Search

Your search keyword '"d'Humieres, E."' showing total 93 results
Start Over Author "d'Humieres, E."
93 results on '"d'Humieres, E."'

1. Saturation of the compression of two interacting magnetic flux tubes evidenced in the laboratory

Author

Sladkov, A., Fegan, C., Yao, W., Bott, A. F. A., Chen, S. N., Ahmed, H., Filippov, E. D., Lelièvre, R., Martin, P., McIlvenny, A., Waltenspiel, T., Antici, P., Borghesi, M., Pikuz, S., Ciardi, A., d'Humières, E., Soloviev, A., Starodubtsev, M., and Fuchs, J.

Subjects
Physics - Plasma Physics
Abstract

Interactions between magnetic fields advected by matter play a fundamental role in the Universe at all possible scales. A crucial role these interactions play is in making turbulent fields highly anisotropic, leading to observed ordered fields. These in turn, are important evolutionary factors for all the systems within and around. Despite scant evidence, due to the difficulty in measuring even near-Earth events, the magnetic field compression factor in these interactions, measured at very varied scales, is limited to a few. However, compressing matter in which a magnetic field is embedded, results in compression up to several thousands. Here we show, using laboratory experiments and matching three-dimensional hybrid simulations, that there is indeed a very effective saturation of the compression when two independent magnetic fields are advected by plasmas encounter. We found that the observed saturation is linked to a build-up of the magnetic pressure at the inflows encounter point, which decelerates them and thereby stops further compression. Moreover, the growth of an electric field, induced by the incoming flows and the magnetic field, acts in redirecting the inflows transversely, further hampering field compression.

Published
2024

2. Helical coil design with controlled dispersion for bunching enhancement of the TNSA protons

Author

Hirsch-Passicos, A, Lacoste, C L C, André, F, Elskens, Y, d'Humières, E, Tikhonchuk, V, and Bardon, M

Subjects
Physics - Accelerator Physics, Physics - Plasma Physics
Abstract

The quality of the proton beam produced by Target Normal Sheath Acceleration (TNSA) with high power lasers can be significantly improved with the use of helical coils. While they showed promising results in terms of focusing, their performances in terms of the of cutoff energy and bunching stay limited due to the dispersive nature of helical coils. A new scheme of helical coil with a tube surrounding the helix is introduced, and the first numerical simulations and an analytical model show a possibility of a drastic reduction of the current pulse dispersion for the parameters of high power laser facilities. The helical coils with tube strongly increase bunching, creating two collimated narrow-band proton beams from a broad and divergent TNSA distribution. The analytical model provides scaling of proton parameters as a function of laser facility features.

Published
2023

3. Dynamics of nanosecond laser pulse propagation and of associated instabilities in a magnetized underdense plasma

Author

Yao, W., Higginson, A., Marquès, J. -R., Antici, P., Béard, J., Burdonov, K., Borghesi, M., Castan, A., Ciardi, A., Coleman, B., Chen, S. N., d'Humières, E., Gangolf, T., Gremillet, L., Khiar, B., Lancia, L., Loiseau, P., Ribeyre, X., Soloviev, A., Starodubtsev, M., Wang, Q., and Fuchs, J.

Subjects
Physics - Plasma Physics
Abstract

The propagation and energy coupling of intense laser beams in plasmas are critical issues in laser-driven inertial confinement fusion. Applying magnetic fields to such a setup has been evoked to enhance fuel confinement and heating, and mitigate laser energy losses. Here we report on experimental measurements demonstrating improved transmission and increased smoothing of a high-power laser beam propagating in an underdense magnetized plasma. We also measure enhanced backscattering, which our simulations show is due to hot electrons confinement, thus leading to reduced target preheating.

