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Your search keyword '"Gennadiy Bagdasarov"' showing total 13 results
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13 results on '"Gennadiy Bagdasarov"'

2. Plasma channel formation in the knife-like focus of laser beam

Author

G. Grittani, Michal Nevrkla, G. Korn, O. G. Olkhovskaya, Eric Esarey, V. A. Gasilov, Wim Leemans, Stepan Bulanov, L. V. N. Goncalves, N. A. Bobrova, C. M. Lazzarini, S. V. Bulanov, C. B. Schroeder, Pavel V. Sasorov, Gennadiy Bagdasarov, and Anthony Gonsalves

Subjects
Electromagnetic field, plasma simulation, Fluids & Plasmas, 01 natural sciences, Atomic, 010305 fluids & plasmas, law.invention, Optics, Particle and Plasma Physics, law, 0103 physical sciences, Focal length, Nuclear, Cylindrical lens, Magnetohydrodynamic drive, 010306 general physics, Physics, Quantum Physics, business.industry, Molecular, Plasma, Condensed Matter Physics, Laser, Pulse (physics), plasma dynamics, Plasma channel, business
Abstract

The plasma channel formation in the focus of a knife-like nanosecond laser pulse irradiating a gas target is studied theoretically, and in gas-dynamics computer simulations. The distribution of the electromagnetic field in the focus region, obtained analytically, is used to calculate the energy deposition in the plasma, which then is implemented in the magnetohydrodynamic computer code. The modelling of the channel evolution shows that the plasma profile, which can guide the laser pulse, is formed by the tightly focused short knife-like lasers. The results of the simulations show that a proper choice of the convergence angle of a knife-like laser beam (determined by the focal length of the last cylindrical lens), and laser pulse duration may provide a sufficient degree of azimuthal symmetry of the formed plasma channel.

Published
2020

3. Laser-heated Capillary Discharge Waveguides as Tunable Structures for Laser-Plasma Acceleration

Author

C. G. R. Geddes, G. Korn, C. V. Pieronek, Pavel V. Sasorov, Carl Schroeder, J. Daniels, V. A. Gasilov, Gennadiy Bagdasarov, Jianhui Bin, Wim Leemans, Stepan Bulanov, Carlo Benedetti, Anthony Gonsalves, J. van Tilborg, K. K. Swanson, N. A. Bobrova, and Eric Esarey

Subjects
Diffraction, Capillary action, Classical Physics, Fluids & Plasmas, Electron, 01 natural sciences, Atomic, 010305 fluids & plasmas, law.invention, Acceleration, Optics, Particle and Plasma Physics, law, Physics::Plasma Physics, 0103 physical sciences, Nuclear, ddc:530, 010306 general physics, Physics, Range (particle radiation), business.industry, Molecular, Condensed Matter Physics, Laser, Plasma acceleration, Magnetohydrodynamics, business, Astronomical and Space Sciences
Abstract

Physics of plasmas 27(9), 093101 (2020). doi:10.1063/5.0014961, Laser-heated capillary discharge waveguides are novel, low plasma density guiding structures able to guide intense laser pulses over many diffraction lengths and have recently enabled the acceleration of electrons to 7.8 GeV by using a laser-plasma accelerator (LPA). These devices represent an improvement over conventional capillary discharge waveguides, as the channel matched spot size and plasma density can be tuned independently of the capillary radius. This has allowed the guiding of petawatt-scale pulses focused to small spot sizes within large diameter capillaries, preventing laser damage of the capillary structure. High performance channel-guided LPAs require control of matched spot size and density, which experiments and simulations reported here show can be tuned over a wide range via initial discharge and laser parameters. In this paper, measurements of the matched spot size and plasma density in laser-heated capillary discharges are presented, which are found to be in excellent agreement with simulations performed using the MHD code MARPLE. Strategies for optimizing accelerator performance are identified based on these results., Published by American Institute of Physics, [S.l.]

