of the temporal evolution of the asymmetry signal and ionization dynamics \cite{Gaus2020}. [1] L. G. Huang, T. Kluge, and T. E. Cowan, Physics of Plasmas23, 063112 (2016).[2] L. G. Huang, H. P. Schlenvoigt, H. Takabe, and T. E. Cowan, Physics of Plasmas24, 103115 (2017). [3] T. Kluge, M. Bussmann, H.-K. Chung, C. Gutt, L. G. Huang, M. Zacharias, U. Schramm, and T. E.Cowan, Physics of Plasmas23, 033103 (2016). [4] L. Gaus, L. Bischoff, M. Bussmann, E. Cunningham, C. B. Curry, E. Galtier, M. Gauthier, A. L.Garc ́ıa, M. Garten, S. Glenzer, J. Grenzer, C. Gutt, N. J. Hartley, L. Huang, U. H ̈ubner, D. Kraus,H. J. Lee, E. E. McBride, J. Metzkes-Ng, B. Nagler, M. Nakatsutsumi, J. Nikl, M. Ota, A. Pelka,I. Prencipe, L. Randolph, M. R ̈odel, Y. Sakawa, H.-P. Schlenvoigt, M.ˇSm ́ıd, F. Treffert, K. Voigt,K. Zeil, T. E. Cowan, U. Schramm, and T. Kluge, “Probing ultrafast laser plasma processes insidesolids with resonant small-angle x-ray scattering,” (2020), arXiv:2012.07922 [physics.plasm-ph].

Published

2021

54. Asymmetries in resonant SAXS

Author

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

Abstract

Asymmetries in resonant SAXS

Published

2021

55. 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

56. High intensity laser interaction with solid-density cryogenic hydrogen jet targets

Author

Bernert, C., Assenbaum, S., Brack, F.-E., Cowan, T., B. Curry, C., Fiuza, F., Garten, M., Gaus, L., Gauthier, M., Göde, S., Göthel, I., Glenzer, S. H., Hübl, A., Kluge, T., Kraft, S., Kroll, F., Metzkes-Ng, J., Löser, M., Obst-Hübl, L., Rehwald, M., Reimold, M., Schlenvoigt, H.-P., Schoenwaelder, C., Schramm, U., Siebold, M., Treffert, F., Ziegler, T., and Zeil, K.

Subjects

cryogenic jet, ion acceleration, high intensity laser

Abstract

Ultra-intense short-pulse lasers in the Petawatt regime and intensity range of 1021W/cm2 offer the possibility to study new compact accelerator schemes by utilizing solid density targets for the generation of energetic ion beams. The optimization of the acceleration process demands comprehensive exploration of the involved plasma dynamics. This applies not only on the femtosecond but also on the pico- to nanosecond timescale, where the laser rising edge modifies the target prior to the 30 fs laser peak. Cryogenic hydrogen jet targets with µm-scale transverse size and solid density (5.2x1022 cm-3) offer the superb opportunity for renewable and debris-free acceleration sources and at the same time allow for comprehensive experimental investigation and realistic simulation of the rich physics involved in the laser target interaction. Here, we present the results of an experiment for laser proton acceleration from a cryogenic hydrogen jet target at the DRACO-PW laser. Optimized acceleration performance is achieved by tailoring the targets plasma density via hydrodynamic expansion induced by a short low-intensity pre-pulse. Optical shadowgraphy probing is utilized to give a realistic input of the targets plasma density for 3 dimensional particle-in-cell simulations of the particle acceleration process.

Published

2021

57. 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

58. Off-harmonic optical probing of high intensity laser interaction with solid-density cryogenic hydrogen jet targets

Author

Bernert, C., Albach, D., Assenbaum, S., Brack, F.-E., Bock, S., Curry, C. B., Garten, M., Gaus, L., Gauthier, M., Glenzer, S. H., Göde, S., Göthel, I., Kim, J. B., Kluge, T., Kraft, S., Kuntzsch, M., Löser, M., Metzkes-Ng, J., Obst-Hübl, L., Püschel, T., Schlenvoigt, H.-P., Schoenwaelder, C., Siebold, M., Treffert, F., Umlandt, M. E. P., Vescovi Pinochet, M. A., Zeil, K., Ziegler, T., Schramm, U., and Rehwald, M.

Subjects

optical probing, ion acceleration, high intensity laser

Abstract

High-intensity short-pulse lasers enable novel compact accelerator schemes for the generation of energetic ion beams. The experimental investigation of the process remains challenging due to the femtosecond timescale and micrometer size of the acceleration. Commonly, diagnostic results are explained by a comparison of the experimental findings with computationally expensive particle-in-cell simulations. Cryogenic hydrogen jet targets (~30 critical densities) with µm-scale transverse size are particularly well suited for this approach. Time-resolved diagnostics like optical probing can infer the state of the target at the initialization time of the simulation and benchmark the simulation results. Here we present the implementation of an off-harmonic optical probing setup at an experiment for laser proton acceleration with a cylindrical hydrogen jet target at the DRACO PW laser with plasma-mirror cleaned laser contrast. We show under which conditions the technique overcomes the problem of parasitic plasma self-emission, present technical aspects of the off-harmonic probing technique together with experimental results of the observed plasma dynamics.

Published

2021

59. Ultra-short pulse laser-driven acceleration of protons to 80 MeV from density tailored cryogenic hydrogen jets

Author

(0000-0001-6200-6406) Rehwald, M., Bernert, C., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., Curry, C. B., Fiuza, F., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Gauthier, M., Göde, S., Göthel, I., Glenzer, S. H., (0000-0003-1943-7141) Hübl, A., Kim, J. B., (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., (0000-0001-7858-0007) Löser, M., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., Schoenwaelder, C., (0000-0003-0390-7671) Schramm, U., (0000-0002-4697-3014) Siebold, M., Treffert, F., (0000-0002-3727-7017) Ziegler, T., (0000-0003-3926-409X) Zeil, K., (0000-0001-6200-6406) Rehwald, M., Bernert, C., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., Curry, C. B., Fiuza, F., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Gauthier, M., Göde, S., Göthel, I., Glenzer, S. H., (0000-0003-1943-7141) Hübl, A., Kim, J. B., (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., (0000-0001-7858-0007) Löser, M., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., Schoenwaelder, C., (0000-0003-0390-7671) Schramm, U., (0000-0002-4697-3014) Siebold, M., Treffert, F., (0000-0002-3727-7017) Ziegler, T., and (0000-0003-3926-409X) Zeil, K.

Abstract

Laser plasma based particle accelerators have attracted great interest in fields where conventional accelerators reach limits based on size, cost or beam parameters. Designing future laser ion accelerators requires a high degree of control of the advanced acceleration schemes involved and predictive modelling capabilities. Here, we investigate the interaction of petawatt class laser pulses with a micrometer sized cryogenic hydrogen jet target. Controlled pre-expansion of the target by low intensity pre-pulses allowed for tailored density scans over more than two orders of magnitude. On-shot target characterization using two-color optical probing provided precise starting conditions for numerical simulations. For the optimal target density profile in the near critical regime proton energies of up to 80 MeV were observed which represents a two-fold increase with respect to the initial solid target case. Three-dimensional particle in cell simulations confirmed the transition between different acceleration mechanisms involved and suggested the magnetic-vortex regime to be responsible for the highest proton energies achieved.

Published

2021

60. Asymmetries in resonant SAXS

Author

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

Abstract

Asymmetries in resonant SAXS

Published

2021

61. 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., (0000-0003-1184-2097) 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., (0000-0001-8090-2626) 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., (0000-0003-1184-2097) 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., (0000-0001-8090-2626) 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

62. Proton beam quality enhancement by spectral phase control of a PW-class laser system

Author

(0000-0002-3727-7017) Ziegler, T., (0000-0001-5602-3007) Albach, D., Bernert, C., (0000-0002-1919-8585) Bock, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0003-0420-3940) Dover, N. P., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Gebhardt, R., Goethel, I., Helbig, U., (0000-0002-4626-0049) Irman, A., Kiriyama, H., (0000-0003-4861-5584) Kluge, T., Kon, A., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0001-7858-0007) Löser, M., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-8143-0827) Nishiuchi, M., (0000-0001-9236-8037) Obst-Hübl, L., Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., (0000-0002-3727-7017) Ziegler, T., (0000-0001-5602-3007) Albach, D., Bernert, C., (0000-0002-1919-8585) Bock, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0003-0420-3940) Dover, N. P., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Gebhardt, R., Goethel, I., Helbig, U., (0000-0002-4626-0049) Irman, A., Kiriyama, H., (0000-0003-4861-5584) Kluge, T., Kon, A., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., (0000-0001-7858-0007) Löser, M., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-8143-0827) Nishiuchi, M., (0000-0001-9236-8037) Obst-Hübl, L., Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., and (0000-0003-3926-409X) Zeil, K.

