Your search keyword '"TIKHONCHUK, V. T."' showing total 15 results

1. Target charging in short-pulse-laser-plasma experiments.

Author

Dubois JL, Lubrano-Lavaderci F, Raffestin D, Ribolzi J, Gazave J, Compant La Fontaine A, d'Humières E, Hulin S, Nicolaï P, Poyé A, and Tikhonchuk VT

Subjects

Computer Simulation, Electron Transport, Electrons, Lasers, Models, Chemical, Plasma Gases chemistry, Plasma Gases radiation effects

Abstract

Interaction of high-intensity laser pulses with solid targets results in generation of large quantities of energetic electrons that are the origin of various effects such as intense x-ray emission, ion acceleration, and so on. Some of these electrons are escaping the target, leaving behind a significant positive electric charge and creating a strong electromagnetic pulse long after the end of the laser pulse. We propose here a detailed model of the target electric polarization induced by a short and intense laser pulse and an escaping electron bunch. A specially designed experiment provides direct measurements of the target polarization and the discharge current in the function of the laser energy, pulse duration, and target size. Large-scale numerical simulations describe the energetic electron generation and their emission from the target. The model, experiment, and numerical simulations demonstrate that the hot-electron ejection may continue long after the laser pulse ends, enhancing significantly the polarization charge.

Published

2014

2. X-ray amplification from a Raman free-electron laser.

Author

Andriyash IA, d'Humières E, Tikhonchuk VT, and Balcou P

Subjects

Oscillometry instrumentation, Oscillometry methods, Scattering, Radiation, Spectrum Analysis, Raman instrumentation, Electrons, Lasers, Models, Theoretical, Spectrum Analysis, Raman methods, X-Rays

Abstract

We demonstrate that a mm-scale free-electron laser can operate in the x-ray range, in the interaction between a moderately relativistic electron bunch, and a transverse high intensity optical lattice. The corrugated light-induced ponderomotive potential acts simultaneously as a guide and as a low-frequency wiggler, triggering stimulated Raman scattering. The gain law in the small signal regime is derived in a fluid approach, and confirmed from particle-in-cell simulations. We describe the nature of bunching, and discuss the saturation properties. The resulting all-optical Raman x-ray laser opens perspectives for ultracompact coherent light sources up to the hard x-ray range.

Published

2012

3. Studies of laser-plasma interaction physics with low-density targets for direct-drive inertial confinement fusion on the Shenguang III prototype.

Author

Tikhonchuk, V. T., Gong, T., Jourdain, N., Renner, O., Condamine, F. P., Pan, K. Q., Nazarov, W., Hudec, L., Limpouch, J., Liska, R., Krůs, M., Wang, F., Yang, D., Li, S. W., Li, Z. C., Guan, Z. Y., Liu, Y. G., Xu, T., Peng, X. S., and Liu, X. M.

Subjects

LASER-plasma interactions, INERTIAL confinement fusion, IONIZATION energy, RAMAN scattering, ELECTRONS

Abstract

The physics of laser-plasma interaction is studied on the Shenguang III prototype laser facility under conditions relevant to inertial confinement fusion designs. A sub-millimeter-size underdense hot plasma is created by ionization of a low-density plastic foam by four high-energy (3.2 kJ) laser beams. An interaction beam is fired with a delay permitting evaluation of the excitation of parametric instabilities at different stages of plasma evolution. Multiple diagnostics are used for plasma characterization, scattered radiation, and accelerated electrons. The experimental results are analyzed with radiation hydrodynamic simulations that take account of foam ionization and homogenization. The measured level of stimulated Raman scattering is almost one order of magnitude larger than that measured in experiments with gasbags and hohlraums on the same installation, possibly because of a greater plasma density. Notable amplification is achieved in high-intensity speckles, indicating the importance of implementing laser temporal smoothing techniques with a large bandwidth for controlling laser propagation and absorption. [ABSTRACT FROM AUTHOR]

Published

2021

4. Laser plasma physics in shock ignition -- transition from collisional to collisionless absorption.

Author

Klimo, O., Tikhonchuk, V. T., Ribeyre, X., Schurtz, G., Riconda, C., Limpouch, J., and Weber, S.

