Your search keyword '"Karsch, S"' showing total 51 results

1. Pareto Optimization and Tuning of a Laser Wakefield Accelerator.

Author

Irshad F, Eberle C, Foerster FM, Grafenstein KV, Haberstroh F, Travac E, Weisse N, Karsch S, and Döpp A

Abstract

Optimization of accelerator performance parameters is limited by numerous trade-offs, and finding the appropriate balance between optimization goals for an unknown system is challenging to achieve. Here, we show that multiobjective Bayesian optimization can map the solution space of a laser wakefield accelerator (LWFA) in a very sample-efficient way. We observe that there exists a wide range of Pareto-optimal solutions that trade beam energy versus charge at similar laser-to-beam efficiency. Moreover, many applications such as light sources require particle beams at certain target energies. We demonstrate accurate energy tuning of the LWFA from 150 to 400 MeV via the simultaneous adjustment of eight parameters. To further advance this use case, we propose an inverse model that allows a user to specify desired beam parameters. Trained on the forward Gaussian process model, the inverse model generates input parameter value ranges within which the desired setting is likely to be reached. The method reveals different strategies for accelerator tuning and is expected to drastically facilitate the operation of LWFAs in the near future.

Published

2024

2. Laser-accelerated electron beams at 1 GeV using optically-induced shock injection.

Author

V Grafenstein K, Foerster FM, Haberstroh F, Campbell D, Irshad F, Salgado FC, Schilling G, Travac E, Weiße N, Zepf M, Döpp A, and Karsch S

Abstract

In recent years, significant progress has been made in laser wakefield acceleration (LWFA), both regarding the increase in electron energy, charge and stability as well as the reduction of bandwidth of electron bunches. Simultaneous optimization of these parameters is, however, still the subject of an ongoing effort in the community to reach sufficient beam quality for next generation's compact accelerators. In this report, we show the design of slit-shaped gas nozzles providing centimeter-long supersonic gas jets that can be used as targets for the acceleration of electrons to the GeV regime. In LWFA experiments at the Centre for Advanced Laser Applications, we show that electron bunches are accelerated to [Formula: see text] using these nozzles. The electron bunches were injected into the laser wakefield via a laser-machined density down-ramp using hydrodynamic optical-field-ionization and subsequent plasma expansion on a ns-timescale. This injection method provides highly controllable quasi-monoenergetic electron beams with high charge around [Formula: see text], low divergence of [Formula: see text], and a relatively small energy spread of around [Formula: see text] at [Formula: see text]. In contrast to capillaries and gas cells, the scheme allows full plasma access for injection, probing or guiding in order to further improve the energy and quality of LWFA beams., (© 2023. The Author(s).)

Published

2023

3. Measuring spatio-temporal couplings using modal spatio-spectral wavefront retrieval.

Author

Weisse N, Esslinger J, Howard S, Foerster FM, Haberstroh F, Doyle L, Norreys P, Schreiber J, Karsch S, and Döpp A

Abstract

Knowledge of spatio-temporal couplings such as pulse-front tilt or curvature is important to determine the focused intensity of high-power lasers. Common techniques to diagnose these couplings are either qualitative or require hundreds of measurements. Here we present both a new algorithm for retrieving spatio-temporal couplings, as well as novel experimental implementations. Our method is based on the expression of the spatio-spectral phase in terms of a Zernike-Taylor basis, allowing us to directly quantify the coefficients for common spatio-temporal couplings. We take advantage of this method to perform quantitative measurements using a simple experimental setup, consisting of different bandpass filters in front of a Shack-Hartmann wavefront sensor. This fast acquisition of laser couplings using narrowband filters, abbreviated FALCON, is easy and cheap to implement in existing facilities. To this end, we present a measurement of spatio-temporal couplings at the ATLAS-3000 petawatt laser using our technique.

Published

2023

4. Radiation Exposure in the Acute Phase after Aneurysmal Subarachnoid Hemorrhage in the Era of CT Perfusion.

Author

Döring K, Mielke D, Moerer O, Stamm G, Karsch S, Psychogios MN, Rohde V, and Malinova V

Subjects

Humans, Perfusion adverse effects, Retrospective Studies, Tomography, X-Ray Computed, Treatment Outcome, Radiation Exposure prevention & control, Subarachnoid Hemorrhage complications, Vasospasm, Intracranial etiology

Abstract

Purpose: Aneurysmal subarachnoid hemorrhage (aSAH) is associated with a high risk of developing multiple complications requiring further diagnostics including imaging associated with radiation exposure (RE). Since aSAH often affects younger patients, the obtained cumulative RE may have serious long-term health consequences. The aim of this study was to calculate the cumulative RE in the acute phase after aSAH and to identify contributors to RE. Additionally, we investigated whether there is a correlation of RE with outcome., Methods: A retrospective analysis of patients with aSAH treated at our department from 2012 to 2018 was performed. The radiation dose of every single cranial radiological examination was calculated for every patient. The outcome was assessed according to the modified Rankin scale (mRS) 3 months after ictus. Factors associated with high RE were evaluated and the correlation of RE with outcome was assessed., Results: In 268 included consecutive patients, the mean cumulative RE per patient was 39.95 mSv, ranging from 2 to 265.5 mSv. A higher RE correlated with delayed cerebral ischemia (r = 0.52, p < 0.0001), delayed infarction (r = 0.25, p < 0.0001), delayed ischemic neurological deficits (r = 0.29, p < 0.0001) and transcranial Doppler (TCD)-vasospasm (r = 0.34, p < 0.0001). Independent predictors of outcome were age (p = 0.0001), World Federation of Neurosurgical Societies (WFNS) grade (p < 0.0001) and delayed infarction (p = 0.0004), while RE did not correlate with outcome., Conclusion: There is a considerable imaging-related RE in aSAH patients. A meticulous decision-making process and imaging protocols with lower RE for the deployment of CT-based and fluoroscopy-based imaging is indicated in order to minimize the risk for radiation-mediated heath consequences in this patient population., (© 2021. Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2022

5. Demonstration of a compact plasma accelerator powered by laser-accelerated electron beams.

Author

Kurz T, Heinemann T, Gilljohann MF, Chang YY, Couperus Cabadağ JP, Debus A, Kononenko O, Pausch R, Schöbel S, Assmann RW, Bussmann M, Ding H, Götzfried J, Köhler A, Raj G, Schindler S, Steiniger K, Zarini O, Corde S, Döpp A, Hidding B, Karsch S, Schramm U, Martinez de la Ossa A, and Irman A

Abstract

Plasma wakefield accelerators are capable of sustaining gigavolt-per-centimeter accelerating fields, surpassing the electric breakdown threshold in state-of-the-art accelerator modules by 3-4 orders of magnitude. Beam-driven wakefields offer particularly attractive conditions for the generation and acceleration of high-quality beams. However, this scheme relies on kilometer-scale accelerators. Here, we report on the demonstration of a millimeter-scale plasma accelerator powered by laser-accelerated electron beams. We showcase the acceleration of electron beams to 128 MeV, consistent with simulations exhibiting accelerating gradients exceeding 100 GV m -1 . This miniaturized accelerator is further explored by employing a controlled pair of drive and witness electron bunches, where a fraction of the driver energy is transferred to the accelerated witness through the plasma. Such a hybrid approach allows fundamental studies of beam-driven plasma accelerator concepts at widely accessible high-power laser facilities. It is anticipated to provide compact sources of energetic high-brightness electron beams for quality-demanding applications such as free-electron lasers.