Abstract

We report on experimental investigations of proton acceleration from solid foils irradiated with PW‑class laser‑pulses, where highest proton cut‑off energies were achieved for temporal pulse parameters that varied significantly from those of an ideally Fourier transform limited (FTL) pulse. Controlled spectral phase modulation of the driver laser by means of an acousto‑optic programmable dispersive filter enabled us to manipulate the temporal shape of the last picoseconds around the main pulse and to study the effect on proton acceleration from thin foil targets. The results show that applying positive third order dispersion values to short pulses is favourable for proton acceleration and can lead to maximum energies of 70 MeV in target normal direction at 18 J laser energy for thin plastic foils, significantly enhancing the maximum energy compared to ideally compressed FTL pulses. The paper further proves the robustness and applicability of this enhancement effect for the use of different target materials and thicknesses as well as laser energy and temporal intensity contrast settings. We demonstrate that application relevant proton beam quality was reliably achieved over many months of operation with appropriate control of spectral phase and temporal contrast conditions using a state‑of‑the‑art high‑repetition rate PW laser system.

Published

2021

63. Fully characterised and online monitored beamline for high dose rate laser proton irradiation experiments at Draco PW

Author

(0000-0002-9859-2408) Brack, F.-E., (0000-0002-0275-9892) Kroll, F., (0000-0002-6914-4083) Gaus, L., (0000-0003-1739-0159) Bernert, C., (0000-0002-0582-1444) Beyreuther, E., (0000-0002-5845-000X) Cowan, T., Karsch, L., (0000-0002-0638-6990) Kraft, S., Leßmann, E., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0003-4128-5498) Pawelke, J., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., Sobiella, M., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-3727-7017) Ziegler, T., (0000-0003-3926-409X) Zeil, K., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-0275-9892) Kroll, F., (0000-0002-6914-4083) Gaus, L., (0000-0003-1739-0159) Bernert, C., (0000-0002-0582-1444) Beyreuther, E., (0000-0002-5845-000X) Cowan, T., Karsch, L., (0000-0002-0638-6990) Kraft, S., Leßmann, E., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0003-4128-5498) Pawelke, J., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., Sobiella, M., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-3727-7017) Ziegler, T., and (0000-0003-3926-409X) Zeil, K.

Abstract

Laser-driven proton pulse provide unique properties in terms of pulse structure (ns) and instantaneous dose rate (10^9 Gy/s) but - inherently broadband and highly divergent - pose a challenge to established beamline concepts on the path to application-adapted irradiation field formation, particularly for three-dimensional cases. We present the successful implementation and characterisation of a highly efficient and tuneable dual pulsed solenoid beamline at the Draco PW facility[1] to generate volumetric dose distribution tailored to specific applications[2]. The vast experimental scope and already successfully performed studies range from systematic volumetric in-vivo tumour irradiations in a dedicated mouse model (with a stable mean dose delivery of ±10 % and a spatial dose homogeneity of ±5 % over a cylindrical volume of 5 mm diameter and height) to high-dose-rate irradiations in the FLASH regime (using proton peak dose rates of up to 10^9 Gy/s with about 20 Gy/shot homogeneously over a cylindrical sample volume of 4.5 mm diameter and 3 mm height) as well as particle diagnostics commissioning (with a multitude of spatial and spectral dose distributions). The beamline setup is complemented by a complex beam monitoring and dosimetry detector suite adapted to the ultra-high dose rate pulses and is in its unique synergy and redundancy capable of %-level precision dose delivery to samples as required for systematic irradiation studies. In addition to established radiochromic film dosimetry, the detector suite includes saturation-corrected (transmission) ionisation chambers [3] as well as screen and bulk scintillator setups, partly with tomographic reconstruction capabilities for 3D dose distribution retrieval. Moreover, non-invasive, single-shot-capable online time-of-flight-based spectral characterisation of filtered proton pulses has proven a powerful tool for beam monitoring as well as dosimetric purposes. In this presentation the complex and versatile dose delivery

Published

2021

64. Laser ion acceleration for radio-biological application – Pushing proton energy frontiers with pre-expanded, actively controlled, near critical density targets

Author

Zeil, K., Rehwald, M., Bernert, C., Assenbaum, S., Brack, F., Bussmann, M., Cowan, T., Curry, C., Fiuza, F., Garten, M., Gaus, L., Gauthier, M., Göde, S., Goethel, I., Glenzer, S., Huang, L., Huebl, A., Kim, J., Kluge, T., Kraft, S., Kroll, F., Metzkes-Ng, J., Loeser, M., Obst-Huebl, L., Reimold, M., Schlenvoigt, H.-P., Schoenwaelder, C., Schramm, U., Siebold, M., Treffert, F., Yang, L., Ziegler, T., Pawelke, J., Beyreuther, E., Zeil, K., Rehwald, M., Bernert, C., Assenbaum, S., Brack, F., Bussmann, M., Cowan, T., Curry, C., Fiuza, F., Garten, M., Gaus, L., Gauthier, M., Göde, S., Goethel, I., Glenzer, S., Huang, L., Huebl, A., Kim, J., Kluge, T., Kraft, S., Kroll, F., Metzkes-Ng, J., Loeser, M., Obst-Huebl, L., Reimold, M., Schlenvoigt, H.-P., Schoenwaelder, C., Schramm, U., Siebold, M., Treffert, F., Yang, L., Ziegler, T., Pawelke, J., and Beyreuther, E.

Abstract

Demanding applications like radiation therapy of cancer are pushing the frontier of laser driven proton accelerators with controlled and well-defined proton beam properties. This talk will give an overview of recent achievements at the high-contrast high power laser source DRACO at HZDR providing high contrast pulses of >500 TW on target for the reliable generation of proton beams with energies of around 60 MeV. For efficient capturing and shaping of the divergent TNSA proton pulses, a setup of two pulsed highfield solenoid magnets has been developed and proven to reliably generate homogeneous depth dose distributions precisely adapted to the three-dimensional sample geometry for ultra-high pulse dose rate irradiation scenarios. Using this method, worldwide first dose controlled volumetric irradiation of in vivo samples with laseraccelerated protons were conducted. The performance of laser based ion acceleration and the scaling of the laser energy to achieve increased ion energies strongly depend on the laser temporal contrast and its effect on the target plasma scale length. Plasma mirror setups have proven to be a valuable tool to significantly improve the temporal contrast by reducing pre-pulse intensity and steepening the rising edge of the main laser pulse. With such contrast enhancement techniques including novel diagnostic schemes, laser proton acceleration using ultra-thin foil targets as well as renewable debris-free hydrogen jets were investigated in a series of experiments within the near-critical density regime. An important implication of this is the demonstration of a credible path toward high repetition rate laser-based ion acceleration applications.

Published

2021

65. Stable acceleration of intense proton beams to energies beyond 80 MeV at rep-rated laser systems

Author

(0000-0002-3727-7017) Ziegler, T., (0000-0003-1739-0159) Bernert, C., (0000-0002-1919-8585) Bock, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0003-0420-3940) Dover, N. P., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Göthel, I., Kiriyama, H., (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., (0000-0002-4738-6436) Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., (0000-0002-3727-7017) Ziegler, T., (0000-0003-1739-0159) Bernert, C., (0000-0002-1919-8585) Bock, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0003-0420-3940) Dover, N. P., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Göthel, I., Kiriyama, H., (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., (0000-0002-4738-6436) Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., and (0000-0003-3926-409X) Zeil, K.

Abstract

We report on experimental investigations of proton acceleration from laser-irradiated solid foils with the Draco-PW laser, where highest proton cut-off energies were achieved for temporal pulse parameters that varied significantlyfrom those of an ideally Fourier transform limited (FTL) pulse. Controlled spectral phase modulation of the driver laser by means of an acousto-optic programmable dispersive filter enabled us to manipulate the temporal shape ofthe last picoseconds around the main pulse and to study the effect on proton acceleration from thin foil targets. The results show that short and asymmetric pulses generated by positive third order dispersion values are favourable for proton acceleration and can lead to maximum energies above 60 MeV at 18 J laser energy for thin plastic foils, effectively doubling the maximum energy compared to ideally compressed FTL pulses. This performance optimization was the key to perform worlds first dose-controlled in-vivo studies with laser accelerated protons. The talk will further report on experiments we have carried out in the relativistically induced transparancy regime where the target turns transparent during the laser pulse interaction. We show recent data how the experimental signatures of the accelerated protons in this regime change compared to standard TNSA conditions and how we could reproduce those results at another similar laser laser system.

Published

2021

66. Laser-proton acceleration with cryogenic hydrogen jets

Author

Zeil, K., Rehwald, M., Bernert, C., Assenbaum, S., Brack, F., Bussmann, M., Cowan, T., Curry, C., Fiuza, F., Garten, M., Gaus, L., Gauthier, M., Göde, S., Goethel, I., Glenzer, S., Huebl, A., Kim, J., Kluge, T., Kraft, S., Kroll, F., Metzkes-Ng, J., Loeser, M., Obst-Huebl, L., Reimold, M., Schlenvoigt, H.-P., Schoenwaelder, C., Schramm, U., Siebold, M., Treffert, F., Ziegler, T., Zeil, K., Rehwald, M., Bernert, C., Assenbaum, S., Brack, F., Bussmann, M., Cowan, T., Curry, C., Fiuza, F., Garten, M., Gaus, L., Gauthier, M., Göde, S., Goethel, I., Glenzer, S., Huebl, A., Kim, J., Kluge, T., Kraft, S., Kroll, F., Metzkes-Ng, J., Loeser, M., Obst-Huebl, L., Reimold, M., Schlenvoigt, H.-P., Schoenwaelder, C., Schramm, U., Siebold, M., Treffert, F., and Ziegler, T.