Subjects

*INERTIAL confinement fusion, *LASER pulses, *COLLISIONS (Physics), *BRILLOUIN scattering, *RAMAN scattering, *ELECTRONS

Abstract

Shock Ignition is considered as a relatively robust and efficient approach to inertial confinement fusion. A strong converging shock, which is used to ignite the fuel, is launched by a high power laser pulse with intensity in the range of 1015 - 1016 W/cm² (at the wavelength of 351 nm). In the lower end of this intensity range the interaction is dominated by collisions while the parametric instabilities are playing a secondary role. This is manifested in a relatively weak reflectivity and efficient electron heating. The interaction is dominated by collective effects at the upper edge of the intensity range. The stimulated Brillouin and Raman scattering (SBS and SRS respectively) take place in a less dense plasma and cavitation provides an efficient collisionless absorption mechanism. The transition from collisional to collisionless absorption in laser plasma interactions at higher intensities is studied here with the help of large scale one-dimensional Particle-in-Cell (PIC) simulations. The relation between the collisional and collisionless processes is manifested in the energy spectrum of electrons transporting the absorbed laser energy and in the spectrum of the reflected laser light. [ABSTRACT FROM AUTHOR]

Published

2013

5. Multi-dimensional PIC-simulations of parametric instabilities for shock-ignition conditions.

Author

Riconda, C., Weber, S., Klimo, O., Héron, A., and Tikhonchuk, V. T.

Subjects

LASER plasmas, LASER beams, PLASMA gases, PLASMA waves, ELECTRONS

Abstract

Laser-plasma interaction is investigated for conditions relevant for the shock-ignition (SI) scheme of inertial confinement fusion using two-dimensional particle-in-cell (PIC) simulations of an intense laser beam propagating in a hot, large-scale, non-uniform plasma. The temporal evolution and interdependence of Raman- (SRS), and Brillouin- (SBS), side/backscattering as well as Two-Plasmon-Decay (TPD) are studied. TPD is developing in concomitance with SRS creating a broad spectrum of plasma waves near the quarter-critical density. They are rapidly saturated due to plasma cavitation within a few picoseconds. The hot electron spectrum created by SRS and TPD is relatively soft, limited to energies below one hundred keV. [ABSTRACT FROM AUTHOR]

Published

2013

6. The Radiation Reaction Effect on Electrons at Super-High Laser Intensities with Application to Ion Acceleration.

Author

Naumova, N. M., Sokolov, I. V., Tikhonchuk, V. T., Schlegel, T., Nees, J. A., Labaune, C., Yanovsky, V. P., and Mourou, G. A.

Subjects

RADIATION, SIMULATION methods & models, LASER beams, ELECTRONS, POSITRONS

Abstract

At super-high laser intensities the radiation back reaction on electrons becomes so significant that its influence on laser-plasma interaction cannot be neglected while simulating these processes with particle-in-cell (PIC) codes. We discuss a way of taking the radiation effect on electrons into account and extracting spatial and frequency distributions of the generated high-frequency radiation. We also examine ponderomotive acceleration of ions in the double layer created by strong laser pulses and we compare an analytical description with PIC simulations as well. We discuss: (1) non-stationary features found in simulations, (2) electron cooling effect due to radiation losses, and (3) the limits of the analytical model. [ABSTRACT FROM AUTHOR]

Published

2009

7. Effect of the laser pulse temporal shape on the hole boring efficiency.

Author

Mironov, V., Zharova, N., d'Humières, E., Capdessus, R., and Tikhonchuk, V. T.

Subjects

LASER pulses, SIMULATION methods & models, ELECTRONS, IONS, ELECTRON energy states, MATHEMATICAL optimization

Abstract

Laser hole boring is a process of ion expulsion from the path of an intense laser beam under the effect of the ponderomotive force. It is considered as a method for more efficient electron energy deposition in fast ignition of inertial fusion reactions. Analysis of the electron dynamics on the laser-plasma interface shows that the hole boring efficiency can be significantly enhanced by an appropriate temporal shaping of the laser pulse. The pulse shape optimization is carried out with a newly developed fast quasi-neutral particle-in-cell (PIC) code and verified with the full PIC simulations. [ABSTRACT FROM AUTHOR]

Published

2012

8. Relativistic laser piston model: Ponderomotive ion acceleration in dense plasmas using ultraintense laser pulses.

Author

Schlegel, T., Naumova, N., Tikhonchuk, V. T., Labaune, C., Sokolov, I. V., and Mourou, G.