Published

2021

6. Spectral broadening of 112  mJ, 1.3  ps pulses at 5  kHz in a LG 10 multipass cell with compressibility to 37  fs.

Author

Kaumanns M, Kormin D, Nubbemeyer T, Pervak V, and Karsch S

Abstract

The first-order helical Laguerre-Gaussian mode (also called donut mode) is used to improve the energy throughput of nonlinear spectral broadening in gas-filled multipass cells. The method proposed in this Letter enables, for the first time to the best of our knowledge, the nonlinear spectral broadening of pulses with energies beyond 100 mJ and is suitable for an average power of more than 500 W while conserving an excellent spatio-spectral homogeneity of ∼98 % and a Gaussian-like focus profile. Additionally compressibility from 1.3 ps to 37 fs is demonstrated.

Published

2021

7. An intact keratin network is crucial for mechanical integrity and barrier function in keratinocyte cell sheets.

Author

Karsch S, Büchau F, Magin TM, and Janshoff A

Subjects

Animals, Biomechanical Phenomena, Cell Line, Epidermis metabolism, Epidermis ultrastructure, Gene Deletion, Intercellular Junctions genetics, Intercellular Junctions metabolism, Intercellular Junctions ultrastructure, Keratinocytes metabolism, Keratins genetics, Keratins ultrastructure, Mice, Wound Healing, Keratinocytes cytology, Keratins metabolism

Abstract

The isotype-specific composition of the keratin cytoskeleton is important for strong adhesion, force resilience, and barrier function of the epidermis. However, the mechanisms by which keratins regulate these functions are still incompletely understood. In this study, the role and significance of the keratin network for mechanical integrity, force transmission, and barrier formation were analyzed in murine keratinocytes. Following the time-course of single-cell wound closure, wild-type (WT) cells slowly closed the gap in a collective fashion involving tightly connected neighboring cells. In contrast, the mechanical response of neighboring cells was compromised in keratin-deficient cells, causing an increased wound area initially and an inefficient overall wound closure. Furthermore, the loss of the keratin network led to impaired, fragmented cell-cell junctions, and triggered a profound change in the overall cellular actomyosin architecture. Electric cell-substrate impedance sensing of cell junctions revealed a dysfunctional barrier in knockout (Kty -/- ) cells compared to WT cells. These findings demonstrate that Kty -/- cells display a novel phenotype characterized by loss of mechanocoupling and failure to form a functional barrier. Re-expression of K5/K14 rescued the barrier defect to a significant extent and reestablished the mechanocoupling with remaining discrepancies likely due to the low abundance of keratins in that setting. Our study reveals the major role of the keratin network for mechanical homeostasis and barrier functionality in keratinocyte layers.

Published

2020

8. Radiation protection modelling for 2.5 Petawatt-laser production of ultrashort x-ray, proton and ion bunches: Monte Carlo model of the Munich CALA facility.

Author

Englbrecht FS, Döpp A, Hartmann J, Lindner FH, Groß ML, Wirth HF, Thirolf PG, Karsch S, Schreiber J, Parodi K, and Dedes G

Subjects

Lasers, Monte Carlo Method, Particle Accelerators, Protons, X-Rays, Radiation Protection methods

Abstract

The 'Centre for Advanced Laser Applications' (CALA) is a new research institute for laser-based acceleration of electron beams for brilliant x-ray generation, laser-driven sub-nanosecond bunches of protons and heavy ions for biomedical applications like imaging and tumour therapy as well as for nuclear and high-field physics.The radiation sources emerging from experiments using the up to 2.5 petawatt laser pulses with 25 femtosecond duration will be mixed particle-species of high intensity, high energy and pulsed, thus posing new challenges compared to conventional radiation protection. Such worldwide pioneering laser experiments result in source characteristics that require careful a-priori radiation safety simulations.The FLUKA Monte-Carlo code was used to model the five CALA experimental caves, including the corridors, halls and air spaces surrounding the caves. Beams of electrons (<5 GeV), protons (<200 MeV), 12 C (<400MeV/u) and 197 Au (<10MeV/u) ions were simulated using spectra, divergences and bunch-charges based on expectations from recent scientific progress.Simulated dose rates locally can exceed 1.5 kSv h -1 inside beam dumps. Vacuum pipes in the cave walls for laser transport and extraction channels for the generated x-rays result in small dose leakage to neighboring areas. Secondary neutrons contribute to most of the prompt dose rate outside caves into which the beam is delivered. This secondary radiation component causes non-negligible dose rates to occur behind walls to which large fluences of secondary particles are directed.By employing adequate beam dumps matched to beam-divergence, magnets, passive shielding and laser pulse repetition limits, average dose rates in- and outside the experimental building stay below design specifications (<0.5μSv h-1) for unclassified areas,<2.5μSv h-1for supervised areas,<7.5μSv h-1maximum local dose rate) and regulatory limits (<1mSv a-1for unclassified areas)., (Creative Commons Attribution license.)

Published

2020

9. Water-Window X-Ray Pulses from a Laser-Plasma Driven Undulator.

Author

Maier AR, Kajumba N, Guggenmos A, Werle C, Wenz J, Delbos N, Zeitler B, Dornmair I, Schmidt J, Gullikson EM, Krausz F, Schramm U, Kleineberg U, Karsch S, and Grüner F

Abstract

Femtosecond (fs) x-ray pulses are a key tool to study the structure and dynamics of matter on its natural length and time scale. To complement radio-frequency accelerator-based large-scale facilities, novel laser-based mechanisms hold promise for compact laboratory-scale x-ray sources. Laser-plasma driven undulator radiation in particular offers high peak-brightness, optically synchronized few-fs pulses reaching into the few-nanometer (nm) regime. To date, however, few experiments have successfully demonstrated plasma-driven undulator radiation. Those that have, typically operated at single and comparably long wavelengths. Here we demonstrate plasma-driven undulator radiation with octave-spanning tuneability at discrete wavelengths reaching from 13 nm to 4 nm. Studying spontaneous undulator radiation is an important step towards a plasma-driven free-electron laser. Our specific setup creates a photon pulse, which closely resembles the plasma electron bunch length and charge profile and thus might enable novel methods to characterize the longitudinal electron phase space.