Abstract

Demanding applications like radiation therapy of cancer have pushed the development of laser proton accelerators and defined necessary proton beam properties as well as levels of control and stability. The presentation will give an overview of the recent experiments for laser driven proton acceleration employing µm-sized cylindrical and sheet-like cryogenic jet targets to produce high energy proton beams without causing any debris. The low plasma density (30 nc) hydrogen jet was irradiated with the Petawatt laser source DRACO at the HZDR. Substantial improvements of the target system stability led to a proton acceleration performance comparable with that obtained with foil targets in optimized TNSA conditions. Furthermore, correlations between laser temporal profile and proton beam performance was investigated by using a synchronized off-harmonic optical probe beam for measuring the temporal evolution of the target expansion prior to the main pulse. Additional tailoring of the jet’s density profile by using artificial pre-pulses allowed for triggering the regime of relativistically induced transparency, yielding proton energies of up to about 80 MeV. Moreover, structured proton beam profiles were used to study the influence of the millimetres scale vacuum environment surrounding the target, where residual gas molecules are ionized by the remnant laser light that is not absorbed into the plasma but reflected or transmitted. This effect leads to the counter-intuitive observation of laser near-field feature imprints in the detected proton beam profiles.

Published

2021

67. Pushing proton energy frontiers with pre-expanded, actively controlled, near critical density targets

Author

Zeil, K., Rehwald, M., Bernert, C., Assenbaum, S., Brack, F., Bussmann, M., Cowan, T., Curry, C., Fiuza, F., Garten, M., Gaus, L., Gauthier, M., Göde, S., Goethel, I., Glenzer, S., Huang, L., Huebl, A., Kim, J., Kluge, T., Kraft, S., Kroll, F., Metzkes-Ng, J., Loeser, M., Obst-Huebl, L., Reimold, M., Schlenvoigt, H.-P., Schoenwaelder, C., Schramm, U., Siebold, M., Treffert, F., Yang, L., Ziegler, T., Zeil, K., Rehwald, M., Bernert, C., Assenbaum, S., Brack, F., Bussmann, M., Cowan, T., Curry, C., Fiuza, F., Garten, M., Gaus, L., Gauthier, M., Göde, S., Goethel, I., Glenzer, S., Huang, L., Huebl, A., Kim, J., Kluge, T., Kraft, S., Kroll, F., Metzkes-Ng, J., Loeser, M., Obst-Huebl, L., Reimold, M., Schlenvoigt, H.-P., Schoenwaelder, C., Schramm, U., Siebold, M., Treffert, F., Yang, L., and Ziegler, T.

Abstract

The performance of laser based ion acceleration and the scaling of the laser energy to achieve increased ion energies strongly depend on the laser temporal contrast and its effect on the target plasma scale length. Plasma mirror setups have proven to be a valuable tool to significantly improve the temporal contrast by reducing pre-pulse intensity and steepening the rising edge of the main laser pulse. With such contrast enhancement techniques including novel diagnostic schemes, laser proton acceleration using ultra-thin foil targets as well as renewable debris-free hydrogen jets were investigated in a series of experiments within the near-critical density regime. An important implication of this is the demonstration of a credible path toward high repetition rate laser-based ion acceleration applications.

Published

2021

68. Off-harmonic optical probing of high intensity laser interaction with solid-density cryogenic hydrogen jet targets

Author

(0000-0003-1739-0159) Bernert, C., (0000-0001-5602-3007) Albach, D., (0000-0002-6928-2048) Assenbaum, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-1919-8585) Bock, S., Curry, C. B., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Gauthier, M., Glenzer, S. H., Göde, S., Göthel, I., Kim, J. B., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-8145-5837) Kuntzsch, M., (0000-0001-7858-0007) Löser, M., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0002-4738-6436) Püschel, T., (0000-0003-4400-1315) Schlenvoigt, H.-P., Schoenwaelder, C., (0000-0002-4697-3014) Siebold, M., Treffert, F., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0003-3926-409X) Zeil, K., (0000-0002-3727-7017) Ziegler, T., (0000-0003-0390-7671) Schramm, U., (0000-0001-6200-6406) Rehwald, M., (0000-0003-1739-0159) Bernert, C., (0000-0001-5602-3007) Albach, D., (0000-0002-6928-2048) Assenbaum, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-1919-8585) Bock, S., Curry, C. B., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Gauthier, M., Glenzer, S. H., Göde, S., Göthel, I., Kim, J. B., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-8145-5837) Kuntzsch, M., (0000-0001-7858-0007) Löser, M., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0002-4738-6436) Püschel, T., (0000-0003-4400-1315) Schlenvoigt, H.-P., Schoenwaelder, C., (0000-0002-4697-3014) Siebold, M., Treffert, F., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-2828-5373) Vescovi Pinochet, M. A., (0000-0003-3926-409X) Zeil, K., (0000-0002-3727-7017) Ziegler, T., (0000-0003-0390-7671) Schramm, U., and (0000-0001-6200-6406) Rehwald, M.

Abstract

High-intensity short-pulse lasers enable novel compact accelerator schemes for the generation of energetic ion beams. The experimental investigation of the process remains challenging due to the femtosecond timescale and micrometer size of the acceleration. Commonly, diagnostic results are explained by a comparison of the experimental findings with computationally expensive particle-in-cell simulations. Cryogenic hydrogen jet targets (~30 critical densities) with µm-scale transverse size are particularly well suited for this approach. Time-resolved diagnostics like optical probing can infer the state of the target at the initialization time of the simulation and benchmark the simulation results. Here we present the implementation of an off-harmonic optical probing setup at an experiment for laser proton acceleration with a cylindrical hydrogen jet target at the DRACO PW laser with plasma-mirror cleaned laser contrast. We show under which conditions the technique overcomes the problem of parasitic plasma self-emission, present technical aspects of the off-harmonic probing technique together with experimental results of the observed plasma dynamics.

Published

2021

69. High intensity laser interaction with solid-density cryogenic hydrogen jet targets

Author

(0000-0003-1739-0159) Bernert, C., (0000-0002-6928-2048) Assenbaum, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., B. Curry, C., Fiuza, F., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Gauthier, M., Göde, S., Göthel, I., Glenzer, S. H., (0000-0003-1943-7141) Hübl, A., (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., (0000-0001-7858-0007) Löser, M., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., Schoenwaelder, C., (0000-0003-0390-7671) Schramm, U., (0000-0002-4697-3014) Siebold, M., Treffert, F., (0000-0002-3727-7017) Ziegler, T., (0000-0003-3926-409X) Zeil, K., (0000-0003-1739-0159) Bernert, C., (0000-0002-6928-2048) Assenbaum, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., B. Curry, C., Fiuza, F., (0000-0001-6994-2475) Garten, M., (0000-0002-6914-4083) Gaus, L., Gauthier, M., Göde, S., Göthel, I., Glenzer, S. H., (0000-0003-1943-7141) Hübl, A., (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., (0000-0001-7858-0007) Löser, M., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4962-2153) Reimold, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., Schoenwaelder, C., (0000-0003-0390-7671) Schramm, U., (0000-0002-4697-3014) Siebold, M., Treffert, F., (0000-0002-3727-7017) Ziegler, T., and (0000-0003-3926-409X) Zeil, K.

Abstract

Ultra-intense short-pulse lasers in the Petawatt regime and intensity range of 1021W/cm2 offer the possibility to study new compact accelerator schemes by utilizing solid density targets for the generation of energetic ion beams. The optimization of the acceleration process demands comprehensive exploration of the involved plasma dynamics. This applies not only on the femtosecond but also on the pico- to nanosecond timescale, where the laser rising edge modifies the target prior to the 30 fs laser peak. Cryogenic hydrogen jet targets with µm-scale transverse size and solid density (5.2x1022 cm-3) offer the superb opportunity for renewable and debris-free acceleration sources and at the same time allow for comprehensive experimental investigation and realistic simulation of the rich physics involved in the laser target interaction. Here, we present the results of an experiment for laser proton acceleration from a cryogenic hydrogen jet target at the DRACO-PW laser. Optimized acceleration performance is achieved by tailoring the targets plasma density via hydrodynamic expansion induced by a short low-intensity pre-pulse. Optical shadowgraphy probing is utilized to give a realistic input of the targets plasma density for 3 dimensional particle-in-cell simulations of the particle acceleration process.