Published
2020
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4. Simulations of plasma channel formation by knife-like nanosecond laser beam

Author

Aleksey Sergeevich Boldarev, Wim Leemans, Pavel V. Sasorov, Daniele Margarone, Tadz'o Levato, Carl Schroeder, Anthony Gonsalves, Mikhal Nevrkla, O. G. Olkhovskaya, Gennadiy Bagdasarov, Stepan Bulanov, V. A. Gasilov, Eric Esarey, S. V. Bulanov, G. Korn, and N. A. Bobrova

Subjects
Optics, Materials science, business.industry, Plasma channel, Nanosecond laser, business, Beam (structure)
Published
2018
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6. High Performance Computations for Short-Lived Plasmas

Author

V. A. Gasilov, O. G. Olkhovskaya, Yulia Sergeevna Sharova, and Gennadiy Bagdasarov

Subjects
Nonlinear system, Mass distribution, Multiphysics, Computation, Scalability, Radiative transfer, Plasma, Supercomputer, Computational science
Abstract

Supercomputer simulations are of fundamental importance for understanding the physics of nonlinear processes in high temperature pulse plasma. The development of predictive codes is an urgent problem in computational plasma physics, as well as many other fields of science. Radiative magneto-hydrodynamics 3D code MARPLE is a full-scale multiphysics research code using the state-of-the-art physics, mathematics, and numerics as well as the up-to-date high performance computing functionality. Scalability study demonstrated that the code can fit existing petaFLOPS supercomputers as well as next-generation exaFLOPS ones. The code is currently used for multiphysics simulations, specifically for high energy density plasma in pulsed-power facilities. Compression of a wire array by a high-current discharge is a valuable tool for fundamental study of matter in extreme states. Different configurations of wire arrays were investigated numerically. A series of high resolution computations helped to create a very compact spherical bright radiation source using dedicated design of the electrodes, the wire array, and the mass distribution along the wires.

Published
2019
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7. Eight GeV electrons from a laser-heated capillary discharge plasma (Conference Presentation)

Author

Vladimir A. Gasilov, C. V. Pieronek, Anthony Gonsalves, Wim Leemans, J. Daniels, Pavel V. Sasorov, Sven Steinke, Carlo Benedetti, K. K. Swanson, Stepan Bulanov, Kei Nakamura, N. A. Bobrova, Carl Schroeder, Tim de Raadt, Gennadiy Bagdasarov, Eric Esarey, and Liona Fan-Chiang

Subjects
Materials science, Capillary action, law, Plasma, Electron, Atomic physics, Presentation (obstetrics), Laser, law.invention
Published
2019
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8. Laser beam coupling with capillary discharge plasma for laser wakefield acceleration applications

Author

Hann-Shin Mao, Carl Schroeder, Gennadiy Bagdasarov, Eric Esarey, A. S. Boldarev, Anthony Gonsalves, Stepan Bulanov, O. G. Olkhovskaya, Pavel V. Sasorov, Daniele Margarone, Carlo Benedetti, Jeroen van Tilborg, Wim Leemans, V. A. Gasilov, Tadzio Levato, and Georg Korn

Subjects
Electron density, Materials science, Capillary action, Classical Physics, Fluids & Plasmas, FOS: Physical sciences, Electron, 01 natural sciences, Atomic, 010305 fluids & plasmas, law.invention, Acceleration, Optics, Particle and Plasma Physics, law, Physics::Plasma Physics, physics.plasm-ph, 0103 physical sciences, Nuclear, 010306 general physics, Coupling, Waves in plasmas, business.industry, Molecular, Plasma, Condensed Matter Physics, Laser, Physics - Plasma Physics, Plasma Physics (physics.plasm-ph), business, Astronomical and Space Sciences
Abstract

