Your search keyword '"F.-E. Brack"' showing total 17 results

1. miniSCIDOM: a scintillator-based tomograph for volumetric dose reconstruction of single laser-driven proton bunches

Author

A. Corvino, M. Reimold, E. Beyreuther, F.-E. Brack, F. Kroll, J. Pawelke, J. D. Schilz, M. Schneider, U. Schramm, M. E. P. Umlandt, K. Zeil, T. Ziegler, and J. Metzkes-Ng

Subjects

beam monitoring detectors, laser-driven proton beams, scintillator-based diagnostics, ultra-high dose rate, Applied optics. Photonics, TA1501-1820

Abstract

Laser plasma accelerators (LPAs) enable the generation of intense and short proton bunches on a micrometre scale, thus offering new experimental capabilities to research fields such as ultra-high dose rate radiobiology or material analysis. Being spectrally broadband, laser-accelerated proton bunches allow for tailored volumetric dose deposition in a sample via single bunches to excite or probe specific sample properties. The rising number of such experiments indicates a need for diagnostics providing spatially resolved characterization of dose distributions with volumes of approximately 1 cm ${}^3$ for single proton bunches to allow for fast online feedback. Here we present the scintillator-based miniSCIDOM detector for online single-bunch tomographic reconstruction of dose distributions in volumes of up to approximately 1 cm ${}^3$ . The detector achieves a spatial resolution below 500 $\unicode{x3bc}$ m and a sensitivity of 100 mGy. The detector performance is tested at a proton therapy cyclotron and an LPA proton source. The experiments’ primary focus is the characterization of the scintillator’s ionization quenching behaviour.

Published

2024

2. OCTOPOD: single-bunch tomography for angular-spectral characterization of laser-driven protons

Author

M. Reimold, S. Assenbaum, E. Beyreuther, E. Bodenstein, F.-E. Brack, C. Eisenmann, F. Englbrecht, F. Kroll, F. Lindner, U. Masood, J. Pawelke, U. Schramm, M. Schneider, M. Sobiella, M. E. P. Umlandt, M. Vescovi, K. Zeil, T. Ziegler, and J. Metzkes-Ng

Subjects

laser–plasma acceleration of protons, proton detector, tomographic reconstruction, Applied optics. Photonics, TA1501-1820

Abstract

Laser–plasma accelerated (LPA) proton bunches are now applied for research fields ranging from ultra-high-dose-rate radiobiology to material science. Yet, the capabilities to characterize the spectrally and angularly broad LPA bunches lag behind the rapidly evolving applications. The OCTOPOD translates the angularly resolved spectral characterization of LPA proton bunches into the spatially resolved detection of the volumetric dose distribution deposited in a liquid scintillator. Up to 24 multi-pinhole arrays record projections of the scintillation light distribution and allow for tomographic reconstruction of the volumetric dose deposition pattern, from which proton spectra may be retrieved. Applying the OCTOPOD at a cyclotron, we show the reliable retrieval of various spatial dose deposition patterns and detector sensitivity over a broad dose range. Moreover, the OCTOPOD was installed at an LPA proton source, providing real-time data on proton acceleration performance and attesting the system optimal performance in the harsh laser–plasma environment.

Published

2023

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

Author

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

Subjects

Medicine, Science

Abstract

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

4. Analyzing the filamentation of MeV-range proton bunches in a laser-driven ion beamline and optimizing their peak intensity

Author

M. Metternich, H. Nazary, D. Schumacher, C. Brabetz, F. Kroll, F.-E. Brack, M. Ehret, A. Blažević, U. Schramm, V. Bagnoud, and M. Roth

