Shock-Wave Pressure Transfer to a Solid Target with Porous Absorber of High-Power Laser Pulse

Results of experiments aimed at amplification of the pressure of laser-induced shock wave on the passage from low- to high-density target material via vacuum gap are presented. During the action of nanosecond laser pulse of terawatt power on plane composite targets comprising a layer of laser radiat...

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Bibliographic Details
Published in:Journal of experimental and theoretical physics 2022-03, Vol.134 (3), p.340-349
Main Authors: Belov, I. A., Bel’kov, S. A., Bondarenko, S. V., Vergunova, G. A., Voronin, A. Yu, Garanin, S. G., Golovkin, S. Yu, Gus’kov, S. Yu, Demchenko, N. N., Derkach, V. N., Dmitriev, E. O., Zmitrenko, N. V., Ilyushechkina, A. V., Kravchenko, A. G., Kuz’min, I. V., Kuchugov, P. A., Myusova, A. E., Rogachev, V. G., Rukavishnikov, A. N., Solomatina, E. Yu, Starodubtsev, K. V., Starodubtsev, P. V., Chugrov, I. A., Sharov, O. O., Yakhin, R. A.
Format: Article
Language:English
Subjects:
Absorbers
Aluminum
Analysis
Classical and Quantum Gravitation
Density
Elementary Particles
Equations of state
Experiments
High power lasers
Inertial confinement fusion
Laser-plasma interactions
Lasers
Nonlinear
Numerical analysis
Particle and Nuclear Physics
Pellet fusion
Physics
Physics and Astronomy
Porous materials
Porous media
Pressure jump
Pressure transfer
Quantum Field Theory
Radiation
Relativity Theory
Shock wave propagation
Soft Matter Physics
Solid State Physics
Statistical
Wave generation
Wave propagation
Wave velocity
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Summary:Results of experiments aimed at amplification of the pressure of laser-induced shock wave on the passage from low- to high-density target material via vacuum gap are presented. During the action of nanosecond laser pulse of terawatt power on plane composite targets comprising a layer of laser radiation absorber of low-density (0.01–0.025 g/cm 3 ) spaced by vacuum gap from a layer of aluminum, the shock-wave velocity in aluminum reached 25–29 km/s and a pressure jump at the aluminum layer boundary was 1.2–1.5 times as large as that observed in experiments on the cumulative transition of laser-induced shock wave into a solid. The obtained experimental data are compared to results of the numerical calculations performed using hydrodynamic programs in which the shock-wave generation and propagation was modeled with allowance for the interaction of laser pulses with partly homogenized plasma of the porous material. Based on the results of experiments, numerical calculations, and their theoretical analysis, the efficiency of using low-density porous media in the targets intended for their equation of state investigations and inertial confinement fusion ignition is considered.
ISSN:1063-7761
1090-6509
DOI:10.1134/S106377612203013X