One of the most robust methods, demonstrated up to date, of accelerating electron beams by laser-plasma sources is the utilization of plasma channels generated by the capillary discharges. These channels, i.e., plasma columns with a minimum density along the laser pulse propagation axis, may optically guide short laser pulses, thereby increasing the acceleration length, leading to a more efficient electron acceleration. Although the spatial structure of the installation is simple in principle, there may be some important effects caused by the open ends of the capillary, by the supplying channels etc., which require a detailed 3D modeling of the processes taking place in order to get a detailed understanding and improve the operation. However, the discharge plasma, being one of the most crucial components of the laser-plasma accelerator, is not simulated with the accuracy and resolution required to advance this promising technology. In the present work, such simulations are performed using the code MARPLE. First, the process of the capillary filling with a cold hydrogen before the discharge is fired, through the side supply channels is simulated. The main goal of this simulation is to get a spatial distribution of the filling gas in the region near the open ends of the capillary. A realistic geometry is used for this and the next stage simulations, including the insulators, the supplying channels as well as the electrodes. Second, the simulation of the capillary discharge is performed with the goal to obtain a time-dependent spatial distribution of the electron density near the open ends of the capillary as well as inside the capillary. Finally, to evaluate effectiveness of the beam coupling with the channeling plasma wave guide and electron acceleration, modeling of laser-plasma interaction was performed with the code INF&RNO, 11 pages, 9 figures

Published
2017

9. Plasma formation in noncircular capillary discharges (Conference Presentation)

Author

Stepan Bulanov, A. S. Boldarev, Danila Khikhlukha, Gennadiy Bagdasarov, S. V. Bulanov, Anthony Gonsalves, Pavel V. Sasorov, Georg Korn, Wim Leemans, Carlo Benedetti, Daniele Margarone, O. G. Olkhovskaya, and V. A. Gasilov

Subjects
Physics, law, Capillary action, Plasma diagnostics, Plasma, Electron, Atomic physics, Magnetohydrodynamics, Plasma acceleration, Laser, Waveguide, law.invention
Abstract

For several decades the capillary discharges have been under intensive investigations due to various promising applications, e.g. for the laser electron accelerators as well as for the X-ray lasers [1,2]. A major portion of the experiments were done with circular cross-section capillaries. An appropriate theoretical and numerical study of circular capillaries can be greatly simplified to a 1D model [3] assuming rotational and axial symmetries of the plasma flow in a long thin channel. On the other hand, studying capillaries with non-circular cross-section [4], which have been attracting substantially less attention, requires more complicated 2D models. Such capillaries, for example, square one, possess several advantages related to their fabrication as well as for plasma diagnostics The aim of our work is to compare the plasma density and temperature distributions formed at the quasistationary stage of the discharge. We present the results of MHD simulations of hydrogen-filled capillary discharges with circular and rectangular cross-sections under almost the same conditions characterizing the initial configurations and the external electric circuit. The simulation parameters are choosen to correspond to the capillary discharge based waveguide for the laser wakefield accelerator [5]. Bibliography [1] Leemans W. P. et al 2014 Phys. Rev. Lett. 113 245002 [2] Benware B. R. et al 1998 Phys. Rev. Lett. 81 5804 [3] Bobrova N. A. et al 2001 Phys. Rev. E 65 016407 [4] Gonsalves A. J. et al 2007 Phys. Rev. Lett. 98 025002 [5] Esarey E. et al 2009 Rev. Mod. Phys. 81 1229

Published
2017
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10. 3D MHD simulation of capillary discharge for the BELLA project

Author

Stepan Bulanov, C. G. R. Geddes, A. S. Boldarev, Hann-Shin Mao, O. G. Olkhovskaya, Wim Leemans, Carl Schroeder, V. A. Gasilov, Eric Esarey, Pavel V. Sasorov, and Gennadiy Bagdasarov

Subjects
Physics, Waves in plasmas, business.industry, Plasma, Plasma acceleration, Laser, Pulse (physics), law.invention, Optics, Physics::Plasma Physics, Capillary Plasma, law, Physics::Accelerator Physics, Plasma channel, Electromagnetic electron wave, business
Abstract

The project BELLA (LBNL, USA) is aimed to create an experimental facility for further advancing the development of laser-driven electron acceleration1. BELLA's unique attribute is the ability to use laser light to accelerate an electron beam up to 10 GeV level in a comparatively short distance of approximately one meter. The acceleration takes place during the propagation of a high power femtosecond laser pulse in the plasma formed in a capillary discharge. This capillary plasma forms a plasma channel able to guide the laser pulse, which in its turn forms a plasma wake wave that accelerates the injected electrons.