Subjects

Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

In this article, we report on the latest investigations and achievements in proton beam shaping with our laser-driven ion beamline at GSI Helmholtzzentrum für Schwerionenforschung GmbH. This beamline was realized within the framework of the Laser Ion Generation, Handling, and Transport (LIGHT) collaboration to study the combination of laser-driven ion beams with conventional accelerator components. At its current state, the ions are accelerated by the high-power laser PHELIX via target normal sheath acceleration, and two pulsed high-magnetic solenoids are used for energy selection, transport, and transverse focusing. In between the two solenoids, there is a rf cavity that gives the LIGHT beamline the capability to longitudinally manipulate and temporally compress ion bunches to sub-nanosecond durations. To get optimal results, the rf cavity has to be synchronized with the PHELIX laser and therefore a reliable measurement of the temporal ion beam profile is necessary. In the past, these measurements showed unexpected correlations between the temporal beam profile and the phase as well as the electric field strength of the cavity. In this article, we present a numerical simulation of the beam transport through the LIGHT beamline which explains this behavior by a beam filamentation. We also report on our latest experimental campaigns, in which we combined transverse and longitudinal focusing for the first time. This led to proton bunches with a peak intensity of (3.28±0.24)×10^{8} protons/(ns mm^{2}) at a central energy of (7.72±0.14) MeV. The intensity refers to a circle with a diameter of (1.38±0.02) mm that encloses 50% of the protons in the focal spot at the end of the beamline. The temporal bunch width at this position was (742±40) ps (FWHM).

Published

2022

5. Three-dimensional acoustic monitoring of laser-accelerated protons in the focus of a pulsed-power solenoid lens

Author

S. Gerlach, F. Balling, A. K. Schmidt, F. E. Brack, F. Kroll, J. Metzkes-Ng, M. Reimold, U. Schramm, M. Speicher, K. Zeil, K. Parodi, and J. Schreiber

Subjects

Nuclear and High Energy Physics, ion diagnostics, detector, Nuclear Energy and Engineering, DRACO, TNSA, ALBUS, ionoaccoustics, high-field magnets, beamline, Atomic and Molecular Physics, and Optics, laser ion acceleration, Electronic, Optical and Magnetic Materials

Abstract

The acoustic pulse emitted from the Bragg peak of a laser-accelerated proton bunch focused into water has recently enabled the reconstruction of the bunch energy distribution. By adding three ultrasonic transducers and implementing a fast data analysis of the filtered raw signals, I-BEAT (Ion-Bunch Energy Acoustic Tracing) 3D now provides the mean bunch energy and absolute lateral bunch position in real-time and for individual bunches. Relative changes in energy spread and lateral bunch size can also be monitored. Our experiments at DRACO with proton bunch energies between 10 and 30 MeV reveal sub-MeV and sub-mm resolution. In addition to this 3D bunch information, the signal strength correlates also with the absolute bunch particle number.

Published

2023

6. Focusing of multi-MeV, subnanosecond proton bunches from a laser-driven source

Author

D. Jahn, D. Schumacher, C. Brabetz, F. Kroll, F. E. Brack, J. Ding, R. Leonhardt, I. Semmler, A. Blažević, U. Schramm, and M. Roth

Subjects

Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

We report on our latest transverse focusing results of subnanosecond proton bunches achieved with a laser-driven multi-MeV ion beamline. In the frame of the LIGHT collaboration, a target normal sheath acceleration (TNSA) source based 6 m long beamline was installed. In the past years, the laser-driven proton beam was transported and shaped by this beamline. The particle beam is collimated with a pulsed high-field solenoid and rotated in longitudinal phase space with a radio-frequency cavity which leads to an energy compression with an energy spread of (2.7±1.7)% (ΔE/E_{0} at FWHM) or a time compression to the subnanosecond regime. Highest peak intensities in the subnanosecond regime open up an interesting field for several applications, e.g., proton imaging, as injectors in conventional accelerators or precise stopping power measurements in a plasma. We report on achieving highest peak intensities using an installed second solenoid as a final focusing system in our beamline to achieve small focal spot sizes. We measured a focal spot size of 1.1×1.2 mm leading to 5.8×10^{19} protons per s cm^{2} at a central energy bin of (9.55±0.25) MeV, which can be combined with a bunch duration below 500 ps at FWHM.

