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Your search keyword '"TIKHONCHUK, V. T."' showing total 33 results
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33 results on '"TIKHONCHUK, V. T."'

1. Evidence of non collisional femtosecond laser electron heating in dielectric materials

Author

Duchateau, G., Chimier, B., Coudert, S., Smetanina, E., Barilleau, L., Fedorov, N., Jouin, H., Geoffroy, G., Martin, P., and Tikhonchuk, V. T.

Subjects
Plasma Physics (physics.plasm-ph), FOS: Physical sciences, Physics - Plasma Physics
Abstract

Electron dynamics in the bulk of large band gap dielectric crystals induced by intense femtosecond laser pulses at 800 nm is studied. With laser intensities under the ablation threshold (a few 10 TW/cm\textsuperscript{2}), electrons with unexpected energies in excess of 40-50 eV are observed by using the photoemission spectroscopy. A theoretical approach based on the Boltzmann kinetic equation including state-of-the-art modeling for various particles interactions is developed to interpret these experimental observations. A direct comparison shows that both electron heating in the bulk and a further laser field acceleration after ejection from the material contribute equivalently to the final electron energy gain. The electron heating in the bulk is shown to be significantly driven by a non-collisional process, i.e. direct multiphoton transitions between sub-bands of the conduction band. This work also sheds light on the contribution of the standard electron excitation/relaxation collisional processes, providing a new baseline to study the electron dynamics in dielectric materials and associated applications as laser material structuring., 5 pages, 5 figures

Published
2019

2. Pair creation in collision ofγ-ray beams produced with high-intensity lasers

Author

Ribeyre, X., d'Humières, E., Jansen, O., Jequier, S., Tikhonchuk, V. T., and Lobet, M.

Subjects
Astrophysics::High Energy Astrophysical Phenomena
Abstract

Direct production of electron-positron pairs in two-photon collisions, the Breit-Wheeler process, is one of the basic processes in the universe. However, it has never been directly observed in the laboratory because of the absence of the intense γ -ray sources. Laser-induced synchrotron sources emission may open a way to observe this process. The feasibility of an experimental setup using a MeV photon source is studied in this paper. We compare several γ -ray sources and estimate the expected number of electron-positron pairs and competing processes by using numerical simulations including quantum electrodynamic effects.

Published
2016

3. Guiding of relativistic electron beams in dense matter by longitudinally imposed strong magnetic fields

Author

Bailly-Grandvaux, M., Santos, J. J., Bellei, C., Forestier-Colleoni, P., Fujioka, S., Giuffrida, L., Honrubia, J. J., Batani, D., Bouillaud, R., Chevrot, M., Cross, J. E., Crowston, R., Dorard, S., Dubois, J. -L., Ehret, M., Gregori, G., Hulin, S., Kojima, S., Loyez, E., Marques, J. -R., Morace, A., Nicolai, Ph., Roth, M., Sakata, S., Schaumann, G., Serres, F., Servel, J., Tikhonchuk, V. T., Woolsey, N., and Zhang, Z.

Subjects
Plasma Physics (physics.plasm-ph), FOS: Physical sciences, Physics - Plasma Physics
Abstract

High-energy-density flows through dense matter are needed for effective progress in the production of laser-driven intense sources of energetic particles and radiation, in driving matter to extreme temperatures creating state regimes relevant for planetary or stellar science as yet inaccessible at the laboratory scale, or in achieving high-gain laser-driven thermonuclear fusion. When interacting at the surface of dense (opaque) targets, intense lasers accelerate relativistic electron beams which transport a significant fraction of the laser energy into the target depth. However, the overall laser-to-target coupling efficiency is impaired by the large divergence of the electron beam, intrinsic to the laser-plasma interaction. By imposing a longitudinal 600T laser-driven magnetic-field, our experimental results show guided >10MA-current of MeV-electrons in solid matter. Due to the applied magnetic field, the transported energy-density and the peak background electron temperature at the 60micron-thick targets rear surface rise by factors 5, resulting from unprecedentedly efficient guiding of relativistic electron currents., 11 pages, 7 figures

Published
2016
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4. The preplasma effect on the properties of the shock wave driven by a fast electron beam

Author

Llor Aisa, E., Ribeyre, X., Gus'kov, S. Yu., and Tikhonchuk, V. T.

Subjects
Shock wave, Physics, Astrophysics::High Energy Astrophysical Phenomena, Atmospheric-pressure plasma, Electron, Plasma, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Shock (mechanics), 0103 physical sciences, Cathode ray, Electromagnetic electron wave, Area density, Atomic physics, 010306 general physics
Abstract

Strong shock wave generation by a mono-energetic fast electron beam in a plasma with an increasing density profile is studied theoretically. The proposed analytical model describes the shock wave characteristics for a homogeneous plasma preceded by a low density precursor. The shock pressure and the time of shock formation depend on the ratio of the electron stopping length to the preplasma areal density and on the initial energy of injected electrons. The conclusions of theoretical model are confirmed in numerical simulations.

Published
2016
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5. Pair creation in collision of $��$--ray beams produced with high intensity lasers

Author

Ribeyre, X., Lobet, M., D'Humi��res, E., Jansen, O., Jequier, S., and Tikhonchuk, V. T.