Published
2022
Full Text
View/download PDF

4. Guided Electromagnetic Discharge Pulses Driven by Short Intense Laser Pulses: Characterisation and Modelling

Author

Ehret, M., Bailly-Grandvaux, M., Korneev, Ph., Apiñaniz, J. I., Brabetz, C., Morace, A., Bradford, P., d'Humières, E., Schaumann, G., Bagnoud, V., Malko, S., Matveevskii, C., Roth, M., Volpe, L., Woolsey, N. C., and Santos, J. J.

Subjects
Physics - Plasma Physics, J.2
Abstract

Strong electromagnetic pulses (EMP) are generated from intense laser interactions with solid-density targets, and can be guided by the target geometry, specifically through conductive connections to the ground. We present an experimental characterization, by time- and spatial-resolved proton deflectometry, of guided electromagnetic discharge pulses along wires including a coil, driven by 0.5 ps, 50 J, 1e19 W/cm2 laser pulses. Proton-deflectometry data allows to time-resolve first the EMP due to the laser-driven target charging and then the return EMP from the ground through the conductive target stalk. Both EMPs have a typical duration of tens of ps and correspond to currents in the kA-range with electric-field amplitudes of multiple GV/m. The sub-mm coil in the target rod creates lensing effects on probing protons, due to both magnetic- and electric-field contributions. This way, protons of 10 MeV-energy range are focused over cm-scale distances. Experimental results are supported by analytical modelling and high-resolution numerical particle-in-cell simulations, unraveling the likely presence of a surface plasma, which parameters define the discharge pulse dispersion in the non-linear propagation regime.

Published
2022
Full Text
View/download PDF

5. Investigating particle acceleration dynamics in interpenetrating magnetized collisionless super-critical shocks

Author

Yao, W., Fazzini, A., Chen, S. N., Burdonov, K., Béard, J., Borghesi, M., Ciardi, A., Miceli, M., Orlando, S., Ribeyre, X., d'Humières, E., and Fuchs, J.

Subjects
Physics - Plasma Physics
Abstract

Colliding collisionless shocks appear in a great variety of astrophysical phenomena and are thought to be possible sources of particle acceleration in the Universe. We have previously investigated particle acceleration induced by single super-critical shocks (whose magnetosonic Mach number is higher than the critical value of 2.7) (Yao et al. 2021, 2022), as well as the collision of two sub-critical shocks (Fazzini et al. 2022). Here, we propose to make measurements of accelerated particles from interpenetrating super-critical shocks to observe the ''phase-locking effect'' (Fazzini et al. 2022) from such an event. This effect is predicted to significantly boost the energy spectrum of the energized ions compared to a single supercritical collisionless shock. We thus anticipate that the results obtained in the proposed experiment could have a significant impact on our understanding of one type of primary source (acceleration of thermal ions as opposed to secondary acceleration mechanisms of already energetic ions) of ion energization of particles in the Universe.

Published
2022
Full Text
View/download PDF

6. Experimental capabilities of the LMJ-PETAL facility

Author

Cayzac, W., Boutoux, G., Brygoo, S., Denoeud, A., Depierreux, S., Tassin, V., Albert, F., Alozy, E., Baccou, C., Batani, D., Blanchot, N., Bonneau, M., Bonnefille, M., Botrel, R., Bowen, C., Bradford, P., Brochier, M., Caillaud, T., Chaleil, A., Chardavoine, S., Chollet, C., Courtois, C., Darbon, S., Davoine, X., Debesset, S., Denis, V., Diaz, R., Dizière, A., Du Jeu, R., Duchastenier, W., Dupré, P., Duval, A., Esnault, C., Etchessahar, B., Ferri, M., Fuchs, J., Geoffray, I., Gremillet, L., Grolleau, A., D’Humières, E., Jalinaud, T., Laffite, S., Lafon, M., Lagache, M.A., Landoas, O., Lantuejoul, I., Le-Deroff, L., Le Tacon, S., Leidinger, J.P., Lelièvre, R., Liberatore, S., Mahieu, B., Masson-Laborde, P.E., Meyer, C., Miquel, J.L., Parreault, R., Philippe, F., Prévot, V., Prunet, P., Raphaël, O., Reverdin, C., Ribotte, L., Riquier, R., Rousseaux, C., Sary, G., Soullié, G., Sozet, M., Ta-Phuoc, K., Trela, J., Trauchessec, V., Vaisseau, X., Vauzour, B., Villette, B., and Lefebvre, E.