Published

2019

7. Laser-generated supersonic plasma jets and shocks in a transverse magnetic field

Author

H Bohlin, F-E Brack, M Cervenak, T Chodukowski, J Cikhardt, J Dostál, R Dudžák, J Hubner, W Huo, S Jelinek, D Klír, F Kroll, M Krupka, M Krůs, T Pisarczyk, Z Rusiniak, U Schramm, T-H Nguyen-Bui, S Weber, A Zaraś-Szydłowska, K Zeil, D Kumar, T Schlegel, and V Tikhonchuk

Subjects

Plasma, Nuclear Energy and Engineering, Pulsed Magnet, Laser, Condensed Matter Physics, Astrophysics

Abstract

The influence of a transverse magnetic field on the formation and evolution of supersonic plasma jets and shocks was studied experimentally, and compared with 3D numerical simulations. An improved jet collimation was seen due to the change in the magnetic field topology restricting the radial expansion of the ablated plasma. The magnetic field was also shown to strongly affect the shock structures, both indirectly through the modified jet geometry, as well as due to a compression of the field lines in the shock region. The interaction characteristics were found to depend on the relative contribution of the magnetic and plasma pressure in balancing the ram pressure of the jet.

Published

2022

8. FLASH Modalities Track (Oral Presentations) LASER-DRIVEN PROTON ACCELERATION AT DRACO PW: A NOVEL PLATFORM FOR ULTRA-HIGH DOSE RATE RADIOBIOLOGY

Author

F.-E. Brack, F. Kroll, J. Jansen, L. Karsch, S. Kraft, E. Lessmann, J. Metzkes-Ng, J. Pawelke, M. Reimold, H.-P. Schlenvoigt, R. Szabó, M.E.P. Umlandt, T. Ziegler, U. Schramm, and K. Zeil

Subjects

Biophysics, General Physics and Astronomy, Radiology, Nuclear Medicine and imaging, General Medicine

Published

2022

9. Proton beam quality enhancement by spectral phase control of a PW‑class laser system

Author

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

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

10. PARTICLE DOSIMETRY FOR PULSED ULTRA-HIGH PEAK DOSE RATES: THE I-BEAT DETECTOR

Author

S. Gerlach, F. Balling, S. Anna-Katharina, F.-E. Brack, L. Kirsch, F. Kroll, U. Schramm, K. Zeil, W. Assmann, K. Parodi, and J. Schreiber

Subjects

Biophysics, General Physics and Astronomy, Radiology, Nuclear Medicine and imaging, General Medicine

Published

2022

11. FLASH Modalities Track (Oral Presentations) ULTRA-HIGH DOSE RATE PROTON RADIOBIOLOGY AT THE 'DRESDEN PLATFORM FOR HIGH DOSE-RATE RADIOBIOLOGY'

Author

E. Beyreuther, F.-E. Brack, K. Brüchner, S. Hans, J. Jansen, L. Karsch, F. Kroll, E. Lessmann, S. Löck, J. Metzkes-Ng, J. Pawelke, M. Reimold, U. Schramm, R. Szabó, and K. Zeil

Subjects

Biophysics, General Physics and Astronomy, Radiology, Nuclear Medicine and imaging, General Medicine

Published

2022

12. FLASH Mechanisms Track (Oral Presentations) OXYGEN DEPLETION IN ULTRA-HIGH DOSE RATES FOR PROTONS AND ELECTRONS: EXPERIMENTAL APPROACH IN WATER AND BIOLOGICAL SAMPLES

Author

J. Jansen, E. Beyreuther, J. Pawelke, L. Karsch, M. Schürer, F. Kroll, F.-E. Brack, M. Reimold, J. Metzkes-Ng, U. Schramm, and J. Seco

