Your search keyword '"Alexander Andreev"' showing total 5 results

1. Generation of high-quality GeV-class electron beams utilizing attosecond ionization injection

Author

Zsolt Lécz, Alexander Andreev, Christos Kamperidis, and Nasr Hafz

Subjects

relativisitc electron beam, mono-energetic electron beam, low emittance, laser wave-guide, ionization injection, laser wakefield acceleration, Science, Physics, QC1-999

Abstract

Acceleration of electrons in laser-driven plasma wakefields has been extended up to the 10 GeV energy within a distance of 10s of centimeters. However, in applications, requiring small energy spread within the electron bunch, only a small portion of the bunch can be used and often the low-energy electrons represent undesired background in the spectrum. We present a compact and tunable scheme providing clean and mono-energetic electron bunches with less than one percent energy spread and with central energy on the GeV level. It is a two-step process consisting of ionization injection with attosecond pulses and acceleration in a capillary plasma wave-guide. Semi-analytical theory and particle-in-cell simulations are used to accurately model the injection and acceleration steps.

Published

2021

2. Corrigendum: Generation of high-quality GeV-class electron beams utilizing attosecond ionization injection (2021 New J. Phys. 23 043016)

Author

Zsolt Lécz, Alexander Andreev, C Kamperidis, and Nasr Hafz

Subjects

laser wakefield acceleration, capillary wave-guide, high power lasers, particle-in-cell method, Science, Physics, QC1-999

Abstract

Acceleration of electrons in laser-driven plasma wakefields has been extended up to the ∼8 GeV energy within a distance of tens of centimeters. However, in applications, requiring small energy spread within the electron bunch, only a small portion of the bunch can be used and often the low-energy electrons represent undesired background in the spectrum. We present a compact and tunable scheme providing clean and mono-energetic electron bunches with less than one percent energy spread and with central energy on the GeV level. It is a two-step process consisting of ionization injection with attosecond pulses and acceleration in a capillary plasma wave-guide. Semi-analytical theory and particle-in-cell simulations are used to accurately model the injection and acceleration steps.

Published

2021

3. Laser-induced extreme magnetic field in nanorod targets

Author

Zsolt Lécz and Alexander Andreev

Subjects

high current, strong magnetic fields, laser-matter interaction, numerical simulations, Science, Physics, QC1-999

Abstract

The application of nano-structured target surfaces in laser-solid interaction has attracted significant attention in the last few years. Their ability to absorb significantly more laser energy promises a possible route for advancing the currently established laser ion acceleration concepts. However, it is crucial to have a better understanding of field evolution and electron dynamics during laser-matter interactions before the employment of such exotic targets. This paper focuses on the magnetic field generation in nano-forest targets consisting of parallel nanorods grown on plane surfaces. A general scaling law for the self-generated quasi-static magnetic field amplitude is given and it is shown that amplitudes up to 1 MT field are achievable with current technology. Analytical results are supported by three-dimensional particle-in-cell simulations. Non-parallel arrangements of nanorods has also been considered which result in the generation of donut-shaped azimuthal magnetic fields in a larger volume.

Published

2018

4. Laser-driven ion acceleration using isolated mass-limited spheres

Author

Thomas Sokollik, K. Gorling, W. Sandner, Alexander Andreev, Peter V. Nickles, Sven Steinke, Tim Paasch-Colberg, U. Eichmann, and Matthias Schnürer

Subjects

Physics, General Physics and Astronomy, Plasma, Ion acceleration, Ion gun, Laser, Charged particle, law.invention, Ion, Acceleration, Physics::Plasma Physics, law, SPHERES, Atomic physics

Abstract

We report on our experiments on laser-driven ion acceleration using fully isolated mass-limited spheres with a diameter down to 8 μm for the first time. Two-dimensional (2D) particle-in-cell (PIC) and hydro-code simulations were used to show that the pre-plasma at both the front and rear sides of the target strongly affect the efficiency of the ion acceleration. The mechanism of the plasma flow around mass-limited targets has not yet been identified for laser-driven ion acceleration. Our models indicate that this effect is the cause of the observed limitation to the ion-beam energy in both previous experiments and in our own.

Published

2010

5. Divergence of fast ions generated by interaction of intense ultra-high contrast laser pulses with thin foils

Author

Anna Lévy, T. Ceccotti, K. Platonov, Ph. A. Martin, and Alexander Andreev

Subjects

Physics, High contrast, business.industry, General Physics and Astronomy, Ion acceleration, Laser, Ion, law.invention, Optics, Physics::Plasma Physics, law, Electric field, Physics::Accelerator Physics, Irradiation, Atomic physics, Divergence (statistics), business, FOIL method

Abstract

We propose an analytical model that analyzes the divergence of fast ion beams accelerated at the rear of thin foils irradiated with ultra-short intense laser pulses. We demonstrate the critical role played by the non-stationary character of the side components of the electric field, which is responsible for ion acceleration from the back of the foil. The model predictions are in very good agreement with 2D PIC simulations and with the experiments performed in the ultra-high-contrast regime as well.

Published

2010