Subjects

LASER beams, ELECTRONS, CATHODE rays, IONS, PARTICLES (Nuclear physics), FLUCTUATIONS (Physics)

Abstract

Laser ponderomotive force at superhigh intensities provides an efficient ion acceleration in bulk dense targets and evacuates a channel enabling further laser beam propagation. The developed quasistationary model of a laser piston—a double layer structure supported by the radiation pressure—predicts the general parameters of the acceleration process in homogeneous and inhomogeneous overdense plasmas. Particle-in-cell simulations confirm the estimated characteristics in a wide range of laser intensities and ion densities and show advantages of circularly polarized laser pulses. Two nonstationary effects are identified in the simulations. First, oscillations of the piston velocity and of the thickness of the ion charge separation layer broaden the energy spectrum of accelerated ions. Second, the electrons accelerated toward the incoming laser wave emit strong high-frequency radiation, enabling a cooling effect, which helps to sustain high charge neutrality in the piston and to maintain an efficient ion acceleration. [ABSTRACT FROM AUTHOR]

Published

2009

9. Effect of pressure relaxation during the laser heating and electron–ion relaxation stages.

Author

Chimier, B., Tikhonchuk, V. T., and Hallo, L.

Subjects

*RELAXATION (Nuclear physics), *ALUMINUM, *LASER ablation, *ULTRASHORT laser pulses, *ELECTRONS, *IONS

Abstract

The multi-phase equation of state by Bushman et al. (Sov. Tech. Rev. 5:1–44, ) is modified to describe states with different electron and ion temperatures and it is applied to the non-equilibrium evolution of an aluminum sample heated by a subpicosecond laser pulse. The sample evolution is described by the two-temperature model for the electron and ion temperatures, while the pressure and density are described by a simplified relaxation equation. The pressure relaxation in the heating stage reduces the binding energy and facilitates the electron-driven ablation. The model is applied to estimate the ablation depth of an Al target irradiated by a subpicosecond laser pulse. It improves the agreement with the experimental data and provides a new explanation of the ablation process. [ABSTRACT FROM AUTHOR]

Published

2008

10. Anisotropic instability in a laser heated plasma.

Author

Sangam, A., Morreeuw, J.-P., and Tikhonchuk, V. T.

Subjects

LASER plasmas, ELECTRONS, ELECTROMAGNETIC waves, MAGNETIC fields, ELECTRON distribution

Abstract

The theory of the Weibel instability induced by the inverse Bremsstrahlung absorption of a laser light in an underdense plasma is revisited. It is shown that previous analyses have strongly overestimated the effect by neglecting the stabilizing term related to the interaction of the generated quasistatic magnetic field with the laser-heated electrons. The revised model leads to a reduction of the growth rate by more than a factor of 10, to strong reduction of the domain of unstable modes and to inversion of the direction of the unstable wave vectors in the long wavelength limit. The consequences of this instability on the laser plasma interaction are also discussed. [ABSTRACT FROM AUTHOR]

Published

2007

11. Fast electrons from electron-ion collisions in strong laser fields.

Author

Kull, H.-J. and Tikhonchuk, V. T.

Subjects

*PARTICLES (Nuclear physics), *ELECTRONS, *COLLISIONS (Nuclear physics), *LASERS, *SPECTRUM analysis, *ELECTRIC fields

Abstract

Electron-ion collisions in the presence of a strong laser field lead to a distribution of fast electrons with maximum energy Emax=(k0+2v0)2/2(a.u.), where k0 is the impact and v0 the quiver velocity of the electron. The energy spectrum is calculated by two approaches: (1) The time-dependent Schrödinger equation is numerically solved for wave packet scattering from a one-dimensional softcore Coulomb potential. Multiphoton energy spectra are obtained demonstrating a separation of the energy spectrum into an exponential distribution for transmission and a plateau distribution for reflection. (2) The energy spectrum is analytically calculated in the framework of classical instantaneous Coulomb collisions with random impact parameters and random phases of the laser field. An exact solution for the energy spectrum is obtained from which the fraction of fast electrons in the plateau region can be estimated. [ABSTRACT FROM AUTHOR]

Published

2005

12. Ion acceleration in expanding multispecies plasmas.

Author

Bychenkov, V. Yu., Novikov, V. N., Batani, D., Tikhonchuk, V. T., and Bochkarev, S. G.