Published

2021

70. 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

71. 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., (0000-0003-1184-2097) 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., (0000-0001-8090-2626) 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., (0000-0003-1184-2097) 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., (0000-0001-8090-2626) 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

72. Internal Access: Full source data of publication: 'Tumor irradiation in mice with a laser-accelerated proton beam'

Author

(0000-0002-0275-9892) Kroll, F., (0000-0002-9859-2408) Brack, F.-E., (0000-0003-1739-0159) Bernert, C., (0000-0002-1919-8585) Bock, S., Bodenstein, E., Brüchner, K., (0000-0002-5845-000X) Cowan, T., (0000-0002-6914-4083) Gaus, L., Gebhardt, R., Helbig, U., Karsch, L., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0003-1776-9556) Krause, M., Leßmann, E., (0000-0002-5248-0910) Masood, U., Meister, S., (0000-0002-9556-0662) Metzkes-Ng, J., Nossula, A., (0000-0003-4128-5498) Pawelke, J., (0000-0002-1610-1493) Pietzsch, J., (0000-0002-4738-6436) Püschel, T., (0000-0003-4962-2153) Reimold, M., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4261-4214) Richter, C., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-3727-7017) Ziegler, T., (0000-0003-3926-409X) Zeil, K., (0000-0002-0582-1444) Beyreuther, E., (0000-0002-0275-9892) Kroll, F., (0000-0002-9859-2408) Brack, F.-E., (0000-0003-1739-0159) Bernert, C., (0000-0002-1919-8585) Bock, S., Bodenstein, E., Brüchner, K., (0000-0002-5845-000X) Cowan, T., (0000-0002-6914-4083) Gaus, L., Gebhardt, R., Helbig, U., Karsch, L., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0003-1776-9556) Krause, M., Leßmann, E., (0000-0002-5248-0910) Masood, U., Meister, S., (0000-0002-9556-0662) Metzkes-Ng, J., Nossula, A., (0000-0003-4128-5498) Pawelke, J., (0000-0002-1610-1493) Pietzsch, J., (0000-0002-4738-6436) Püschel, T., (0000-0003-4962-2153) Reimold, M., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4261-4214) Richter, C., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., (0000-0001-7332-7395) Umlandt, M. E. P., (0000-0002-3727-7017) Ziegler, T., (0000-0003-3926-409X) Zeil, K., and (0000-0002-0582-1444) Beyreuther, E.

Abstract

All source data and scripts for publication: "Tumor irradiation in mice with a laser-accelerated proton beam"

Published

2021

73. Experimental control of laser proton acceleration beyond 50 MeV

Author

Ziegler, T., Bernert, C., Bock, S., Brack, F.-E., Cowan, T., Garten, M., Gaus, L., Gebhardt, R., Helbig, U., Irman, A., Kiriyama, H., Kluge, T., Kraft, S., Kroll, F., Metzkes-Ng, J., Nishiuchi, M., Obst-Hübl, L., Püschel, T., Rehwald, M., Schlenvoigt, H.-P., Schramm, U., and Zeil, K.

Subjects

Physics::Accelerator Physics

Abstract

We report on the ongoing plasma accelerator development at the HZDR, moving from plasma-acceleration studies towards real plasma-accelerators that can be controlled and applied in the lab. We show experimental investigations of proton acceleration from laser-irradiated solid foils with the DRACO PW laser, where highest proton cut-off energies were achieved for temporal pulse shape parameters well different from that of a Fourier transform limited (FTL) pulse. Controlled spectral phase modulation of the driver laser by means of an acousto-optic programmable dispersive filter enabled us to manipulate the temporal laser pulse shape and to study the effect on proton acceleration from thin foil targets. The results show that short and asymmetric pulses generated by positive third order dispersion values are favourable for proton acceleration and can lead to maximum energies of 60 MeV for thin plastic foils. Assuming appropriate control of the spectral phase of the laser and comparable temporal contrast conditions, we believe that the presented method can be universally applied to improve the proton acceleration performance using any other laser system operated in the PW regime.

Published

2020

74. Spectral and spatial shaping of laser-driven proton beams using a pulsed high-field magnet beamline

Author

(0000-0002-9859-2408) Brack, F.-E., (0000-0002-0275-9892) Kroll, F., Gaus, L., Bernert, C., (0000-0002-0582-1444) Beyreuther, E., (0000-0002-5845-000X) Cowan, T., Karsch, L., (0000-0002-0638-6990) Kraft, S., Kunz-Schughart, L. A., Leßmann, E., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0003-4128-5498) Pawelke, J., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., Sobiella, M., Rita Szabó, E., (0000-0002-3727-7017) Ziegler, T., (0000-0003-3926-409X) Zeil, K., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-0275-9892) Kroll, F., Gaus, L., Bernert, C., (0000-0002-0582-1444) Beyreuther, E., (0000-0002-5845-000X) Cowan, T., Karsch, L., (0000-0002-0638-6990) Kraft, S., Kunz-Schughart, L. A., Leßmann, E., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0003-4128-5498) Pawelke, J., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., Sobiella, M., Rita Szabó, E., (0000-0002-3727-7017) Ziegler, T., and (0000-0003-3926-409X) Zeil, K.

Abstract

ntense laser-driven proton pulses, inherently broadband and highly divergent, pose a challenge to established beamline concepts on the path to application-adapted irradiation field formation, particularly for 3D. Here we experimentally show the successful implementation of a highly efficient (50% transmission) and tuneable dual pulsed solenoid setup to generate a homogeneous (laterally and in depth) volumetric dose distribution (cylindrical volume of 5 mm diameter and depth) at a single pulse dose of 0.7 Gy via multi-energy slice selection from the broad input spectrum. The experiments were conducted at the Petawatt beam of the Dresden Laser Acceleration Source Draco and were aided by a predictive simulation model verified by proton transport studies. With the characterised beamline we investigated manipulation and matching of lateral and depth dose profiles to various desired applications and targets. Using an adapted dose profile, we performed a first proof-of-technical-concept laser-driven proton irradiation of volumetric in-vitro tumour tissue (SAS spheroids) to demonstrate concurrent operation of laser accelerator, beam shaping, dosimetry and irradiation procedure of volumetric biological samples.

Published

2020

75. Experimental control of laser proton acceleration beyond 50 MeV

Author

(0000-0002-3727-7017) Ziegler, T., Bernert, C., (0000-0002-1919-8585) Bock, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0001-6994-2475) Garten, M., Gaus, L., Gebhardt, R., Helbig, U., (0000-0002-4626-0049) Irman, A., (0000-0002-4862-6569) Kiriyama, H., (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., (0000-0001-9236-8037) Obst-Hübl, L., Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., (0000-0002-3727-7017) Ziegler, T., Bernert, C., (0000-0002-1919-8585) Bock, S., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-5845-000X) Cowan, T., (0000-0001-6994-2475) Garten, M., Gaus, L., Gebhardt, R., Helbig, U., (0000-0002-4626-0049) Irman, A., (0000-0002-4862-6569) Kiriyama, H., (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., (0000-0001-9236-8037) Obst-Hübl, L., Püschel, T., (0000-0001-6200-6406) Rehwald, M., (0000-0003-4400-1315) Schlenvoigt, H.-P., (0000-0003-0390-7671) Schramm, U., and (0000-0003-3926-409X) Zeil, K.

Abstract

We report on the ongoing plasma accelerator development at the HZDR, moving from plasma-acceleration studies towards real plasma-accelerators that can be controlled and applied in the lab. We show experimental investigations of proton acceleration from laser-irradiated solid foils with the DRACO PW laser, where highest proton cut-off energies were achieved for temporal pulse shape parameters well different from that of a Fourier transform limited (FTL) pulse. Controlled spectral phase modulation of the driver laser by means of an acousto-optic programmable dispersive filter enabled us to manipulate the temporal laser pulse shape and to study the effect on proton acceleration from thin foil targets. The results show that short and asymmetric pulses generated by positive third order dispersion values are favourable for proton acceleration and can lead to maximum energies of 60 MeV for thin plastic foils. Assuming appropriate control of the spectral phase of the laser and comparable temporal contrast conditions, we believe that the presented method can be universally applied to improve the proton acceleration performance using any other laser system operated in the PW regime.

Published

2020

76. Dose controlled irradiation experiments with laser-accelerated protons at Draco Petawatt

Author

Brack, F.-E., Kroll, F., Metzkes-Ng, J., Obst-Hübl, L., Bernert, C., Kraft, S., Schlenvoigt, H.-P., Gaus, L., Beyreuther, E., Karsch, L., Pawelke, J., Zeil, K., and Schramm, U.

Subjects

Physics::Instrumentation and Detectors, Quantitative Biology::Tissues and Organs, Physics::Medical Physics, Physics::Accelerator Physics

Abstract

We performed experiments with the Petawatt beam of the Dresden laser acceleration source Draco to investigate the feasibility of controlled volumetric tumour irradiations with laser-accelerated protons. Therefore, a beamline of two pulsed solenoid magnets was implemented to efficiently capture and shape the beam, which was then analysed by a comprehensive suite of detectors (ionization chamber, scintillator, radiochromic film, ..). We extensively studied how to manipulate and match lateral and depth dose profiles to the desired application and target. These were assisted by benchmark experiments at a conventional accelerator to further characterize the ion-optical properties of the solenoids and to investigate potential distortions of the transported proton beam. With the characterized beamline first proof-of-principle irradiation studies of volumetric normal and tumour tissue samples have been performed successfully. To advance to full scale irradiation experiments, a higher mean dose rate is necessary to deliver high absolute dose values via multiple bunches (dose control) in short times (~min). Current limitations are the low repetition rate of the beamline and its long cooldown times. Therefore, we developed a novel, actively cooled pulsed solenoid, to be implemented in the beamline, enabling complex irradiation studies with high repetition rates and consequently high mean dose rates.