Published

2020

10. Nonlinear plasma wavelength scalings in a laser wakefield accelerator.

Author

Ding H, Döpp A, Gilljohann M, Götzfried J, Schindler S, Wildgruber L, Cheung G, Hooker SM, and Karsch S

Abstract

Laser wakefield acceleration relies on the excitation of a plasma wave due to the ponderomotive force of an intense laser pulse. However, plasma wave trains in the wake of the laser have scarcely been studied directly in experiments. Here we use few-cycle shadowgraphy in conjunction with interferometry to quantify plasma waves excited by the laser within the density range of GeV-scale accelerators, i.e., a few 10^{18}cm^{-3}. While analytical models suggest a clear dependency between the nonlinear plasma wavelength and the peak potential a&#95;{0}, our study shows that the analytical models are only accurate for driver strength a&#95;{0}≲1. Experimental data and systematic particle-in-cell simulations reveal that nonlinear lengthening of the plasma wave train depends not solely on the laser peak intensity but also on the waist of the focal spot.

Published

2020

11. On-target temporal characterization of optical pulses at relativistic intensity.

Author

Leshchenko VE, Kessel A, Jahn O, Krüger M, Münzer A, Trushin SA, Veisz L, Major Z, and Karsch S

Abstract

High-field experiments are very sensitive to the exact value of the peak intensity of an optical pulse due to the nonlinearity of the underlying processes. Therefore, precise knowledge of the pulse intensity, which is mainly limited by the accuracy of the temporal characterization, is a key prerequisite for the correct interpretation of experimental data. While the detection of energy and spatial profile is well established, the unambiguous temporal characterization of intense optical pulses, another important parameter required for intensity evaluation, remains a challenge, especially at relativistic intensities and a few-cycle pulse duration. Here, we report on the progress in the temporal characterization of intense laser pulses and present the relativistic surface second harmonic generation dispersion scan (RSSHG-D-scan)-a new approach allowing direct on-target temporal characterization of high-energy, few-cycle optical pulses at relativistic intensity., Competing Interests: Conflict of interestThe authors declare that they have no conflict of interest., (© The Author(s) 2019.)

Published

2019

12. Hybrid LWFA-PWFA staging as a beam energy and brightness transformer: conceptual design and simulations.

Author

Martinez de la Ossa A, Assmann RW, Bussmann M, Corde S, Couperus Cabadağ JP, Debus A, Döpp A, Ferran Pousa A, Gilljohann MF, Heinemann T, Hidding B, Irman A, Karsch S, Kononenko O, Kurz T, Osterhoff J, Pausch R, Schöbel S, and Schramm U

Abstract

We present a conceptual design for a hybrid laser-driven plasma wakefield accelerator (LWFA) to beam-driven plasma wakefield accelerator (PWFA). In this set-up, the output beams from an LWFA stage are used as input beams of a new PWFA stage. In the PWFA stage, a new witness beam of largely increased quality can be produced and accelerated to higher energies. The feasibility and the potential of this concept is shown through exemplary particle-in-cell simulations. In addition, preliminary simulation results for a proof-of-concept experiment in Helmholtz-Zentrum Dresden-Rossendorf (Germany) are shown. This article is part of the Theo Murphy meeting issue 'Directions in particle beam-driven plasma wakefield acceleration'.

Published

2019

13. Stiffness of MDCK II Cells Depends on Confluency and Cell Size.

Author

Nehls S, Nöding H, Karsch S, Ries F, and Janshoff A

Subjects

Animals, Biomechanical Phenomena, Cell Adhesion, Dogs, Madin Darby Canine Kidney Cells, Phenotype, Single-Cell Analysis, Cell Size, Mechanical Phenomena

Abstract

Mechanical phenotyping of adherent cells has become a serious tool in cell biology to understand how cells respond to their environment and eventually to identify disease patterns such as the malignancy of cancer cells. In the steady state, homeostasis is of pivotal importance, and cells strive to maintain their internal stresses even in challenging environments and in response to external chemical and mechanical stimuli. However, a major problem exists in determining mechanical properties because many techniques, such as atomic force microscopy, that assess these properties of adherent cells locally can only address a limited number of cells and provide elastic moduli that vary substantially from cell to cell. The origin of this spread in stiffness values is largely unknown and might limit the significance of measurements. Possible reasons for the disparity are variations in cell shape and size, as well as biological reasons such as the cell cycle or polarization state of the cell. Here, we show that stiffness of adherent epithelial cells rises with increasing projected apical cell area in a nonlinear fashion. This size stiffening not only occurs as a consequence of varying cell-seeding densities, it can also be observed within a small area of a particular cell culture. Experiments with single adherent cells attached to defined areas via microcontact printing show that size stiffening is limited to cells of a confluent monolayer. This leads to the conclusion that cells possibly regulate their size distribution through cortical stress, which is enhanced in larger cells and reduced in smaller cells., (Copyright © 2019 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2019

14. 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 FE, Ding H, Englbrecht FS, Gao Y, Gebhard J, Gilljohann M, Götzfried J, Hartmann J, Herr S, Hilz P, Kraft SD, Kreuzer C, Kroll F, Lindner FH, Metzkes-Ng J, Ostermayr TM, Ridente E, Rösch TF, Schilling G, Schlenvoigt HP, Speicher M, Taray D, Würl M, Zeil K, Schramm U, Karsch S, Parodi K, Bolton PR, Assmann W, and Schreiber J

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

15. Highlights of the updated Dutch evidence- and consensus-based guideline on psoriasis 2017.

Author

van der Kraaij GE, Balak DMW, Busard CI, van Cranenburgh OD, Chung Y, Driessen RJB, de Groot M, de Jong EMGJ, Kemperman PMJH, de Kort WJA, Karsch SA, Lamberts A, Lecluse LLA, van Lümig PPM, Menting SP, Prens EP, van den Reek JMPA, Seyger MMB, Thio HB, Veldkamp WR, Wakkee M, Nast A, Jacobs A, Rosumeck S, and Spuls Chair PI