Published
2024
Full Text
View/download PDF

7. Particle energization in colliding subcritical collisionless shocks investigated in the laboratory

Author

Fazzini, A., Yao, W., Burdonov, K., Béard, J., Chen, S. N., Ciardi, A., d'Humières, E., Diab, R., Filippov, E. D., Kisyov, S., Lelasseux, V., Miceli, M., Moreno, Q., Orlando, S., Pikuz, S., Ribeyre, X., Starodubtsev, M., Zemskov, R., and Fuchs, J.

Subjects
Physics - Plasma Physics
Abstract

Colliding collisionless shocks appear in a great variety of astrophysical phenomena and are thought to be possible sources of particle acceleration in the Universe. To investigate the detailed dynamics of this phenomenon, we have performed a dedicated laboratory experiment. We have generated two counter-streaming subcritical collisionless magnetized shocks by irradiating two teflon (CF$_2$) targets with 100 J, 1 ns laser beams on the LULI2000 laser facility. The interaction region between the plasma flows was pre-filled with a low density background hydrogen plasma and initialized with an externally applied homogeneous magnetic field perpendicular to the shocks. We report here on measurements of the plasma density and temperature during the formation of the supercritical shocks, their transition to subcritical, and final interpenetration. We have also modeled the macroscopic evolution of the system via hydrodynamic simulations and the microphysics at play during the interaction via Particle-In-Cell simulations. The main goal was to understand what was the effect of the second shock on particle energization. We found that in the presence of two shocks the ambient ions reach energies around 1.5 times of the ones obtained with single shocks. Both the presence of the downstream zone of the second shock and of the downstream zone common for the two shocks play a role in the different energization: the characteristics of the perpendicular electric fields in the two areas allow, indeed, certain particles to keep being accelerated or to avoid being decelerated.

Published
2022
Full Text
View/download PDF

8. Laser Driven Nuclear physics at ELINP

Author

Negoita, F., Roth, M., Thirolf, P. G., Tudisco, S., Hannachi, F., Moustaizis, S., Pomerantz, I., Mckenna, P., Fuchs, J., Sphor, K., Acbas, G., Anzalone, A., Audebert, P., Balascuta, S., Cappuzzello, F., Cernaianu, M. O., Chen, S., Dancus, I., Freeman, R., Geissel, H., Ghenuche, P., Gizzi, L., Gobet, F., Gosselin, G., Gugiu, M., Higginson, D., D¶Humiêres, E., Ivan, C., Jaroszynski, D., Kar, S., Lamia, L., Leca, V., Neagu, L., Lanzalone, G., Meot, V., Mirfayzi, S. R., Mitu, I. O., Morel, P., Murphy, C., Petcu, C., Petrascu, H., Petrone, C., Raczka, P., Risca, M., Rotaru, F., Santos, J. J., Schumacher, D., Stutman, D., Tarisien, M., Tataru, M., Tatulea, B., Turcu, I. C. E., Versteegen, M., Ursescu, D., Gales, S., and Zamfir, N. V.

Subjects
Physics - Instrumentation and Detectors, Nuclear Experiment
Abstract

High power lasers have proven being capable to produce high energy gamma rays, charged particles and neutrons to induce all kinds of nuclear reactions. At ELI, the studies with high power lasers will enter for the first time into new domains of power and intensities.

Published
2022

9. Multiscale study of high energy attosecond pulse interaction with matter and application to proton-Boron fusion

Author

Ribeyre, X., Capdessus, R., d'Humières, E., Wheeler, J., and Mourou, G.