Subjects

Biophysics, General Physics and Astronomy, Radiology, Nuclear Medicine and imaging, General Medicine

Published

2022

13. Deflection of laser accelerated protons from cryogenic hydrogen jets due to self-generated magnetic fields

Author

T. Cowen, Shaun Kerr, Ulrich Schramm, Clement Goyon, J. B. Kim, Gerald Williams, Arthur Pak, Siegfried Glenzer, F-E Brack, Martin Rehwald, Hans-Peter Schlenvoigt, Maxence Gauthier, Bastian Aurand, J. Metzkes, Chandra Curry, B. Ramakrishna, R. Mishra, C. Roedel, Ying Tsui, U. Helbig, P. Sommer, Oswald Willi, J. J. Ruby, Lieselotte Obst, René Gebhardt, Frederico Fiuza, Adrienne Propp, C. Ruyer, Karl Zeil, and S. Goede

Subjects

Physics, Cryogenics, Laser, Magnetic field, Ion, law.invention, Nuclear physics, Ignition system, Deflection (physics), Physics::Plasma Physics, law, Physics::Accelerator Physics, Thermal emittance, Inertial confinement fusion

Abstract

Laser-driven ion acceleration is of great interest across a range of disciplines with potential applications including the fast ignition approach to inertial confinement fusion and proton therapy. The most robust acceleration mechanisms studied to date however, based on target normal sheath acceleration (TNSA), do not satisfy the emittance, flux and ion energy requirements for direct applications.

Published

2016

14. Ring-like spatial distribution of laser accelerated protons in the ultra-high-contrast TNSA-regime

Author

L. Bock, S. Kuschel, A. Seidel, Jörg Schreiber, J. Reisloehner, Karl Zeil, Malte C. Kaluza, Marco Hellwing, S. Tietze, Jianhui Bin, Sergey Rykovanov, Marco Hornung, P. Hilz, Joachim Hein, J. Polz, Matthew Zepf, M. B. Schwab, Georg A. Becker, F-E Brack, Hartmut Liebetrau, Alexander Kessler, Stephan Kraft, Wenjun Ma, Frank Schorcht, Sebastian Keppler, Ulrich Schramm, and H-P Schlenvoigt

Subjects

Materials science, Condensed Matter Physics, Ring (chemistry), Laser, Spatial distribution, 01 natural sciences, 010305 fluids & plasmas, law.invention, Acceleration, Nuclear Energy and Engineering, law, Electric field, 0103 physical sciences, Physics::Accelerator Physics, Atomic physics, 010306 general physics, Normal, Beam (structure), FOIL method

Abstract

The spatial distribution of protons accelerated from submicron-thick plastic foil targets using multi-terawatt, frequency-doubled laser pulses with ultra-high temporal contrast has been investigated experimentally. A very stable, ring-like beam profile of the accelerated protons, oriented around the target's normal direction has been observed. The ring's opening angle has been found to decrease with increasing foil thicknesses. Two-dimensional particle-in-cell simulations reproduce our results indicating that the ring is formed during the expansion of the proton density distribution into the vacuum as described by the mechanism of target-normal sheath acceleration. Here-in addition to the longitudinal electric fields responsible for the forward acceleration of the protons-a lateral charge separation leads to transverse field components accelerating the protons in the lateral direction.