Subjects

Consensus, Dermatology methods, Evidence-Based Medicine methods, Humans, Netherlands, Societies, Medical standards, Dermatology standards, Evidence-Based Medicine standards, Practice Guidelines as Topic, Psoriasis therapy

Published

2019

16. Calibration and cross-laboratory implementation of scintillating screens for electron bunch charge determination.

Author

Kurz T, Couperus JP, Krämer JM, Ding H, Kuschel S, Köhler A, Zarini O, Hollatz D, Schinkel D, D'Arcy R, Schwinkendorf JP, Osterhoff J, Irman A, Schramm U, and Karsch S

Abstract

We revise the calibration of scintillating screens commonly used to detect relativistic electron beams with low average current, e.g., from laser-plasma accelerators, based on new and expanded measurements that include higher charge density and different types of screens than previous work [Buck et al. , Rev. Sci. Instrum. 81 , 033301 (2010)]. Electron peak charge densities up to 10 nC/mm 2 were provided by focused picosecond-long electron beams delivered by the Electron Linac for beams with high Brilliance and low Emittance (ELBE) at the Helmholtz-Zentrum Dresden-Rossendorf. At low charge densities, a linear scintillation response was found, followed by the onset of saturation in the range of nC/mm 2 . The absolute calibration factor (photons/sr/pC) in this linear regime was measured to be almost a factor of 2 lower than that reported by Buck et al. retrospectively implying a higher charge in the charge measurements performed with the former calibration. A good agreement was found with the results provided by Glinec et al. [Rev. Sci. Instrum. 77 , 103301 (2006)]. Furthermore long-term irradiation tests with an integrated dose of approximately 50 nC/mm 2 indicate a significant decrease of the scintillation efficiency over time. Finally, in order to enable the transfer of the absolute calibration between laboratories, a new constant reference light source has been developed.

Published

2018

17. Single-Cell Defects Cause a Long-Range Mechanical Response in a Confluent Epithelial Cell Layer.

Author

Karsch S, Kong D, Großhans J, and Janshoff A

Subjects

Animals, Biomechanical Phenomena, Dogs, Madin Darby Canine Kidney Cells, Epithelial Cells cytology, Mechanical Phenomena, Single-Cell Analysis

Abstract

Epithelial cells are responsible for tissue homeostasis and form a barrier to maintain chemical gradients and mechanical integrity. Therefore, rapid wound closure is crucial for proper tissue function and restoring homeostasis. In this study, the mechanical properties of cells surrounding a single-cell wound are investigated during closure of the defect. The single-cell wound is induced in an intact layer using micropipette action and responses in neighboring cells are monitored with atomic force microscopy. Direct neighbors reveal a rise in the apparent pretension, which is dominated by cortical tension. The same effect was observed for a single-cell wound induced by laser ablation and during closure of a not fully confluent layer. Moreover, changes in the apparent pretension are far reaching and persist even in cells separated by three cell widths from the defect. This shows that epithelial cells respond to minimal wounds in a collective fashion by increased contractility with substantial reach., (Copyright © 2017 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2017

18. Dynamics of laser-driven proton acceleration exhibited by measured laser absorptivity and reflectivity.

Author

Bin JH, Allinger K, Khrennikov K, Karsch S, Bolton PR, and Schreiber J

Abstract

Proton acceleration from nanometer thin foils with intense laser pulses is investigated experimentally. We analyzed the laser absorptivity by parallel monitoring of laser transmissivity and reflectivity with different laser intensities when moving the targets along the laser axis. A direct correlation between laser absorptivity and maximum proton energy is observed. Experimental results are interpreted in analytical estimation, exhibiting a coexistence of plasma expansion and light-sail form of radiation pressure acceleration (RPA-LS) mechanisms during the entire proton acceleration process based on the measured laser absorptivity and reflectivity.

Published

2017

19. Collective Deceleration of Laser-Driven Electron Bunches.

Author

Chou S, Xu J, Khrennikov K, Cardenas DE, Wenz J, Heigoldt M, Hofmann L, Veisz L, and Karsch S

Abstract

Few-fs electron bunches from laser wakefield acceleration (LWFA) can efficiently drive plasma wakefields (PWFs), as shown by their propagation through underdense plasma in two experiments. A strong and density-insensitive deceleration of the bunches has been observed in 2 mm of 10^{18}  cm^{-3} density plasma with 5.1  GV/m average gradient, which is attributed to a self-driven PWF. This observation implies that the physics of PWFs, usually relying on large-scale rf accelerators as drivers, can be studied by tabletop LWFA electron sources.

Published

2016

20. Generation of multi-octave spanning high-energy pulses by cascaded nonlinear processes in BBO.

Author

Kessel A, Trushin SA, Karpowicz N, Skrobol C, Klingebiel S, Wandt C, and Karsch S

Abstract

We present the generation of optical pulses with a spectral range of 500-2400 nm and energies up to 10 µJ at 1 kHz repetition rate by cascaded second-order nonlinear interaction of few-cycle pulses in beta-barium borate (BBO). Numerical simulations with a 1D+time split-step model are performed to explain the experimental findings. The large bandwidth and smooth spectral amplitude of the resulting pulses make them an ideal seed for ultra-broadband optical parametric chirped pulse amplification and an attractive source for spectroscopic applications.

Published

2016

21. Quantitative X-ray phase-contrast microtomography from a compact laser-driven betatron source.

Author

Wenz J, Schleede S, Khrennikov K, Bech M, Thibault P, Heigoldt M, Pfeiffer F, and Karsch S

Abstract

X-ray phase-contrast imaging has recently led to a revolution in resolving power and tissue contrast in biomedical imaging, microscopy and materials science. The necessary high spatial coherence is currently provided by either large-scale synchrotron facilities with limited beamtime access or by microfocus X-ray tubes with rather limited flux. X-rays radiated by relativistic electrons driven by well-controlled high-power lasers offer a promising route to a proliferation of this powerful imaging technology. A laser-driven plasma wave accelerates and wiggles electrons, giving rise to a brilliant keV X-ray emission. This so-called betatron radiation is emitted in a collimated beam with excellent spatial coherence and remarkable spectral stability. Here we present a phase-contrast microtomogram of a biological sample using betatron X-rays. Comprehensive source characterization enables the reconstruction of absolute electron densities. Our results suggest that laser-based X-ray technology offers the potential for filling the large performance gap between synchrotron- and current X-ray tube-based sources.