Subjects
Physics - Plasma Physics
Abstract

For several decades, the interest of the scientific community in aneutronic fusion reactions such as proton-Boron fusion has grown because of potential applications in different fields. Recently, many scientific teams in the world have worked experimentally on the possibility to trigger proton-Boron fusion using intense lasers demonstrating an important renewal of interest of this field. It is now possible to generate ultra-short high intensity laser pulses at high repetition rate. These pulses also have unique properties that can be leveraged to produce proton-Boron fusion reactions. In this article, we investigate the interaction of a high energy attosecond pulse with a solid proton-Boron target and the associated ion acceleration supported by numerical simulations. We demonstrate the efficiency of single-cycle attosecond pulses in comparison to multi-cycle attosecond pulses in ion acceleration and magnetic field generation. Using these results we also propose a path to proton-Boron fusion using high energy attosecond pulses.

Published
2021

10. Characterization and performance of the Apollon Short-Focal-Area facility following its commissioning at 1 PW level

Author

Burdonov, K., Fazzini, A., Lelasseux, V., Albrecht, J., Antici, P., Ayoul, Y., Beluze, A., Cavanna, D., Ceccotti, T., Chabanis, M., Chaleil, A., Chen, S. N., Chen, Z., Consoli, F., Cuciuc, M., Davoine, X., Delaneau, J. P., d'Humières, E., Dubois, J-L., Evrard, C., Filippov, E., Freneaux, A., Forestier-Colleoni, P., Gremillet, L., Horny, V., Lancia, L., Lecherbourg, L., Lebas, N., Leblanc, A., Ma, W., Martin, L., Negoita, F., Paillard, J-L., Papadopoulos, D., Perez, F., Pikuz, S., Qi, G., Quéré, F., Ranc, L., Söderstrom, P. -A., Scisciò, M., Sun, S., Vallières, S., Wang, P., Yao, W., Mathieu, F., Audebert, P., and Fuchs, J.

Subjects
Physics - Plasma Physics
Abstract

We present the results of the first commissioning phase of the ``short focal length'' area (SFA) of the Apollon laser facility (located in Saclay, France), which was performed with the first available laser beam (F2), scaled to a nominal power of one petawatt. Under the conditions that were tested, this beam delivered on target pulses of 10 J average energy and 24 fs duration. Several diagnostics were fielded to assess the performance of the facility. The on-target focal spot, its spatial stability, the temporal intensity profile prior to the main pulse, as well as the resulting density gradient formed at the irradiated side of solid targets, have been thoroughly characterized, with the goal of helping users design future experiments. Emissions of energetic electrons, ions, and electromagnetic radiation were recorded, showing good laser-to-target coupling efficiency and an overall performance comparable with that of similar international facilities. This will be followed in 2022 by a further commissioning stage at the multi-petawatt level.

Published
2021
Full Text
View/download PDF

11. Detailed characterization of laboratory magnetized super-critical collisionless shock and of the associated proton energization

Author

Yao, W., Fazzini, A., Chen, S. N., Burdonov, K., Antici, P., Béard, J., Bolaños, S., Ciardi, A., Diab, R., Filippov, E. D., Kisyov, S., Lelasseux, V., Miceli, M., Moreno, Q., Nastasa, V., Orlando, S., Pikuz, S., Popescu, D. C., Revet, G., Ribeyre, X., d'Humières, E., and Fuchs, J.