Published
2015
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11. Plasma equilibrium inside various cross-section capillary discharges

Author

Wim Leemans, Gennadiy Bagdasarov, O. G. Olkhovskaya, Carl Schroeder, Stepan Bulanov, Eric Esarey, Pavel V. Sasorov, Daniele Margarone, A. S. Boldarev, Jeroen van Tilborg, Anthony Gonsalves, V. A. Gasilov, Samuel K. Barber, Tadzio Levato, Georg Korn, and Sergei V. Bulanov

Subjects
Materials science, Capillary action, Classical Physics, Fluids & Plasmas, FOS: Physical sciences, Atomic, 01 natural sciences, Molecular physics, 010305 fluids & plasmas, law.invention, Physics::Fluid Dynamics, Cross section (physics), Particle and Plasma Physics, Physics::Plasma Physics, law, physics.plasm-ph, 0103 physical sciences, Nuclear, Magnetohydrodynamic drive, 010306 general physics, Molecular, Plasma, Condensed Matter Physics, Physics - Plasma Physics, Symmetry (physics), Magnetic field, Plasma Physics (physics.plasm-ph), Cathode ray, Waveguide, Astronomical and Space Sciences
Abstract

Plasma properties inside a hydrogen-filled capillary discharge waveguide were modeled with dissipative magnetohydrodynamic simulations to enable analysis of capillaries of circular and square cross-sections implying that square capillaries can be used to guide circularly-symmetric laser beams. When the quasistationary stage of the discharge is reached, the plasma and temperature in the vicinity of the capillary axis has almost the same profile for both the circular and square capillaries. The effect of cross-section on the electron beam focusing properties were studied using the simulation-derived magnetic field map. Particle tracking simulations showed only slight effects on the electron beam symmetry in the horizontal and diagonal directions for square capillary., 6 pages, 10 figures

Published
2017
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12. Experimental and numerical study of a wire-explosion-pos plasma dynamics

Author

Yuriy G. Kalinin, S. I. Tkachenko, Vladimir A. Gasilov, O. G. Olkhovskaya, Alexander A. Shvedov, Gennadiy Bagdasarov, Georgiy I. Dolgachev, and Konstantin V. Chukbar

Subjects
Physics, Amplitude, Hall effect, Rise time, Plasma, Mechanics, Magnetohydrodynamics, Current (fluid), Coaxial, Magnetic field
Abstract

A design of fast current switch using wire explosion is a problem of studying by our team experimentally and numerically. The main unit of the experimental setup represents itself two coaxial cylindrical electrodes connected by a thin single wire which is exploded by the current pulse. In the experiments a current with the amplitude up to 80 kA and rise time of 7 μs flowing through the 4-mm tungsten wire. Plasma generated by exploded wire fills the inter-electrode space "circularly" owing to the interaction with magnetic field (up to 30 kG) produced by an external source and directed along the electrodes. The setup construction allows us to change the amplitude of current flowing between the electrodes and to measure the total resistance of inter-electrode volume. Therefore we can study a plasma dynamics by varying the current value. In our experiments the current amplitude is changed in a rather wide range of 10–80 kA, and a current rise time is changed from 109 to 1010 A/s. The experimental data are compared with those obtained via computer simulation carried out by means of the radiative magnetohydrodynamic code MARPLE3D (KIAM RAS). W e studied 3D plasma dynamics numerically (i) at a stage of a wire explosion and filling of the inter-electrode gap by plasma, and (ii) a stage of a plasma switch functioning. Numerical simulations allow to estimate a time which need to fill the volume between the coaxial electrodes with the plasma generated from the wire and to study the switch dynamics dependence on the hydromagnetic instability as well as on the Hall effect. The numerical data correlates with experimental results. The main problems we discuss are: (i) what are possible reasons of the rapid decreasing of the switch resistance and (ii) how we can maintain an appropriately high resistance of the switch during the time needed for its applications.

Published
2013
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