Published

2018

15. Ring-like spatial distribution of laser accelerated protons in the ultra-high-contrast TNSA-regime.

Author

G A Becker, S Tietze, S Keppler, J Reislöhner, J H Bin, L Bock, F-E Brack, J Hein, M Hellwing, P Hilz, M Hornung, A Kessler, S D Kraft, S Kuschel, H Liebetrau, W Ma, J Polz, H-P Schlenvoigt, F Schorcht, and M B Schwab

Subjects

PROTON beams, SPATIAL distribution (Quantum optics), LASER-plasma interactions, PROTON accelerators, ELECTRIC field effects, LASER pulses

Abstract

The spatial distribution of protons accelerated from submicron-thick plastic foil targets using multi-terawatt, frequency-doubled laser pulses with ultra-high temporal contrast has been investigated experimentally. A very stable, ring-like beam profile of the accelerated protons, oriented around the target’s normal direction has been observed. The ring’s opening angle has been found to decrease with increasing foil thicknesses. Two-dimensional particle-in-cell simulations reproduce our results indicating that the ring is formed during the expansion of the proton density distribution into the vacuum as described by the mechanism of target-normal sheath acceleration. Here—in addition to the longitudinal electric fields responsible for the forward acceleration of the protons—a lateral charge separation leads to transverse field components accelerating the protons in the lateral direction. [ABSTRACT FROM AUTHOR]

Published

2018

16. Laser-ablation-based ion source characterization and manipulation for laser-driven ion acceleration.

Author

P Sommer, J Metzkes-Ng, F-E Brack, T E Cowan, S D Kraft, L Obst, M Rehwald, H-P Schlenvoigt, U Schramm, and K Zeil

Subjects

LASER ablation, LASER pulses, PROTON accelerators, ION beams, TITANIUM, PARTIAL pressure

Abstract

For laser-driven ion acceleration from thin foils (∼10 μm–100 nm) in the target normal sheath acceleration regime, the hydro-carbon contaminant layer at the target surface generally serves as the ion source and hence determines the accelerated ion species, i.e. mainly protons, carbon and oxygen ions. The specific characteristics of the source layer—thickness and relevant lateral extent—as well as its manipulation have both been investigated since the first experiments on laser-driven ion acceleration using a variety of techniques from direct source imaging to knife-edge or mesh imaging. In this publication, we present an experimental study in which laser ablation in two fluence regimes (low: F ∼ 0.6 J cm−2, high: F ∼ 4 J cm−2) was applied to characterize and manipulate the hydro-carbon source layer. The high-fluence ablation in combination with a timed laser pulse for particle acceleration allowed for an estimation of the relevant source layer thickness for proton acceleration. Moreover, from these data and independently from the low-fluence regime, the lateral extent of the ion source layer became accessible. [ABSTRACT FROM AUTHOR]

Published

2018

17. On the study of hydrodynamic instabilities in the presence of background magnetic fields in high-energy-density plasmas

Author

M. J.-E. Manuel, B. Khiar, G. Rigon, B. Albertazzi, S. R. Klein, F. Kroll, F. -E. Brack, T. Michel, P. Mabey, S. Pikuz, J. C. Williams, M. Koenig, A. Casner, and C. C. Kuranz

Subjects

Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

Blast-wave-driven hydrodynamic instabilities are studied in the presence of a background B-field through experiments and simulations in the high-energy-density (HED) physics regime. In experiments conducted at the Laboratoire pour l’utilisation des lasers intenses (LULI), a laser-driven shock-tube platform was used to generate a hydrodynamically unstable interface with a prescribed sinusoidal surface perturbation, and short-pulse x-ray radiography was used to characterize the instability growth with and without a 10-T B-field. The LULI experiments were modeled in FLASH using resistive and ideal magnetohydrodynamics (MHD), and comparing the experiments and simulations suggests that the Spitzer model implemented in FLASH is necessary and sufficient for modeling these planar systems. These results suggest insufficient amplification of the seed B-field, due to resistive diffusion, to alter the hydrodynamic behavior. Although the ideal-MHD simulations did not represent the experiments accurately, they suggest that similar HED systems with dynamic plasma-β (=2μ0ρv2/B2) values of less than ∼100 can reduce the growth of blast-wave-driven Rayleigh–Taylor instabilities. These findings validate the resistive-MHD FLASH modeling that is being used to design future experiments for studying B-field effects in HED plasmas.

Published

2021