Published

2019

77. I-BEAT: Ultrasonic method for online measurement of the energy distribution of a single ion bunch

Author

Haffa, D., Yang, R., Bin, J., Lehrack, S., Brack, F.-E., Ding, H., Englbrecht, F., Gao, Y., Gaus, L., Gebhard, J., Gilljohann, M., Götzfried, J., Hartmann, J., Herr, S., Hilz, P., Kraft, S., Kreuzer, C., Kroll, F., Lindner, F. H., Metzkes-Ng, J., Ostermayr, T. M., Ridente, E., Rösch, T. F., Schilling, G., Schlenvoigt, H.-P., Speicher, M., Taray, D., Würl, M., Zeil, K., Schramm, U., Karsch, S., Parodi, K., Bolton, P., Schreiber, J., and Assmann, W.

Subjects

Physics::Accelerator Physics, ion spectrometer, laser ion acceleration

Abstract

the shape of a wave carries all information about the spatial and temporal structure of its source, given that the medium and its properties are known. Most modern imaging methods seek to utilize this nature of waves originating from Huygens’ principle. We discuss the retrieval of the complete kinetic energy distribution from the acoustic trace that is recorded when a short ion bunch deposits its energy in water. this novel method, which we refer to as Ion-Bunch energy Acoustic tracing (I-BeAt), is a refinement of the ionoacoustic approach. With its capability of completely monitoring a single, focused proton bunch with prompt readout and high repetition rate, I-BeAt is a promising approach to meet future requirements of experiments and applications in the field of laser-based ion acceleration. We demonstrate its functionality at two laser-driven ion sources for quantitative online determination of the kinetic energy distribution in the focus of single proton bunches

Published

2019

78. Dose controlled irradiation experiments with laser-accelerated protons at Draco Petawatt

Author

(0000-0002-9859-2408) Brack, F.-E., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-9236-8037) Obst-Hübl, L., Bernert, C., (0000-0002-0638-6990) Kraft, S., (0000-0003-4400-1315) Schlenvoigt, H.-P., Gaus, L., (0000-0002-0582-1444) Beyreuther, E., Karsch, L., (0000-0003-4128-5498) Pawelke, J., (0000-0003-3926-409X) Zeil, K., (0000-0003-0390-7671) Schramm, U., (0000-0002-9859-2408) Brack, F.-E., (0000-0002-0275-9892) Kroll, F., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0001-9236-8037) Obst-Hübl, L., Bernert, C., (0000-0002-0638-6990) Kraft, S., (0000-0003-4400-1315) Schlenvoigt, H.-P., Gaus, L., (0000-0002-0582-1444) Beyreuther, E., Karsch, L., (0000-0003-4128-5498) Pawelke, J., (0000-0003-3926-409X) Zeil, K., and (0000-0003-0390-7671) Schramm, U.

Abstract

We performed experiments with the Petawatt beam of the Dresden laser acceleration source Draco to investigate the feasibility of controlled volumetric tumour irradiations with laser-accelerated protons. Therefore, a beamline of two pulsed solenoid magnets was implemented to efficiently capture and shape the beam, which was then analysed by a comprehensive suite of detectors (ionization chamber, scintillator, radiochromic film, ..). We extensively studied how to manipulate and match lateral and depth dose profiles to the desired application and target. These were assisted by benchmark experiments at a conventional accelerator to further characterize the ion-optical properties of the solenoids and to investigate potential distortions of the transported proton beam. With the characterized beamline first proof-of-principle irradiation studies of volumetric normal and tumour tissue samples have been performed successfully. To advance to full scale irradiation experiments, a higher mean dose rate is necessary to deliver high absolute dose values via multiple bunches (dose control) in short times (~min). Current limitations are the low repetition rate of the beamline and its long cooldown times. Therefore, we developed a novel, actively cooled pulsed solenoid, to be implemented in the beamline, enabling complex irradiation studies with high repetition rates and consequently high mean dose rates.

Published

2019

79. Laser-driven proton beam profiles in ultra-high fields

Author

(0000-0001-9236-8037) Obst-Hübl, L., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., Branco, J., (0000-0002-8258-3881) Bussmann, M., Cochran, G., (0000-0002-5845-000X) Cowan, T., Curry, C. B., (0000-0002-6914-4083) Gaus, L., Fiuza, F., (0000-0001-6994-2475) Garten, M., Gauthier, M., Glenzer, S. H., Göde, S., (0000-0003-1943-7141) Hübl, A., (0000-0002-4626-0049) Irman, A., Kim, J. B., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., Macdonald, M. J., (0000-0002-9556-0662) Metzkes-Ng, J., Mishra, R., (0000-0001-7990-9564) Pausch, R., Poole, P., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., Rödel, C., Ruyer, C., (0000-0003-4400-1315) Schlenvoigt, H.-P., Sommer, P., Schoenwalder, C., Schumaker, W., (0000-0002-3727-7017) Ziegler, T., (0000-0003-0390-7671) Schramm, U., Schumacher, D. W., (0000-0003-3926-409X) Zeil, K., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., Branco, J., (0000-0002-8258-3881) Bussmann, M., Cochran, G., (0000-0002-5845-000X) Cowan, T., Curry, C. B., (0000-0002-6914-4083) Gaus, L., Fiuza, F., (0000-0001-6994-2475) Garten, M., Gauthier, M., Glenzer, S. H., Göde, S., (0000-0003-1943-7141) Hübl, A., (0000-0002-4626-0049) Irman, A., Kim, J. B., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., Macdonald, M. J., (0000-0002-9556-0662) Metzkes-Ng, J., Mishra, R., (0000-0001-7990-9564) Pausch, R., Poole, P., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., Rödel, C., Ruyer, C., (0000-0003-4400-1315) Schlenvoigt, H.-P., Sommer, P., Schoenwalder, C., Schumaker, W., (0000-0002-3727-7017) Ziegler, T., (0000-0003-0390-7671) Schramm, U., Schumacher, D. W., and (0000-0003-3926-409X) Zeil, K.

Abstract

Extreme field gradients intrinsic to relativistic laser-interactions with thin solid targets enable compact multi-MeV proton accelerators with unique bunch characteristics. Protons are accelerated in TV/m fields that are established within the micrometer-scale vicinity of the high-power laser focus. This initial acceleration phase is followed by ballistic proton bunch propagation with negligible space-charge effects over millimeters to hundreds of centimeters to the particle detector or a proton target at a dedicated irradiation site. The detected proton emission distribution can be influenced by the spatio-temporal intensity distribution in the laser focus, electron transport through the target, potential plasma instabilities, as well as local and global target geometry and surface properties. Substantially extending this picture, our recent results show a critical influence of the milimeter scale vacuum environment on the accelerated proton bunch, where residual gas molecules are ionized by the remnant laser light that is not absorbed into the target plasma but reflected or transmitted. In an experiment with µm-sized hydrogen jet targets, this effect lead to the counter-intuitive observation of laser near-field feature imprints in the detected proton beam profiles. Our results show that the remnant laser pulse induces a quasi-static deflecting field map in the ionized residual background gas that serves as a memorizing medium and allows for asynchronous information transfer to the naturally delayed proton bunch. Occurring under typical experimental laser, target and vacuum conditions, all-optical imprinting needs to be taken into account for sensible interpretation of modulated proton beam profiles.

Published

2019

80. All-optical structuring of laser-driven proton beam profiles

Author

(0000-0002-9556-0662) Metzkes-Ng, J., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., Branco, J., (0000-0002-8258-3881) Bussmann, M., (0000-0002-5845-000X) Cowan, T., Curry, C. B., (0000-0002-6914-4083) Gaus, L., Fiuza, F., (0000-0001-6994-2475) Garten, M., Gauthier, M., Glenzer, S. H., Göde, S., (0000-0003-1943-7141) Hübl, A., (0000-0002-4626-0049) Irman, A., Kim, J. B., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., Macdonald, M. J., Mishra, R., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0001-7990-9564) Pausch, R., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., Rödel, C., Ruyer, C., (0000-0003-4400-1315) Schlenvoigt, H.-P., Sommer, P., Schoenwalder, C., Schumaker, W., (0000-0002-3727-7017) Ziegler, T., (0000-0003-0390-7671) Schramm, U., (0000-0003-3926-409X) Zeil, K., (0000-0002-9556-0662) Metzkes-Ng, J., (0000-0003-1739-0159) Bernert, C., (0000-0002-9859-2408) Brack, F.-E., Branco, J., (0000-0002-8258-3881) Bussmann, M., (0000-0002-5845-000X) Cowan, T., Curry, C. B., (0000-0002-6914-4083) Gaus, L., Fiuza, F., (0000-0001-6994-2475) Garten, M., Gauthier, M., Glenzer, S. H., Göde, S., (0000-0003-1943-7141) Hübl, A., (0000-0002-4626-0049) Irman, A., Kim, J. B., (0000-0003-4861-5584) Kluge, T., (0000-0002-0638-6990) Kraft, S., (0000-0002-0275-9892) Kroll, F., Macdonald, M. J., Mishra, R., (0000-0001-9236-8037) Obst-Hübl, L., (0000-0001-7990-9564) Pausch, R., (0000-0003-0931-1350) Prencipe, I., (0000-0001-6200-6406) Rehwald, M., Rödel, C., Ruyer, C., (0000-0003-4400-1315) Schlenvoigt, H.-P., Sommer, P., Schoenwalder, C., Schumaker, W., (0000-0002-3727-7017) Ziegler, T., (0000-0003-0390-7671) Schramm, U., and (0000-0003-3926-409X) Zeil, K.