Subjects

IONS, ELECTRONS, PLASMA waves, ULTRASHORT laser pulses, MAGNETIC fields, LANDAU damping, MAGNETOHYDRODYNAMIC waves

Abstract

The acceleration of light and heavy ions in an expanding plasma slab with hot electrons produced by an intense and short laser pulse is studied by using the hybrid Boltzmann–Vlasov–Poisson model. Spatial profiles, energy distributions, and maximum energies of accelerated ions are analyzed in function of the plasma and hot electron parameters. The crucial parameter for ion acceleration is found to be the ratio of the foil thickness to the hot electron Debye length. Special attention is paid to characterization of protons accelerated from a thin hydrogenated layer at the target surface. The evolution of the proton spectrum is studied for the cases of isothermal and cooling hot electron distributions. The obtained dependencies of the ion energy on the pulse duration and the target characteristics allow one to define the optimal conditions for the ion acceleration with lasers. © 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004

13. Characterization of suprathermal electrons inside a laser accelerated plasma via highly-resolved K⍺-emission.

Author

Šmíd, M., Renner, O., Colaitis, A., Tikhonchuk, V. T., Schlegel, T., and Rosmej, F. B.

Subjects

ELECTRONS, LASER plasmas, LASER-plasma interactions, INERTIAL confinement fusion, X-ray spectroscopy

Abstract

Suprathermal electrons are routinely generated in high-intensity laser produced plasmas via instabilities driven by non-linear laser-plasma interaction. Their accurate characterization is crucial for the performance of inertial confinement fusion as well as for performing experiments in laboratory astrophysics and in general high-energy-density physics. Here, we present studies of non-thermal atomic states excited by suprathermal electrons in kJ-ns-laser produced plasmas. Highly spatially and spectrally resolved X-ray emission from the laser-deflected part of the warm dense Cu foil visualized the hot electrons. A multi-scale two-dimensional hydrodynamic simulation including non-linear laser-plasma interactions and hot electron propagation has provided an input for ab initio non-thermal atomic simulations. The analysis revealed a significant delay between the maximum of laser pulse and presence of suprathermal electrons. Agreement between spectroscopic signatures and simulations demonstrates that combination of advanced high-resolution X-ray spectroscopy and non-thermal atomic physics offers a promising method to characterize suprathermal electrons inside the solid density matter. Suprathermal electrons in laser-generated plasmas are potentially useful in many plasma environments. Here the authors show the characterization of suprathermal electrons in laser-generated Cu plasma using a high-resolution X-ray spectroscopy combined with hydrodynamic and atomic modeling. [ABSTRACT FROM AUTHOR]

Published

2019

14. A reduced model for relativistic electron beam transport in solids and dense plasmas.

Author

Touati, M, Feugeas, J-L, Nicolaï, Ph, Santos, J J, Gremillet, L, and Tikhonchuk, V T

Subjects

ELECTRON beams, DENSE plasmas, ANGULAR momentum (Mechanics), PLASMONS (Physics), IONS, ELECTRONS

Abstract

A hybrid reduced model for relativistic electron beam transport based on the angular moments of the relativistic kinetic equation with a special closure is presented. It takes into account collective effects with the self-generated electromagnetic fields as well as collisional effects with the slowing down of the relativistic electrons by plasmons, bound and free electrons and their angular scattering on both ions and electrons. This model allows for fast computations of relativistic electron beam transport while describing their energy distribution evolution. Despite the loss of information concerning the angular distribution of the electron beam, the model reproduces analytical estimates in the academic case of a monodirectional and monoenergetic electron beam propagating through a warm and dense plasma and hybrid particle-in-cell simulation results in a realistic laser-generated electron beam transport case. [ABSTRACT FROM AUTHOR]

Published

2014

15. Gain of electron orbital angular momentum in a direct laser acceleration process.

Author

Nuter, R., Korneev, Ph., Dmitriev, E., Thiele, I., and Tikhonchuk, V. T.

Subjects

*ANGULAR momentum (Mechanics), *LAGUERRE-Gaussian beams, *ANGULAR velocity, *LASERS, *ELECTRONS, *LASER plasmas, *VECTOR beams

Abstract

Three-dimensional "particle in cell" simulations show that a quasistatic magnetic field can be generated in a plasma irradiated by a linearly polarized Laguerre-Gauss beam with a nonzero orbital angular momentum (OAM). Perturbative analysis of the electron dynamics in the low intensity limit and detailed numerical analysis predict a laser to electrons OAM transfer. Plasma electrons gain angular velocity thanks to the dephasing process induced by the combined action of the ponderomotive force and the laser induced-radial oscillation. Similar to the "direct laser acceleration," where Gaussian laser beams transmit part of its axial momentum to electrons, Laguerre-Gaussian beams transfer a part of their orbital angular momentum to electrons through the dephasing process. [ABSTRACT FROM AUTHOR]

Published

2020