Subjects
Plasma Physics (physics.plasm-ph), Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, Instrumentation and Detectors (physics.ins-det), Optics (physics.optics)
Abstract

Direct production of electron--positron pairs in two photon collisions, the Breit--Wheeler process, is one of the basic processes in the Universe. However, it has never been observed in laboratory because of absence of the intense gamma-ray sources. Laser induced synchrotron sources emission may open for the first time a way to observe this process. A feasibility of an experimental set--up using a MeV photon source is studied in this paper. We compare several $��$--ray sources, estimate the expected number of electron--positron pairs and competing processes by using numerical simulations including quantum electrodynamic effects.

Published
2015
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6. Energy dispersion in radiation pressure accelerated ion beams

Author

Grech, M., Skupin, S., Diaw, A., Schlegel, T., and Tikhonchuk, V. T.

Subjects
Plasma Physics (physics.plasm-ph), FOS: Physical sciences, Physics::Accelerator Physics, Physics - Plasma Physics
Abstract

We address the problem of energy dispersion of radiation pressure accelerated (RPA) ion beams emerging from a thin (solid) target. Two different acceleration schemes, namely phase-stable acceleration and multi-stage acceleration, are considered by means of analytical modelling and one-dimensional particle-in-cell simulations. Our investigations offer a deeper understanding of RPA and allow us to derive some guidelines for generating monoenergetic ion beams., 22 pages, 11 figures

Published
2011

24. Experimental characterization of fast electron stopping power in dense media ranging from solid to warm and dense matter

Author

Santos, J. J., Hulin, S., Vauzour, B., Vaisseau, X., Batani, D., Bouilleaud, R., Deneuville, F., Dorchies, F., Feugeas, J. -L, Fourment, C., D Humières, E., Nicolai, Ph, Tikhonchuk, V. T., Michael Touati, Debayle, A., Honrubia, J. J., Gremillet, L., Ceccotti, T., Floquet, V., Benocci, R., Morace, A., Veltcheva, M., Volpe, L., Baton, S. D., Pérez, F., Schlenvoigt, H. -P, Yahia, V., Beg, F. N., Chawla, S., Jarrot, L. C., Peebles, J., Sawada, H., Sorokovikova, A., Wei, M., Fedosejevs, R., Kerr, S., Coury, M., Gray, R., Mckenna, P., Li, K., Davies, J. R., Rhee, Y., Mclean, H., Patel, P., Santos, J, Hulin, S, Vauzour, B, Vaisseau, X, Batani, D, Bouilleaud, R, Deneuville, F, Dorchies, F, Feugeas, J, Fourment, C, D'Humieres, E, Nicolai, P, Tikhonchuk, V, Touati, M, Debayle, A, Honrubia, J, Gremillet, L, Ceccotti, T, Floquet, V, Benocci, R, Morace, A, Veltcheva, M, Volpe, L, Baton, S, Perez, F, Schlenvoigt, H, Yahia, V, Beg, F, Chawla, S, Jarrot, L, Peebles, J, Sawada, H, Sorokovikova, A, Wei, M, Fedosejevs, R, Kerr, S, Coury, M, Gray, R, Mckenna, P, Li, K, Davies, J, Rhee, Y, Mclean, H, and Patel, P

Subjects
Electron stopping power, warm dense matter

33. Laser produced electromagnetic pulses: generation, detection and mitigation

Author

Josef Krasa, Nigel Woolsey, Yihang Zhang, Josefine Metzkes-Ng, David Hillier, Roland Smith, David Neely, M. Cipriani, Zhe Zhang, Riccardo De Angelis, Alejandro Laso Garcia, Ales Honsa, Massimo De Marco, Irene Prencipe, Vladimir Tikhonchuk, Colin N. Danson, Paul McKenna, Viliam Kmetik, Egle Zemaityte, Roman Vrana, Yutong Li, R. J. Clarke, Fabrizio Consoli, Bernhard Zielbauer, M. Bardon, Weiman Jiang, Frédéric Lubrano, Philip Bradford, J. L. Dubois, Thomas E. Cowan, Bertrand Etchessahar, David Carroll, Jakub Cikhardt, P Raczka, Alexandre Poyé, Consoli, F., Tikhonchuk, V. T., Bardon, M., Bradford, P., Carroll, D. C., Cikhardt, J., Cipriani, M., Clarke, R. J., Cowan, T. E., Danson, C. N., De Angelis, R., De Marco, M., Dubois, J. -L., Etchessahar, B., Garcia, A. L., Hillier, D. I., Honsa, A., Jiang, W., Kmetik, V., Krasa, J., Li, Y., Lubrano, F., Mckenna, P., Metzkes-Ng, J., Poye, A., Prencipe, I., Raczka, P., Smith, R. A., Vrana, R., Woolsey, N. C., Zemaityte, E., Zhang, Y., Zhang, Z., Zielbauer, B., and Neely, D.

Subjects
Electromagnetic field, Nuclear and High Energy Physics, Computer science, Terahertz radiation, High-Power Lasers, 7. Clean energy, 01 natural sciences, Electromagnetic radiation, Mitigation Techniques, 010305 fluids & plasmas, law.invention, law, 0103 physical sciences, Electronic engineering, diagnostics, Electronics, 010306 general physics, electromagnetic pulses, Diagnostics, QC, Electromagnetic pulse, Emphasis (telecommunications), Laser, Atomic and Molecular Physics, and Optics, Electromagnetic Pulses, Electronic, Optical and Magnetic Materials, Nuclear Energy and Engineering, Frequency domain, mitigation techniques, ddc:620, high-power lasers
Abstract

High power laser science and engineering 8, e22 (2020). doi:10.1017/hpl.2020.13, Published by Cambridge Univ. Press, Cambridge

Published
2020

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