Abstract

Extreme field gradients intrinsic to relativistic laser-interactions with thin solid targets enable compact multi-MeV proton accelerators. The initial µm-scale acceleration phase is followed by ballistic proton propagation with negligible space-charge effects over millimeters to hundreds of centimeters to a site of analysis/application. The detected proton distribution can be influenced by the spatio-temporal intensity distribution in the laser focus, electron transport, plasma instabilities, as well as target geometry and surface properties. Substantially extending this picture, our recent results show a critical influence of the mm-scale vacuum environment on the accelerated proton bunch, where residual gas molecules are ionized by the remnant laser light not absorbed into the target plasma but reflected or transmitted. In an experiment with µm-sized hydrogen jet targets, this effect lead to the counter-intuitive observation of laser near-field feature imprints in the detected proton beam profiles. Our results show that the remnant laser pulse induces a quasi-static deflecting field in the ionized residual background gas that serves as a memorizing medium and allows for asynchronous information transfer to the naturally delayed proton bunch. Occurring under typical experimental laser, target and vacuum conditions, all-optical imprinting needs to be taken into account for sensible interpretation of modulated proton beam profiles.

Published

2019

81. Pulsed High-Field Magnets for a laser-driven Ion Beam shaping and Laboratory Astrophysics

Author

Brack, F.-E., Kroll, F., Metzkes-Ng, J., Gaus, L., Kraft, S., Schlenvoigt, H.-P., Karsch, L., Pawelke, J., Zherlitsyn, S., Herrmansdörfer, T., Zeil, K., and Schramm, U.

Subjects

Physics::Medical Physics

Abstract

Pulsed high-field magnets have become a common, versatile research tool. We present a pulsed magnet technology platform that opens up new areas of application in the field of laser-driven plasma physics. Compact high-field magnets, generating ms-long magnetic field pulses with amplitudes ranging as high as 20 T, have been developed for operation under high vacuum and in close vicinity to the harsh laser-plasma environment. The combination of the presented magnet technology and portable pulsed power systems paves the way for novel experiments in laboratory astrophysics and enables unique studies on beam optics for laser-driven ion sources. We implemented a tunable pulsed beamline at the Dresden laser acceleration source (Draco) for radiobiological irradiation studies. It consists of two pulsed solenoids for shaping laser-accelerated ion beams spatially and spectrally for application. We performed experiments with the PW beam of Draco to investigate the feasibility of worldwide first controlled volumetric in vivo tumour irradiations in a dedicated mouse model with laser-accelerated protons. The study shows the reliable generation of homogeneous dose distributions laterally and in depth. Practical issues, like magnet repetition rate and stability, mean dose rate and future radiobiological challenges will be discussed and an outlook on the already performed volumetric tumour irradiation experiments will be given. Furthermore, a split-pair coil was developed that can be used for the investigation of magnetized plasma in the frame laboratory astrophysical phenomena. The magnet provides optical access to the magnetized laser-driven plasma via two bores perpendicular to the coil axis. These openings enable optical and X-ray probing as well as insertion of obstacles and/or laser targets from solids to gas jets.

Published

2018

82. Laser-Based Particle Accelerators at HZDR - Ions

Author

Brack, F.-E., Kroll, F., Metzkes, J., Obst, L., Kraft, S., Schlenvoigt, H.-P., Gaus, L., Ziegler, T., Rehwald, M., Zeil, K., and Schramm, U.

Abstract

Summary of the current status and carried out experiments of Laser-driven ion experiments at Draco

Published

2018

83. Medical Applications of Laser-driven Particle Sources - An Overview of Activities in Dresden

Author

Kroll, F., Zeil, K., Obst, L., Rehwald, M., Schlenvoigt, H.-P., Brack, F., Metzkes-Ng, J., Bernert, C., Gaus, L., Ziegler, T., Kluge, T., Garten, M., Hübl, A., Kraft, S., Schramm, U., Beyreuther, E., Karsch, L., Pawelke, J., and Kunz-Schughart, L.

Abstract

The talk summarizes activities of HZDR on the topic of laser-driven particle sources for medical applications. The focus lies on a the development and characterization of a pulsed high-field beamline that allows to transport and spacially as well as spectrally shape a laser-driven ion beam and thereby prepare it for irradiation studies, e.g. on radiobiological studies.

Published

2018

84. Laser-driven radiobiology experiments at Draco Petawatt

Author

Brack, F.-E., Kroll, F., Metzkes, J., Obst, L., Kraft, S., Schlenvoigt, H.-P., Gaus, L., Beyreuther, E., Karsch, L., Pawelke, J., Zeil, K., and Schramm, U.

Abstract

Summary of the current status and carried out experiments of Laser-driven radiobiology experiments at Draco Petawatt

Published

2018

85. Laser-driven ion acceleration at the Draco PW laser

Author

Obst, L., Bernert, C., Brack, F., Branco, J., Bussmann, M., Cowan, T. E., Garten, M., Gaus, L., Huebl, A., Kluge, T., Kraft, S. D., Kroll, F., Metzkes-Ng, J., Rehwald, M., Schlenvoigt, H., Schramm, U., Ziegler, T., and Zeil, K.

Subjects

Physics::Accelerator Physics

Abstract

Presentation of past and ongoing campaigns aimed at the efficient generation of high energy proton beams at the Draco PW laser facility of Helmholtz-Zentrum Dresden - Rossendorf (HZDR).

Published

2018

86. Pulsed High-Field Magnets for a laser-driven Ion Beam shaping and Laboratory Astrophysics

Author

(0000-0002-9859-2408) Brack, F.-E., Kroll, F., Metzkes-Ng, J., Gaus, L., Kraft, S., Schlenvoigt, H.-P., Karsch, L., Pawelke, J., Zherlitsyn, S., Herrmansdörfer, T., Zeil, K., Schramm, U., (0000-0002-9859-2408) Brack, F.-E., Kroll, F., Metzkes-Ng, J., Gaus, L., Kraft, S., Schlenvoigt, H.-P., Karsch, L., Pawelke, J., Zherlitsyn, S., Herrmansdörfer, T., Zeil, K., and Schramm, U.

Abstract

Pulsed high-field magnets have become a common, versatile research tool. We present a pulsed magnet technology platform that opens up new areas of application in the field of laser-driven plasma physics. Compact high-field magnets, generating ms-long magnetic field pulses with amplitudes ranging as high as 20 T, have been developed for operation under high vacuum and in close vicinity to the harsh laser-plasma environment. The combination of the presented magnet technology and portable pulsed power systems paves the way for novel experiments in laboratory astrophysics and enables unique studies on beam optics for laser-driven ion sources. We implemented a tunable pulsed beamline at the Dresden laser acceleration source (Draco) for radiobiological irradiation studies. It consists of two pulsed solenoids for shaping laser-accelerated ion beams spatially and spectrally for application. We performed experiments with the PW beam of Draco to investigate the feasibility of worldwide first controlled volumetric in vivo tumour irradiations in a dedicated mouse model with laser-accelerated protons. The study shows the reliable generation of homogeneous dose distributions laterally and in depth. Practical issues, like magnet repetition rate and stability, mean dose rate and future radiobiological challenges will be discussed and an outlook on the already performed volumetric tumour irradiation experiments will be given. Furthermore, a split-pair coil was developed that can be used for the investigation of magnetized plasma in the frame laboratory astrophysical phenomena. The magnet provides optical access to the magnetized laser-driven plasma via two bores perpendicular to the coil axis. These openings enable optical and X-ray probing as well as insertion of obstacles and/or laser targets from solids to gas jets.

Published

2018

87. Laser-driven ion acceleration at the Draco PW laser

Author

(0000-0001-9236-8037) Obst, L., Bernert, C., Brack, F., Branco, J., Bussmann, M., Cowan, T. E., Garten, M., Gaus, L., Huebl, A., Kluge, T., Kraft, S. D., Kroll, F., Metzkes-Ng, J., Rehwald, M., Schlenvoigt, H., Schramm, U., Ziegler, T., Zeil, K., (0000-0001-9236-8037) Obst, L., Bernert, C., Brack, F., Branco, J., Bussmann, M., Cowan, T. E., Garten, M., Gaus, L., Huebl, A., Kluge, T., Kraft, S. D., Kroll, F., Metzkes-Ng, J., Rehwald, M., Schlenvoigt, H., Schramm, U., Ziegler, T., and Zeil, K.

Abstract

Presentation of past and ongoing campaigns aimed at the efficient generation of high energy proton beams at the Draco PW laser facility of Helmholtz-Zentrum Dresden - Rossendorf (HZDR).

Published

2018

88. Preparation of small animal irradiation experiemnts with laser-accelerated protons

Author

Kroll, F., Beyreuther, E., Brack, F.-E., Gaus, L., Karsch, L., Kraft, S., Metzkes, J., Pawelke, J., Schlenvoigt, H.-P., Schürer, M., Zeil, K., and Schramm, U.