Published

2015

22. Tunable all-optical quasimonochromatic thomson x-ray source in the nonlinear regime.

Author

Khrennikov K, Wenz J, Buck A, Xu J, Heigoldt M, Veisz L, and Karsch S

Abstract

We present an all-laser-driven, energy-tunable, and quasimonochromatic x-ray source based on Thomson scattering from laser-wakefield-accelerated electrons. One part of the laser beam was used to drive a few-fs bunch of quasimonoenergetic electrons, while the remainder was backscattered off the bunch at weakly relativistic intensity. When the electron energy was tuned from 17-50 MeV, narrow x-ray spectra peaking at 5-42 keV were recorded with high resolution, revealing nonlinear features. We present a large set of measurements showing the stability and practicality of our source.

Published

2015

23. Efficient generation of THz pulses with 0.4 mJ energy.

Author

Fülöp JA, Ollmann Z, Lombosi C, Skrobol C, Klingebiel S, Pálfalvi L, Krausz F, Karsch S, and Hebling J

Abstract

Efficient generation of THz pulses with high energy was demonstrated by optical rectification of 785-fs laser pulses in lithium niobate using tilted-pulse-front pumping. The enhancement of conversion efficiency by a factor of 2.4 to 2.7 was demonstrated up to 186 μJ THz energy by cryogenic cooling of the generating crystal and using up to 18.5 mJ/cm2 pump fluence. Generation of THz pulses with more than 0.4 mJ energy and 0.77% efficiency was demonstrated even at room temperature by increasing the pump fluence to 186 mJ/cm2. The spectral peak is at about 0.2 THz, suitable for charged-particle manipulation.

Published

2014

24. Shock-front injector for high-quality laser-plasma acceleration.

Author

Buck A, Wenz J, Xu J, Khrennikov K, Schmid K, Heigoldt M, Mikhailova JM, Geissler M, Shen B, Krausz F, Karsch S, and Veisz L

Abstract

We report the generation of stable and tunable electron bunches with very low absolute energy spread (ΔE ≈ 5 MeV) accelerated in laser wakefields via injection and trapping at a sharp downward density jump produced by a shock front in a supersonic gas flow. The peak of the highly stable and reproducible electron energy spectrum was tuned over more than 1 order of magnitude, containing a charge of 1-100 pC and a charge per energy interval of more than 10 pC/MeV. Laser-plasma electron acceleration with Ti:sapphire lasers using this novel injection mechanism provides high-quality electron bunches tailored for applications.

Published

2013

25. Generation of sub-mJ terahertz pulses by optical rectification.

Author

Fülöp JA, Pálfalvi L, Klingebiel S, Almási G, Krausz F, Karsch S, and Hebling J

Abstract

Recent theoretical calculations predicted an order-of-magnitude increase in the efficiency of terahertz pulse generation by optical rectification in lithium niobate when 500 fs long pump pulses are used, rather than the commonly used ~100 fs pulses. Even by using longer than optimal pump pulses of 1.3 ps duration, 2.5× higher THz pulse energy (125 μJ) was measured with 2.5× higher pump-to-THz energy conversion efficiency (0.25%) than reported previously with shorter pulses. These results verify the advantage of longer pump pulses and support the expectation that mJ-level THz pulses will be available by cooling the crystal and using large pumped area.

Published

2012

26. Broadband amplification by picosecond OPCPA in DKDP pumped at 515 nm.

Author

Skrobol C, Ahmad I, Klingebiel S, Wandt C, Trushin SA, Major Z, Krausz F, and Karsch S

Abstract

On the quest towards reaching petawatt-scale peak power light pulses with few-cycle duration, optical parametric chirped pulse amplification (OPCPA) pumped on a time scale of a few picoseconds represents a very promising route. Here we present an experimental demonstration of few-ps OPCPA in DKDP, in order to experimentally verify the feasibility of the scheme. Broadband amplification was observed in the wavelength range of 830-1310 nm. The amplified spectrum supports two optical cycle pulses, at a central wavelength of ~920 nm, with a pulse duration of 6.1 fs (FWHM). The comparison of the experimental results with our numerical calculations of the OPCPA process showed good agreement. These findings confirm the reliability of our theoretical modelling, in particular with respect to the design for further amplification stages, scaling the output peak powers to the petawatt scale.

Published

2012

27. Experimental and theoretical investigation of timing jitter inside a stretcher-compressor setup.

Author

Klingebiel S, Ahmad I, Wandt C, Skrobol C, Trushin SA, Major Z, Krausz F, and Karsch S

Abstract

In an optically synchronized short-pulse optical-parametric chirped-pulse amplification (OPCPA) system, we observe a few-100 fs-scale timing jitter. With an active timing stabilization system slow fluctuations are removed and the timing jitter can be reduced to 100 fs standard deviation (Std). As the main source for the timing fluctuations we could identify air turbulence in the stretcher-compressor setup inside the chirped pulse amplification (CPA) pump chain. This observation is supported by theoretical investigation of group delay changes for angular deviations occurring between the parallel gratings of a compressor or stretcher, as they can be introduced by air turbulence.

Published

2012

28. High energy picosecond Yb:YAG CPA system at 10 Hz repetition rate for pumping optical parametric amplifiers.

Author

Klingebiel S, Wandt C, Skrobol C, Ahmad I, Trushin SA, Major Z, Krausz F, and Karsch S

Abstract

We present a chirped pulse amplification (CPA) system based on diode-pumped Yb:YAG. The stretched ns-pulses are amplified and have been compressed to less than 900 fs with an energy of 200 mJ and a repetition rate of 10 Hz. This system is optically synchronized with a broadband seed laser and therefore ideally suited for pumping optical parametric chirped pulse amplification (OPCPA) stages on a ps-timescale.

Published

2011

29. All-optical steering of laser-wakefield-accelerated electron beams.

Author

Popp A, Vieira J, Osterhoff J, Major Z, Hörlein R, Fuchs M, Weingartner R, Rowlands-Rees TP, Marti M, Fonseca RA, Martins SF, Silva LO, Hooker SM, Krausz F, Grüner F, and Karsch S

Abstract

We investigate the influence of a tilted laser-pulse-intensity front on laser-wakefield acceleration. Such asymmetric light pulses may be exploited to obtain control over the electron-bunch-pointing direction and in our case allowed for reproducible electron-beam steering in an all-optical way within an 8 mrad opening window with respect to the initial laser axis. We also discovered evidence of collective electron-betatron oscillations due to off-axis electron injection into the wakefield induced by a pulse-front tilt. These findings are supported by 3D particle-in-cell simulations.

Published

2010

30. Simulations of petawatt-class few-cycle optical-parametric chirped-pulse amplification, including nonlinear refractive index effects.

