Your search keyword '"S, Dobosz"' showing total 6 results

1. Gas cell density characterization for laser wakefield acceleration.

Author

Audet, T.L., Lee, P., Maynard, G., Dufrénoy, S. Dobosz, Maitrallain, A., Bougeard, M., Monot, P., and Cros, B.

Subjects

*LASER plasma accelerators, *PLASMA accelerators, *LASER beams, *ELECTRON beams, *LASER plasmas

Abstract

Abstract In the design of laser plasma electron injectors for multi-stage laser driven wakefield accelerators, the control of plasma density is a key element to stabilize the acceleration process. A cell with variable parameters is used to confine the gas and tailor the density profile. The gas filling process was characterized both experimentally and by fluid simulations. Results show a good agreement between experiments and simulations. Simulations were also used to study the effect of each of the gas cell parameters on the density distribution and show the possibility to finely control the density profile. Highlights • A variable parameter gas cell was designed for laser wakefield electron acceleration. • The density in the gas cell was characterized both experimentally and numerically. • Numerical and experimental results are in very good agreement. • A parametric study was performed with fluid simulations. • The density profile can be precisely tailored by varying the cell parameters. [ABSTRACT FROM AUTHOR]

Published

2018

2. Effects of the dopant concentration in laser wakefield and direct laser acceleration of electrons.

Author

González, I. Gallardo, Ekerfelt, H., Hansson, M., Audet, T. L., Aurand, B., Desforges, F. G., Dufrénoy, S. Dobosz, Persson, A., Davoine, X., Wahlström, C-G, Cros, B., and Lundh, O.

Subjects

*DOPING agents (Chemistry), *ELECTRON scattering, *PLASMA waves, *ACOUSTIC surface waves, *CRYSTAL structure

Abstract

In this work, we experimentally study the effects of the nitrogen concentration in laser wakefield acceleration of electrons in a gas mixture of hydrogen and nitrogen. A 15 TWpeak power laser pulse is focused to ionize the gas, excite a plasma wave and accelerate electrons up to 230 MeV. We find that at dopant concentrations above 2% the total divergence of the electrons is increased and the high energy electrons are emitted preferentially with an angle of ±6 mrad, leading to a forked spatio-spectral distribution associated to direct laser acceleration (DLA). However, electrons can gain more energy and have a divergence lower than 4 mrad for concentrations below 0.5% and the same laser and plasma conditions. Particle-in-cell simulations show that for dopant concentrations above 2%, the amount of trapped charge is large enough to significantly perturb the plasma wave, reducing the amplitude of the longitudinal wakefield and suppressing other trapping mechanisms. At high concentrations the number of trapped electrons overlapping with the laser fields is increased, which rises the amount of charge affected by DLA. We conclude that the dopant concentration affects the quantity of electrons that experience significant DLA and the beam loading of the plasma wave driven by the laser pulse. These two mechanisms influence the electrons final energy, and thus the dopant concentration should be considered as a factor for the optimization of the electron beam parameters. [ABSTRACT FROM AUTHOR]

Published

2018

3. Electron injector for compact staged high energy accelerator.

Author

Audet, T.L., Desforges, F.G., Maitrallain, A., Dufrénoy, S. Dobosz, Bougeard, M., Maynard, G., Lee, P., Hansson, M., Aurand, B., Persson, A., González, I. Gallardo, Monot, P., Wahlström, C.-G., Lundh, O., and Cros, B.

Subjects

*ELECTRON beams, *PARTICLE accelerators, *LASER plasma accelerators, *NUCLEAR physics experiments, *FLUCTUATIONS (Physics)

Abstract

An electron injector for multi-stage laser wakefield experiments is presented. It consists of a variable length gas cell of small longitudinal dimension ( ⩽ 10 mm ). The gas filling process in this cell was characterized both experimentally and with fluid simulation. Electron acceleration experiments were performed at two different laser facilities. Results show low divergence and low pointing fluctuation electron bunches suitable for transport to a second stage, and a peaked energy distribution suitable for injection into the second stage wakefield accelerator. [ABSTRACT FROM AUTHOR]

Published

2016

4. Investigation of ionization-induced electron injection in a wakefield driven by laser inside a gas cell.

Author

Audet, T. L., Hansson, M., Lee, P., Desforges, F. G., Maynard, G., Dufrénoy, S. Dobosz, Lehe, R., Vay, J.-L., Aurand, B., Persson, A., González, I. Gallardo, Maitrallain, A., Monot, P., Wahlström, C.-G., Lundh, O., and Cros, B.

Subjects

*IONIZATION (Atomic physics), *GAS analysis, *ELECTRONS, *LASERS, *DENSITY

Abstract

Ionization-induced electron injection was investigated experimentally by focusing a driving laser pulse with a maximum normalized potential of 1.2 at different positions along the plasma density profile inside a gas cell, filled with a gas mixture composed of 99%H2 þ 1%N2. Changing the laser focus position relative to the gas cell entrance controls the accelerated electron bunch properties, such as the spectrum width, maximum energy, and accelerated charge. Simulations performed using the 3D particle-in-cell code WARP with a realistic density profile give results that are in good agreement with the experimental ones. The interest of this regime for optimizing the bunch charge in a selected energy window is discussed. [ABSTRACT FROM AUTHOR]

Published

2016

5. Non-invasive characterisation of a laser-driven positron beam.

Author

A Alejo, G M Samarin, J Warwick, C McCluskey, G Cantono, T Ceccotti, S Dobosz Dufrénoy, P Monot, and G Sarri

Subjects

*POSITRON beams, *POSITRONIUM, *ELECTRON beams, *POSITRONS, *ELECTRONS

Abstract

We report on an indirect and non-invasive method to simultaneously characterise the energy-dependent emittance and source size of ultra-relativistic positron beams generated during the propagation of a laser-wakefield accelerated electron beam through a high-Z converter target. The strong correlation of the geometrical emittance of the positrons with that of the scattered electrons allows the former to be inferred, with high accuracy, from monitoring the latter. The technique has been tested in a proof-of-principle experiment where, for 100 MeV positrons, we infer geometrical emittances and source sizes of the order of 3 µm and 150 µm, respectively. This is consistent with the numerically predicted possibility of achieving sub-µm geometrical emittances and micron-scale source sizes at the GeV level. [ABSTRACT FROM AUTHOR]

Published

2020

6. Localization of ionization-induced trapping in a laser wakefield accelerator using a density down-ramp.

Author

M Hansson, T L Audet, H Ekerfelt, B Aurand, I Gallardo González, F G Desforges, X Davoine, A Maitrallain, S Reymond, P Monot, A Persson, S Dobosz Dufrénoy, C-G Wahlström, B Cros, and O Lundh

Subjects

*LASER plasma accelerators, *ELECTRON impact ionization, *ELECTRON energy states, *PLASMA density, *ELECTRON traps

Abstract

We report on a study on controlled trapping of electrons, by field ionization of nitrogen ions, in laser wakefield accelerators in variable length gas cells. In addition to ionization-induced trapping in the density plateau inside the cells, which results in wide, but stable, electron energy spectra, a regime of ionization-induced trapping localized in the density down-ramp at the exit of the gas cells, is found. The resulting electron energy spectra are peaked, with 10% shot-to-shot fluctuations in peak energy. Ionization-induced trapping of electrons in the density down-ramp is a way to trap and accelerate a large number of electrons, thus improving the efficiency of the laser-driven wakefield acceleration. [ABSTRACT FROM AUTHOR]

Published

2016