Subjects

Physics::Accelerator Physics

Abstract

Laser-driven ion acceleration has been considered a potential alternative for conventional accelerators that may provide for a more compact and cost-efficient particle therapy solution in the future. The beam properties of laser-accelerated beams strongly differ from quasi-continuous beams from synchrotrons or cyclotrons. Laser-driven ion bunches are typically picoseconds short, yet carry up to 10^13 particles with a broad energy spectrum and high divergence. A current driving question is whether the highly intense pulsed ion beams obtain an equivalent biological effectiveness compared to quasi-continuous beams in the case that a living organism is irradiated. Therefore, a controlled small animal irradiation (LN229 glioblastoma cells on nude mouse ear) will be performed at the Dresden laser acceleration source Draco using an intense proton beam. The talk gives a general overview on laser-acceleration efforts in the context of translational medical research at HZDR and focuses on the experimental preparation and characterization of a proton beamline based on two pulsed high-field (20 T) solenoid magnets. The magnets match the pulsed nature of the particle source and provide for efficient beam capture, transport and field formation. Two challenging experimental tasks will be critically discussed: First, 25 MeV proton beam production at mean dose rates of the order of Gy/min with a high degree of reproducibility. And second, the generation of homogeneous lateral and depth dose distributions by means of the beam transport system.

Published

2017

89. Laser ion acceleration using the Draco Petawatt facility at HZDR - experiments and radio-biological application

Author

Zeil, K., Obst, L., Rehwald, M., Schlenvoigt, H.-P., Brack, F., Kroll, F., Metzkes, J., Prencipe, I., Huebl, A., Kluge, T., Bussmann, M., Kraft, S., Ziegler, T., Bernert, C., Jahn, A., Gaus, L., Schramm, U., Zeil, K., Obst, L., Rehwald, M., Schlenvoigt, H.-P., Brack, F., Kroll, F., Metzkes, J., Prencipe, I., Huebl, A., Kluge, T., Bussmann, M., Kraft, S., Ziegler, T., Bernert, C., Jahn, A., Gaus, L., and Schramm, U.

Abstract

Demanding applications like radiation therapy of cancer are pushing the frontier of laser driven proton accelerators with controlled and well-defined proton beam properties. This talk will give an overview of recent achievements at the high-contrast high power laser source DRACO at HZDR. The laser system was recently upgraded by an additional Petawatt (PW) amplifier stage and new front end components finally providing high contrast pulses of >500 TW on target at 1 Hz pulse repetition rate. In first experiments with the new PW beam line of Draco the feasibility of worldwide first controlled volumetric irradiation of a specifically developed tumor model, grown on the ears of nude mice with laser-accelerated protons was investigated. In order to efficiently capture and shape the divergent TNSA proton beam, a setup of two pulsed high-field solenoid magnets was used. In the talk the reliable generation of homogeneous dose distributions lateral and in depth will be discussed. The performance of laser based ion acceleration and the scaling of the laser energy to achieve increased ion energies strongly depend on the laser temporal contrast and its effect on the target plasma scale length. Plasma mirror setups have proven to be a valuable tool to significantly improve the temporal contrast by reducing pre-pulse intensity and steepening the rising edge of the main laser pulse. With such contrast enhancement techniques laser proton acceleration using ultra-thin foil targets as well as a renewable debris-free hydrogen jet (in collaboration with SLAC and European XFEL) target was investigated with a laser pulse energy of 3 J and duration of 30 fs and show robust TNSA proton pulses with energies of up to 25 MeV. An important implication of this is the demonstration of a credible path toward high repetition rate laser-based ion acceleration applications.

Published

2017

90. Uncoupling of electrical and clinical expression of neonatal seizures after anti-epileptic drug administration

Author

Scher, M.S., primary, Alvin, J., additional, Gaus, L., additional, Minnigh, B., additional, and Painter, M.J., additional

Published

1994

91. Separation of Silver and Lead

Author

Benedict, R., primary and Gaus, L., additional

Published

1893

92. Imaging x-ray spectrometer at the high energy density instrument of the European x-ray free electron laser

Author

X. Pan, M. Šmíd, R. Štefaníková, F. Donat, C. Baehtz, T. Burian, V. Cerantola, L. Gaus, O. S. Humphries, V. Hajkova, L. Juha, M. Krupka, M. Kozlová, Z. Konopkova, T. R. Preston, L. Wollenweber, U. Zastrau, K. Falk, Pan, X, Smid, M, Stefanikova, R, Donat, F, Baehtz, C, Burian, T, Cerantola, V, Gaus, L, Humphries, O, Hajkova, V, Juha, L, Krupka, M, Kozlova, M, Konopkova, Z, Preston, T, Wollenweber, L, Zastrau, U, and Falk, K

Subjects

FEL, spectrometer, XES, IXS, XAS, Instrumentation

Abstract

A multipurpose imaging x-ray crystal spectrometer is developed for the high energy density instrument of the European X-ray Free Electron Laser. The spectrometer is designed to measure x rays in the energy range of 4–10 keV, providing high-resolution, spatially resolved spectral measurements. A toroidally bent germanium (Ge) crystal is used, allowing x-ray diffraction from the crystal to image along a one-dimensional spatial profile while spectrally resolving along the other. A detailed geometrical analysis is performed to determine the curvature of the crystal. The theoretical performance of the spectrometer in various configurations is calculated by ray-tracing simulations. The key properties of the spectrometer, including the spectral and spatial resolution, are demonstrated experimentally on different platforms. Experimental results prove that this Ge spectrometer is a powerful tool for spatially resolved measurements of x-ray emission, scattering, or absorption spectra in high energy density physics.

Published

2023

93. Ultra-short pulse laser acceleration of protons to 80 MeV from cryogenic hydrogen jets tailored to near-critical density.

Author

Rehwald M, Assenbaum S, Bernert C, Brack FE, Bussmann M, Cowan TE, Curry CB, Fiuza F, Garten M, Gaus L, Gauthier M, Göde S, Göthel I, Glenzer SH, Huang L, Huebl A, Kim JB, Kluge T, Kraft S, Kroll F, Metzkes-Ng J, Miethlinger T, Loeser M, Obst-Huebl L, Reimold M, Schlenvoigt HP, Schoenwaelder C, Schramm U, Siebold M, Treffert F, Yang L, Ziegler T, and Zeil K

Subjects

Lasers, Particle Accelerators, Acceleration, Protons, Hydrogen

Abstract

Laser plasma-based particle accelerators attract great interest in fields where conventional accelerators reach limits based on size, cost or beam parameters. Despite the fact that particle in cell simulations have predicted several advantageous ion acceleration schemes, laser accelerators have not yet reached their full potential in producing simultaneous high-radiation doses at high particle energies. The most stringent limitation is the lack of a suitable high-repetition rate target that also provides a high degree of control of the plasma conditions required to access these advanced regimes. Here, we demonstrate that the interaction of petawatt-class laser pulses with a pre-formed micrometer-sized cryogenic hydrogen jet plasma overcomes these limitations enabling tailored density scans from the solid to the underdense regime. Our proof-of-concept experiment demonstrates that the near-critical plasma density profile produces proton energies of up to 80 MeV. Based on hydrodynamic and three-dimensional particle in cell simulations, transition between different acceleration schemes are shown, suggesting enhanced proton acceleration at the relativistic transparency front for the optimal case., (© 2023. The Author(s).)

Published

2023

94. Enhanced ion acceleration from transparency-driven foils demonstrated at two ultraintense laser facilities.

Author

Dover NP, Ziegler T, Assenbaum S, Bernert C, Bock S, Brack FE, Cowan TE, Ditter EJ, Garten M, Gaus L, Goethel I, Hicks GS, Kiriyama H, Kluge T, Koga JK, Kon A, Kondo K, Kraft S, Kroll F, Lowe HF, Metzkes-Ng J, Miyatake T, Najmudin Z, Püschel T, Rehwald M, Reimold M, Sakaki H, Schlenvoigt HP, Shiokawa K, Umlandt MEP, Schramm U, Zeil K, and Nishiuchi M

Abstract

Laser-driven ion sources are a rapidly developing technology producing high energy, high peak current beams. Their suitability for applications, such as compact medical accelerators, motivates development of robust acceleration schemes using widely available repetitive ultraintense femtosecond lasers. These applications not only require high beam energy, but also place demanding requirements on the source stability and controllability. This can be seriously affected by the laser temporal contrast, precluding the replication of ion acceleration performance on independent laser systems with otherwise similar parameters. Here, we present the experimental generation of >60 MeV protons and >30 MeV u -1 carbon ions from sub-micrometre thickness Formvar foils irradiated with laser intensities >10 21 Wcm 2 . Ions are accelerated by an extreme localised space charge field ≳30 TVm -1 , over a million times higher than used in conventional accelerators. The field is formed by a rapid expulsion of electrons from the target bulk due to relativistically induced transparency, in which relativistic corrections to the refractive index enables laser transmission through normally opaque plasma. We replicate the mechanism on two different laser facilities and show that the optimum target thickness decreases with improved laser contrast due to reduced pre-expansion. Our demonstration that energetic ions can be accelerated by this mechanism at different contrast levels relaxes laser requirements and indicates interaction parameters for realising application-specific beam delivery., (© 2023. The Author(s).)