Author

Thai A, Skrobol C, Bates PK, Arisholm G, Major Z, Krausz F, Karsch S, and Biegert J

Abstract

We present three-dimensional simulations of optical-parametric chirped-pulse amplification stages for a few-cycle petawatt-class laser. The simulations take into account the effects of depletion, diffraction, walk-off, quantum noise, and the nonlinear refractive index (n(2)). In the absence of n(2) effects, we show these stages can generate 3.67J pulses supporting 4fs transform-limited pulse durations. Adding the nonlinear refractive index to the simulation, the energy output is reduced by ~11% and the bandwidth narrows by ~129nm, increasing the Fourier limit by ~17.5%.

Published

2010

31. Monoenergetic energy doubling in a hybrid laser-plasma wakefield accelerator.

Author

Hidding B, Königstein T, Osterholz J, Karsch S, Willi O, and Pretzler G

Abstract

An ultracompact laser-plasma-generated, fs-scale electron double bunch system can be injected into a high-density driver/witness-type plasma wakefield accelerator afterburner stage to boost the witness electrons monoenergetically to energies far beyond twice their initial energy on the GeV scale. The combination of conservation of monoenergetic phase-space structure and fs duration with radial electric plasma fields E(r)∼100  GV/m leads to dramatic transversal witness compression and unprecedented charge densities. It seems feasible to upscale and implement the scheme to future accelerator systems.

Published

2010

32. Absolute charge calibration of scintillating screens for relativistic electron detection.

Author

Buck A, Zeil K, Popp A, Schmid K, Jochmann A, Kraft SD, Hidding B, Kudyakov T, Sears CM, Veisz L, Karsch S, Pawelke J, Sauerbrey R, Cowan T, Krausz F, and Schramm U

Abstract

We report on new charge calibrations and linearity tests with high-dynamic range for eight different scintillating screens typically used for the detection of relativistic electrons from laser-plasma based acceleration schemes. The absolute charge calibration was done with picosecond electron bunches at the ELBE linear accelerator in Dresden. The lower detection limit in our setup for the most sensitive scintillating screen (KODAK Biomax MS) was 10 fC/mm(2). The screens showed a linear photon-to-charge dependency over several orders of magnitude. An onset of saturation effects starting around 10-100 pC/mm(2) was found for some of the screens. Additionally, a constant light source was employed as a luminosity reference to simplify the transfer of a one-time absolute calibration to different experimental setups.

Published

2010

33. Electron bunch length measurements from laser-accelerated electrons using single-shot THz time-domain interferometry.

Author

Debus AD, Bussmann M, Schramm U, Sauerbrey R, Murphy CD, Major Z, Hörlein R, Veisz L, Schmid K, Schreiber J, Witte K, Jamison SP, Gallacher JG, Jaroszynski DA, Kaluza MC, Hidding B, Kiselev S, Heathcote R, Foster PS, Neely D, Divall EJ, Hooker CJ, Smith JM, Ertel K, Langley AJ, Norreys P, Collier JL, and Karsch S

Abstract

Laser-plasma wakefield-based electron accelerators are expected to deliver ultrashort electron bunches with unprecedented peak currents. However, their actual pulse duration has never been directly measured in a single-shot experiment. We present measurements of the ultrashort duration of such electron bunches by means of THz time-domain interferometry. With data obtained using a 0.5 J, 45 fs, 800 nm laser and a ZnTe-based electro-optical setup, we demonstrate the duration of laser-accelerated, quasimonoenergetic electron bunches [best fit of 32 fs (FWHM) with a 90% upper confidence level of 38 fs] to be shorter than the drive laser pulse, but similar to the plasma period.

Published

2010

34. Generation of ultrahigh-velocity ionizing shocks with petawatt-class laser pulses.

Author

Nilson PM, Mangles SP, Willingale L, Kaluza MC, Thomas AG, Tatarakis M, Najmudin Z, Clarke RJ, Lancaster KL, Karsch S, Schreiber J, Evans RG, Dangor AE, and Krushelnick K

Abstract

Ultrahigh-velocity shock waves (approximately 10,000 km/s or 0.03c) are generated by focusing a 350-TW laser pulse into low-density helium gas. The collisionless ultrahigh-Mach-number electrostatic shock propagates from the plasma into the surrounding gas, ionizing gas as it becomes collisional. The shock undergoes a corrugation instability due to propagation of the ionizing shock within the gas (the Dyakov-Kontorovich instability). This system may be relevant to the study of very high-Mach-number ionizing shocks in astrophysical situations.

Published

2009

35. Chirped-pulse amplification of laser pulses with dispersive mirrors.

Author

Pervak V, Ahmad I, Trushin SA, Major Z, Apolonski A, Karsch S, and Krausz F

Abstract

We report a novel implementation of chirped-pulse amplification (CPA) by dominantly using dispersive multilayer mirrors for chirp control. Our prototyp dispersive-mirror (DMC) compressor has been designed for a kHz Ti:sapphire amplifier and yielded--in a proof-of-concept study--millijoule-energy, sub-20-fs, 790-nm laser pulses with an overall throughput of approximately 90% and unprecedented spatio-temporal quality. Dispersive-mirror-based CPA permits a dramatic simplification of high-power lasers and affords promise for their advancement to shorter pulse durations, higher peak powers, and higher average powers with user-friendly systems.

Published

2009

36. Laser-driven shock acceleration of ion beams from spherical mass-limited targets.

Author

Henig A, Kiefer D, Geissler M, Rykovanov SG, Ramis R, Hörlein R, Osterhoff J, Major Z, Veisz L, Karsch S, Krausz F, Habs D, and Schreiber J

Abstract

We report on experimental studies of ion acceleration from spherical targets of diameter 15 microm irradiated by ultraintense (1x10(20) W/cm2) pulses from a 20-TW Ti:sapphire laser system. A highly directed proton beam with plateau-shaped spectrum extending to energies up to 8 MeV is observed in the laser propagation direction. This beam arises from acceleration in a converging shock launched by the laser, which is confirmed by 3-dimensional particle-in-cell simulations. The temporal evolution of the shock-front curvature shows excellent agreement with a two-dimensional radiation pressure model.

Published

2009

37. Terawatt diode-pumped Yb:CaF2 laser.

Author

Siebold M, Hornung M, Boedefeld R, Podleska S, Klingebiel S, Wandt C, Krausz F, Karsch S, Uecker R, Jochmann A, Hein J, and Kaluza MC

Abstract

We present what we believe to be the first terawatt diode-pumped laser employing single-crystalline Yb:CaF(2) as the amplifying medium. A maximum pulse energy of 420 mJ at a repetition rate of 1 Hz was achieved by seeding with a stretched femtosecond pulse 2 ns in duration, preamplified to 40 mJ. After recompression, a pulse energy of 197 mJ and a duration of 192 fs were obtained, corresponding to a peak power of 1 TW. Furthermore, nanosecond pulses containing an energy of up to 905 mJ were generated without optical damage.

