Geodesic
Three-dimensionel modeling of kinetics of electron-proton plasma with supercritical density in an powerful electromagnetic field of laser radiation
Matematičeskoe modelirovanie, Tome 27 (2015) no. 6, pp. 33-53.

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Numerical solution of the equations of Maxwell–Vlasov in a three-dimensional (3D) model of interaction of powerful electromagnetic field of laser radiation with a electron-proton supercritical density plasma gives kinetic distribution functions for electrons and protons versus time. In the present paper such kinetic is analyzed in detail, which makes it possible to elucidate the mechanism of important effect under consideration — effect of proton acceleration to very high energies to tens MeV. This mechanism consists of transfer to the proton component of plasma impulse of the incident electromagnetic wave, enhanced by reflection effect of this wave. Qualitatively these results are in accordance with the physical experiments, fulfilled in last decade. This paper also presents results of the calculation of the distribution of all (six) components of the electromagnetic field inside the plasma with due regard for to electroneutrality violations of the plasma. This work concerns the kinetic properties of the plasma and is a continuation of our previous works.
Keywords: Maxwell, electromagnetic field, laser radiation, protons high-energy, ultra relativistic electrons.
Mots-clés : Vlasov 
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V. S. Imshennik; S. L. Ginzburg; V. F. Dyachenko. Three-dimensionel modeling of kinetics of electron-proton plasma with supercritical density in an powerful electromagnetic field of laser radiation. Matematičeskoe modelirovanie, Tome 27 (2015) no. 6, pp. 33-53. http://geodesic.mathdoc.fr/item/MM_2015_27_6_a2/

[1] S. P. Hatchett, C. G. Brown, T. E. Cowan et al., “Electron, photon and ion beams from the relativistic interaction of Petawatt laser pulses with solid targets”, Physics of Plasmas, 7:5(2) (2000), 2076–2082

[2] S. L. Ginzburg, V. F. Diachenko, V. S. Imshennik, “3D-model vzaimodeistviia moshchnogo lazernogo izlucheniia s plazmoi sverkhkriticheskoi plotnostieiu i generaciia protonov vysokikh energii”, Matematicheskoe modelirovanie, 26:10 (2014), 79–94 | Zbl

[3] S. L. Ginzburg, V. F. Diachenko, V. S. Imshennik, “Generaciia protonov vysokikh energii v 3D-modeli vzaimodeistviia moshchnogo lazernogo izlucheniia s plazmoi sverkhkriticheskoi plotnosti”, Preprinty IPM im. M. V. Keldysha RAN, 2013, 049, 30 pp.

[4] V. F. Diachenko, V. S. Imshennik, “About the anomalous interaction of intense light beams with dense plasma”, Plasma Phys., 5 (1979), 413–417

[5] V. F. Diachenko, “O raschetakh zadach besstolknovitelienoi plazmy”, ZhVMiMF, 1985, no. 4, 622–627

[6] V. F. Diachenko, Desiat lekcii po fizicheskoi matematike, Faktorial, M., 1997, 64 pp.

[7] H. Daido, M. Nishiuchi, A. S. Pirozhkov, “Review of Laser-driven ion sources and their applications”, Rep. Prog. Phys., 75 (2012), 056401, 71 pp.

[8] M. M. Basko, “Inertial confinement fusion: steady progress towards ignition and high gain”, Nucl. Fusion, 45 (2005), 38

[9] S. L. Ginzburg, V. F. Diachenko, V. S. Imshennik, V. V. Paleichik, “Three-dimensional simulations of anomalous absorption of laser radiation by plasma with supercritical density”, Plasma Physics Reports, 38:2 (2012), 153–168 | MR

[10] L. D. Landau, E. M. Lifshitz, The Classical Theory of Fields, 4th ed., Butterworth-Heinemann, Oxford, 2003 | MR

[11] R. I. Ilkaev, S. G. Garanin, “Issledovanie problem termoiadernogo sinteza”, Vestnik RAN, 76 (2006), 503–516 | MR

[12] Zh. A. Muru, A. M. Sergeev, A. V. Korzhimanov, A. A. Goloskov, E. A. Khazanov, “Ekstremalnye svetovye polia i ikh fundamentalnye prilozheniia”, Vestnik RAN, 2014, 502–509 | Zbl

[13] S. L. Ginzburg, V. F. Diachenko, V. V. Paleichik, “3D-raschety pogloshcheniia elektromagnitnoi volny plazmoi”, Preprinty IPM im. M. V. Keldysha RAN, 2009, 001, 12 pp.