Published

2023

95. Off-harmonic optical probing of high intensity laser plasma expansion dynamics in solid density hydrogen jets.

Author

Bernert C, Assenbaum S, Brack FE, Cowan TE, Curry CB, Garten M, Gaus L, Gauthier M, Göde S, Goethel I, Glenzer SH, Kluge T, Kraft S, Kroll F, Kuntzsch M, Metzkes-Ng J, Loeser M, Obst-Huebl L, Rehwald M, Schlenvoigt HP, Schoenwaelder C, Schramm U, Siebold M, Treffert F, Ziegler T, and Zeil K

Abstract

Due to the non-linear nature of relativistic laser induced plasma processes, the development of laser-plasma accelerators requires precise numerical modeling. Especially high intensity laser-solid interactions are sensitive to the temporal laser rising edge and the predictive capability of simulations suffers from incomplete information on the plasma state at the onset of the relativistic interaction. Experimental diagnostics utilizing ultra-fast optical backlighters can help to ease this challenge by providing temporally resolved inside into the plasma density evolution. We present the successful implementation of an off-harmonic optical probe laser setup to investigate the interaction of a high-intensity laser at [Formula: see text] peak intensity with a solid-density cylindrical cryogenic hydrogen jet target of [Formula: see text] diameter as a target test bed. The temporal synchronization of pump and probe laser, spectral filtering and spectrally resolved data of the parasitic plasma self-emission are discussed. The probing technique mitigates detector saturation by self-emission and allowed to record a temporal scan of shadowgraphy data revealing details of the target ionization and expansion dynamics that were so far not accessible for the given laser intensity. Plasma expansion speeds of up to [Formula: see text] followed by full target transparency at [Formula: see text] after the high intensity laser peak are observed. A three dimensional particle-in-cell simulation initiated with the diagnosed target pre-expansion at [Formula: see text] and post processed by ray tracing simulations supports the experimental observations and demonstrates the capability of time resolved optical diagnostics to provide quantitative input and feedback to the numerical treatment within the time frame of the relativistic laser-plasma interaction., (© 2022. The Author(s).)

Published

2022

96. Publisher Correction: Spectral and spatial shaping of laser-driven proton beams using a pulsed high-field magnet beamline.

Author

Brack FE, Kroll F, Gaus L, Bernert C, Beyreuther E, Cowan TE, Karsch L, Kraft S, Kunz-Schughart LA, Lessmann E, Metzkes-Ng J, Obst-Huebl L, Pawelke J, Rehwald M, Schlenvoigt HP, Schramm U, Sobiella M, Szabó ER, Ziegler T, and Zeil K

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

97. Spectral and spatial shaping of laser-driven proton beams using a pulsed high-field magnet beamline.

Author

Brack FE, Kroll F, Gaus L, Bernert C, Beyreuther E, Cowan TE, Karsch L, Kraft S, Kunz-Schughart LA, Lessmann E, Metzkes-Ng J, Obst-Huebl L, Pawelke J, Rehwald M, Schlenvoigt HP, Schramm U, Sobiella M, Szabó ER, Ziegler T, and Zeil K

Abstract

Intense laser-driven proton pulses, inherently broadband and highly divergent, pose a challenge to established beamline concepts on the path to application-adapted irradiation field formation, particularly for 3D. Here we experimentally show the successful implementation of a highly efficient (50% transmission) and tuneable dual pulsed solenoid setup to generate a homogeneous (laterally and in depth) volumetric dose distribution (cylindrical volume of 5 mm diameter and depth) at a single pulse dose of 0.7 Gy via multi-energy slice selection from the broad input spectrum. The experiments were conducted at the Petawatt beam of the Dresden Laser Acceleration Source Draco and were aided by a predictive simulation model verified by proton transport studies. With the characterised beamline we investigated manipulation and matching of lateral and depth dose profiles to various desired applications and targets. Using an adapted dose profile, we performed a first proof-of-technical-concept laser-driven proton irradiation of volumetric in-vitro tumour tissue (SAS spheroids) to demonstrate concurrent operation of laser accelerator, beam shaping, dosimetry and irradiation procedure of volumetric biological samples.

Published

2020

98. Intercellular transport of Oct4 in mammalian cells: a basic principle to expand a stem cell niche?

Author

Rolf HJ, Niebert S, Niebert M, Gaus L, Schliephake H, and Wiese KG

Subjects

Animals, Antlers cytology, Biological Transport, Coculture Techniques, Deer, Embryonic Stem Cells cytology, Embryonic Stem Cells physiology, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells physiology, Mice, Models, Animal, Octamer Transcription Factor-3 physiology, Pluripotent Stem Cells cytology, Pluripotent Stem Cells physiology, Cell Communication physiology, Octamer Transcription Factor-3 metabolism, Regeneration, Stem Cell Niche, Stem Cells cytology

Abstract

Background: The octamer-binding transcription factor 4 (Oct4) was originally described as a marker of embryonic stem cells. Recently, the role of Oct4 as a key regulator in pluripotency was shown by its ability to reprogram somatic cells in vitro, either alone or in concert with other factors. While artificial induction of pluripotency using transcription factors is possible in mammalian cell culture, it remains unknown whether a potential natural transfer mechanism might be of functional relevance in vivo. The stem cell based regeneration of deer antlers is a unique model for rapid and complete tissue regeneration in mammals and therefore most suitable to study such mechanisms. Here, the transfer of pluripotency factors from resident stem cell niche cells to differentiated cells could recruit more stem cells and start rapid tissue regeneration., Methodology/principal Findings: We report on the ability of STRO-1(+) deer antlerogenic mesenchymal stem cells (DaMSCs) to transport Oct4 via direct cell-to-cell connections. Upon cultivation in stem cell expansion medium, we observed nuclear Oct4 expression in nearly all cells. A number of these cells exhibit Oct4 expression not only in the nucleus, but also with perinuclear localisation and within far-ranging intercellular connections. Furthermore, many cells showed intercellular connections containing both F-actin and α-tubulin and through which transport could be observed. To proof that intercellular Oct4-transfer has functional consequences in recipient cells we used a co-culture approach with STRO-1(+) DaMSCs and a murine embryonic fibroblast indicator cell line (Oct4-GFP MEF). In this cell line a reporter gene (GFP) under the control of an Oct4 responsive element is only expressed in the presence of Oct4. GFP expression in Oct4-GFP cells started after 24 hours of co-culture providing evidence of Oct4 transfer from STRO-1(+) DaMSCs to Oct4-GFP MEF target cells., Conclusions: Our findings indicate a possible mechanism for the expansion of a resident stem cell niche by induction of pluripotency in surrounding non-niche cells via transfer of transcription factors through intercellular connections. This provides a new approach to explain the rapid annual antler regrowth.

Published

2012

99. Uncoupling of EEG-clinical neonatal seizures after antiepileptic drug use.

Author

Scher MS, Alvin J, Gaus L, Minnigh B, and Painter MJ

Subjects

Anticonvulsants adverse effects, Evoked Potentials drug effects, Female, Gestational Age, Humans, Infant, Newborn, Infant, Premature, Diseases diagnosis, Male, Phenobarbital adverse effects, Phenytoin adverse effects, Spasms, Infantile diagnosis, Treatment Outcome, Anticonvulsants administration & dosage, Electroencephalography drug effects, Infant, Premature, Diseases drug therapy, Phenobarbital administration & dosage, Phenytoin administration & dosage, Spasms, Infantile drug therapy

Abstract

A prospective study of the efficacy of seizure cessation by phenobarbital versus phenytoin administration utilized both clinical and electroencephalographic expressions of seizure behaviors. The phenomenon of uncoupling was defined as the persistence of electrographic seizures despite the suppression of >or=50% clinical seizures after either one or both antiepileptic drugs use. Fifty-nine neonates (25 to 43 weeks estimated gestational age) with electrically-confirmed seizures were assigned to either of two drugs and continuously monitored over a 24-hour period. Nine of the fifty-nine patients had only electrographic seizure expression both before and after drug administration. Of the remaining 50 patients who had both electrical and clinical seizure expression before treatment, 24 infants responded to the first choice of an antiepileptic drug with no further seizures. Fifteen of the remaining 26 infants (58%) with persistent seizures after treatment had uncoupling of electrical and clinical expressions of seizures; no difference in the uncoupling effect was noted for neonates who were treated with either antiepileptic drug or based on prematurity or gender. Serial electroencephalographic monitoring helps document continued electrographic seizure expression after antiepileptic drug use, following complete or partial suppression of clinical seizure behaviors.

Published

2003

100. Neonatal phenobarbital and phenytoin binding profiles.

Author

Painter MJ, Minnigh MB, Gaus L, Scher M, Brozanski B, and Alvin J

Subjects

Birth Weight, Female, Gestational Age, Humans, Infant, Newborn, Male, Phenobarbital administration & dosage, Phenytoin administration & dosage, Protein Binding, Seizures blood, Seizures drug therapy, Phenobarbital blood, Phenytoin blood

Abstract

Phenobarbital and phenytoin binding profiles were determined in 27 neonates. Binding of both drugs decreased compared with that in older subjects. In vitro binding of both agents correlated significantly with total protein and albumin concentrations. In vivo binding at 0.5 hours correlated significantly with birthweight and gestational age. Phenobarbital, but not phenytoin, binding decreased when three other therapeutic agents were concomitantly administered. Bilirubin concentrations, free fatty-acid concentrations, and pH values encountered in this population did not significantly influence binding. An in vitro binding profile accurately predicted in vivo free fractions (percent drug unbound) and plasma concentrations of both drugs.

Published

1994