Published

2008

38. Generation of stable, low-divergence electron beams by laser-wakefield acceleration in a steady-state-flow gas cell.

Author

Osterhoff J, Popp A, Major Z, Marx B, Rowlands-Rees TP, Fuchs M, Geissler M, Hörlein R, Hidding B, Becker S, Peralta EA, Schramm U, Grüner F, Habs D, Krausz F, Hooker SM, and Karsch S

Abstract

Laser-driven, quasimonoenergetic electron beams of up to approximately 200 MeV in energy have been observed from steady-state-flow gas cells. These beams emitted within a low-divergence cone of 2.1+/-0.5 mrad FWHM display unprecedented shot-to-shot stability in energy (2.5% rms), pointing (1.4 mrad rms), and charge (16% rms) owing to a highly reproducible gas-density profile within the interaction volume. Laser-wakefield acceleration in gas cells of this type provides a simple and reliable source of relativistic electrons suitable for applications such as the production of extreme-ultraviolet undulator radiation.

Published

2008

39. Generation of 220 mJ nanosecond pulses at a 10 Hz repetition rate with excellent beam quality in a diode-pumped Yb:YAG MOPA system.

Author

Wandt C, Klingebiel S, Siebold M, Major Z, Hein J, Krausz F, and Karsch S

Abstract

A novel all-diode-pumped master oscillator power amplifier system based on Yb:YAG crystal rods has been developed. It consists of a Q-switched oscillator delivering 3 mJ, 6.4 ns pulses at a 10 Hz repetition rate and an additional four-pass amplifier, which boosts the output energy to 220 mJ, while a close to TEM(00) beam quality could be observed. Additionally a simulation of the amplification was written that allows for further scaling considerations.

Published

2008

40. High-energy, diode-pumped, nanosecond Yb:YAG MOPA system.

Author

Siebold M, Hein J, Wandt C, Klingebiel S, Krausz F, and Karsch S

Subjects

Equipment Design, Equipment Failure Analysis, Lasers, Nanotechnology methods, Lasers, Semiconductor, Nanotechnology instrumentation, Ytterbium chemistry

Abstract

Diode-pumped nanosecond multi-pass laser amplification to the joule level using an Yb:YAG slab crystal has been demonstrated. A maximum output pulse energy of 2.9 J at an optical-to-optical efficiency of 10% has been achieved. The seed pulses with a pulse duration of 6.4 ns were generated in a Q-switched Yb:YAG laser and amplified up to a pulse energy of 200mJ in a multi-pass booster amplifier. A maximum average output power of 15W at a repetition rate of 10 Hz has been measured. We also present a relay imaging semi-stable cavity for multi-pass amplification and a diode-pumping scheme employing horizontally stacked high-power laser diodes.

Published

2008

41. Novel method for characterizing relativistic electron beams in a harsh laser-plasma environment.

Author

Hidding B, Pretzler G, Clever M, Brandl F, Zamponi F, Lübcke A, Kämpfer T, Uschmann I, Förster E, Schramm U, Sauerbrey R, Kroupp E, Veisz L, Schmid K, Benavides S, and Karsch S

Subjects

Computer Simulation, Computer-Aided Design, Equipment Design, Equipment Failure Analysis, Hot Temperature, Radiation Dosage, Reproducibility of Results, Scattering, Radiation, Sensitivity and Specificity, Algorithms, Electrons, Gases chemistry, Lasers, Models, Chemical, Radiometry instrumentation, Radiometry methods

Abstract

Particle pulses generated by laser-plasma interaction are characterized by ultrashort duration, high particle density, and sometimes a very strong accompanying electromagnetic pulse (EMP). Therefore, beam diagnostics different from those known from classical particle accelerators such as synchrotrons or linacs are required. Easy to use single-shot techniques are favored, which must be insensitive towards the EMP and associated stray light of all frequencies, taking into account the comparably low repetition rates and which, at the same time, allow for usage in very space-limited environments. Various measurement techniques are discussed here, and a space-saving method to determine several important properties of laser-generated electron bunches simultaneously is presented. The method is based on experimental results of electron-sensitive imaging plate stacks and combines these with Monte Carlo-type ray-tracing calculations, yielding a comprehensive picture of the properties of particle beams. The total charge, the energy spectrum, and the divergence can be derived simultaneously for a single bunch.

Published

2007

42. Collimated multi-MeV ion beams from high-intensity laser interactions with underdense plasma.

Author

Willingale L, Mangles SP, Nilson PM, Clarke RJ, Dangor AE, Kaluza MC, Karsch S, Lancaster KL, Mori WB, Najmudin Z, Schreiber J, Thomas AG, Wei MS, and Krushelnick K

Abstract

A beam of multi-MeV helium ions has been observed from the interaction of a short-pulse high-intensity laser pulse with underdense helium plasma. The ion beam was found to have a maximum energy for He2+ of (40(+3)(-8)) MeV and was directional along the laser propagation path, with the highest energy ions being collimated to a cone of less than 10 degrees. 2D particle-in-cell simulations show that the ions are accelerated by a sheath electric field that is produced at the back of the gas target. This electric field is generated by transfer of laser energy to a hot electron beam, which exits the target generating large space-charge fields normal to its boundary.

Published

2006

43. Generation of quasimonoenergetic electron bunches with 80-fs laser pulses.

Author

Hidding B, Amthor KU, Liesfeld B, Schwoerer H, Karsch S, Geissler M, Veisz L, Schmid K, Gallacher JG, Jamison SP, Jaroszynski D, Pretzler G, and Sauerbrey R

Abstract

Highly collimated, quasimonoenergetic multi-MeV electron bunches were generated by the interaction of tightly focused, 80-fs laser pulses in a high-pressure gas jet. These monoenergetic bunches are characteristic of wakefield acceleration in the highly nonlinear wave breaking regime, which was previously thought to be accessible only by much shorter laser pulses in thinner plasmas. In our experiment, the initially long laser pulse was modified in underdense plasma to match the necessary conditions. This picture is confirmed by semianalytical scaling laws and 3D particle-in-cell simulations. Our results show that laser-plasma interaction can drive itself towards this type of laser wakefield acceleration even if the initial laser and plasma parameters are outside the required regime.

Published

2006

44. Study of electron-beam propagation through preionized dense foam plasmas.

Author

Jung R, Osterholz J, Löwenbrück K, Kiselev S, Pretzler G, Pukhov A, Willi O, Kar S, Borghesi M, Nazarov W, Karsch S, Clarke R, and Neely D

Abstract

The transport of an intense electron-beam produced by the Vulcan petawatt laser through dense plasmas has been studied by imaging with high resolution the optical emission due to electron transit through the rear side of coated foam targets. It is observed that the MeV-electron beam undergoes strong filamentation and the filaments organize themselves in a ringlike structure. This behavior has been modeled using particle-in-cell simulations of the laser-plasma interaction as well as of the transport of the electron beam through the preionized plasma. In the simulations the filamentary structures are reproduced and attributed to the Weibel instability.

Published

2005

45. Comparison of laser ion acceleration from the front and rear surfaces of thin foils.

Author

Fuchs J, Sentoku Y, Karsch S, Cobble J, Audebert P, Kemp A, Nikroo A, Antici P, Brambrink E, Blazevic A, Campbell EM, Fernández JC, Gauthier JC, Geissel M, Hegelich M, Pépin H, Popescu H, Renard-LeGalloudec N, Roth M, Schreiber J, Stephens R, and Cowan TE

Abstract

The comparative efficiency and beam characteristics of high-energy ions generated by high-intensity short-pulse lasers (approximately 1-6 x 10(19) W/cm2) from both the front and rear surfaces of thin metal foils have been measured under identical conditions. Using direct beam measurements and nuclear activation techniques, we find that rear-surface acceleration produces higher energy particles with smaller divergence and a higher efficiency than front-surface acceleration. Our observations are well reproduced by realistic particle-in-cell simulations, and we predict optimal criteria for future applications.

Published

2005

46. Ion acceleration from the shock front induced by hole boring in ultraintense laser-plasma interactions.

Author

Habara H, Lancaster KL, Karsch S, Murphy CD, Norreys PA, Evans RG, Borghesi M, Romagnani L, Zepf M, Norimatsu T, Toyama Y, Kodama R, King JA, Snavely R, Akli K, Zhang B, Freeman R, Hatchett S, MacKinnon AJ, Patel P, Key MH, Stoeckl C, Stephens RB, Fonseca RA, and Silva LO

Abstract

Ion-acceleration processes have been studied in ultraintense laser plasma interactions for normal incidence irradiation of solid deuterated targets via neutron spectroscopy. The experimental neutron spectra strongly suggest that the ions are preferentially accelerated radially, rather than into the bulk of the material from three-dimensional Monte Carlo fitting of the neutron spectra. Although the laser system has a 10(-7) contrast ratio, a two-dimensional magnetic hydrodynamics simulation shows that the laser pedestal generates a 10 mum scale length in the coronal plasma with a 3 mum scale-length plasma near the critical density. Two-dimensional particle-in-cell simulations, incorporating this realistic density profile, indicate that the acceleration of the ions is caused by a collisionless shock formation. This has implications for modeling energy transport in solid density plasmas as well as cone-focused fast ignition using the next generation PW lasers currently under construction.

Published

2004

47. Ultralow emittance, multi-MeV proton beams from a laser virtual-cathode plasma accelerator.

Author

Cowan TE, Fuchs J, Ruhl H, Kemp A, Audebert P, Roth M, Stephens R, Barton I, Blazevic A, Brambrink E, Cobble J, Fernández J, Gauthier JC, Geissel M, Hegelich M, Kaae J, Karsch S, Le Sage GP, Letzring S, Manclossi M, Meyroneinc S, Newkirk A, Pépin H, and Renard-LeGalloudec N

Abstract

The laminarity of high-current multi-MeV proton beams produced by irradiating thin metallic foils with ultraintense lasers has been measured. For proton energies >10 MeV, the transverse and longitudinal emittance are, respectively, <0.004 mm mrad and <10(-4) eV s, i.e., at least 100-fold and may be as much as 10(4)-fold better than conventional accelerator beams. The fast acceleration being electrostatic from an initially cold surface, only collisions with the accelerating fast electrons appear to limit the beam laminarity. The ion beam source size is measured to be <15 microm (FWHM) for proton energies >10 MeV.

Published

2004

48. Spatial uniformity of laser-accelerated ultrahigh-current MeV electron propagation in metals and insulators.

Author

Fuchs J, Cowan TE, Audebert P, Ruhl H, Gremillet L, Kemp A, Allen M, Blazevic A, Gauthier JC, Geissel M, Hegelich M, Karsch S, Parks P, Roth M, Sentoku Y, Stephens R, and Campbell EM

Abstract

The evolution of laser-generated MeV, MA electron beams propagating through conductors and insulators has been studied by comparing measurement and modeling of the distribution of MeV protons that are sheath accelerated by the propagated electrons. We find that electron flow through metals is uniform and can be laser imprinted, whereas propagation through insulators induces spatial disruption of the fast electrons. Agreement is found with material dependent modeling.

Published

2003

49. High-intensity laser induced ion acceleration from heavy-water droplets.

Author

Karsch S, Düsterer S, Schwoerer H, Ewald F, Habs D, Hegelich M, Pretzler G, Pukhov A, Witte K, and Sauerbrey R

Abstract

Fusion neutrons from a heavy water droplet target irradiated with laser pulses of 3 x 10(19) W/cm(2) and from a deuterated secondary target are observed by a time-of-flight (TOF) neutron spectrometer. The observed TOF spectrum can be explained by fusion of deuterium ions simultaneously originating from two different sources: ion acceleration in the laser focus by ponderomotively induced charge separation and target-normal sheath acceleration off the target rear surface. The experimental findings agree well with 3D particle-in-cell simulations.

Published

2003

50. Correction of strong phase and amplitude modulations by two deformable mirrors in a multistaged Ti:sapphire laser.

Author

Baumhacker H, Pretzler G, Witte KJ, Hegelich M, Kaluza M, Karsch S, Kudryashov A, Samarkin V, and Roukossouev A

Abstract

We describe a novel scheme consisting of two deformable bimorph mirrors that can free ultrashort laser pulses from simultaneously present strong wave-front distortions and intensity-profile modulations. This scheme is applied to the Max-Planck-Institut für Quantenoptik 10-TW Advanced Titanium-Sapphire Laser (ATLAS) facility. We demonstrate that with this scheme the focusability of the ATLAS pulses can be improved from 10(18) to 2x10(19) W/cm(2) without any penalty in recompression fidelity.

Published

2002