Subjects
Physics - Plasma Physics
Abstract

Collisionless shocks are ubiquitous in the Universe and are held responsible for the production of non-thermal particles and high-energy radiation. In the absence of particle collisions in the system, theoretical works show that the interaction of an expanding plasma with a pre-existing electromagnetic structure (as in our case) is able to induce energy dissipation and allow for shock formation. Shock formation can alternatively take place when two plasmas interact, through microscopic instabilities inducing electromagnetic fields which are able in turn to mediate energy dissipation and shock formation. Using our platform where we couple a fast-expanding plasma induced by high-power lasers (JLF/Titan at LLNL and LULI2000) with high-strength magnetic fields, we have investigated the generation of magnetized collisionless shock and the associated particle energization. We have characterized the shock to be collisionless and super-critical. We report here on measurements of the plasma density, temperature, the electromagnetic field structures, and particle energization in the experiments, under various conditions of ambient plasma and B-field. We have also modeled the formation of the shocks using macroscopic hydrodynamic simulations and the associated particle acceleration using kinetic particle-in-cell simulations. As a companion paper of \citet{yao2020laboratory}, here we show additional results of the experiments and simulations, providing more information to reproduce them and demonstrating the robustness of our interpreted proton energization mechanism to be shock surfing acceleration.

Published
2021
Full Text
View/download PDF

12. Electron-positron pair production in the collision of real photon beams with wide energy distributions

Author

Esnault, L, d'Humières, E, Arefiev, A, and Ribeyre, X

Subjects
Physics - Plasma Physics
Abstract

The creation of an electron-positron pair in the collision of two real photons, namely the linear Breit-Wheeler process, has never been detected directly in the laboratory since its prediction in 1934 despite its fundamental importance in quantum electrodynamics and astrophysics. In the last few years, several experimental setup have been proposed to observe this process in the laboratory, relying either on thermal radiation, Bremsstrahlung, linear or multiphoton inverse Compton scattering photons sources created by lasers or by the mean of a lepton collider coupled with lasers. In these propositions, the influence of the photons' energy distribution on the total number of produced pairs has been taken into account with an analytical model only for two of these cases. We hereafter develop a general and original, semi-analytical model to estimate the influence of the photons energy distribution on the total number of pairs produced by the collision of two such photon beams, and give optimum energy parameters for some of the proposed experimental configurations. Our results shows that the production of optimum Bremsstrahlung and linear inverse Compton sources are, only from energy distribution considerations, already reachable in today's facilities. Despite its less interesting energy distribution features for the LBW pair production, the photon sources generated via multiphoton inverse Compton scattering by the propagation of a laser in a micro-channel can also be interesting, thank to the high collision luminosity that could eventually be reached by such configurations. These results then gives important insights for the design of experiments intended to detect linear Breit-Wheeler produced positrons in the laboratory for the first time.

Published
2021
Full Text
View/download PDF

13. Laboratory evidence for proton energization by collisionless shock surfing

Author

Yao, W., Fazzini, A., Chen, S. N., Burdonov, K., Antici, P., Béard, J., Bolaños, S., Ciardi, A., Diab, R., Filippov, E. D., Kisyov, S., Lelasseux, V., Miceli, M., Moreno, Q., Nastasa, V., Orlando, S., Pikuz, S., Popescu, D. C., Revet, G., Ribeyre, X., d'Humières, E., and Fuchs, J.

Subjects
Physics - Plasma Physics
Abstract

Charged particles can be accelerated to high energies by collisionless shock waves in astrophysical environments, such as supernova remnants. By interacting with the magnetized ambient medium, these shocks can transfer energy to particles. Despite increasing efforts in the characterization of these shocks from satellite measurements at the Earth's bow shock and powerful numerical simulations, the underlying acceleration mechanism or a combination thereof is still widely debated. Here, we show that astrophysically relevant super-critical quasi-perpendicular magnetized collisionless shocks can be produced and characterized in the laboratory. We observe characteristics of super-criticality in the shock profile as well as the energization of protons picked up from the ambient gas to hundreds of keV. Kinetic simulations modelling the laboratory experiment identified shock surfing as the proton acceleration mechanism. Our observations not only provide the direct evidence of early stage ion energization by collisionless shocks, but they also highlight the role this particular mechanism plays in energizing ambient ions to feed further stages of acceleration. Furthermore, our results open the door to future laboratory experiments investigating the possible transition to other mechanisms, when increasing the magnetic field strength, or the effect induced shock front ripples could have on acceleration processes.

Published
2020
Full Text
View/download PDF

14. Over-critical sharp-gradient plasma slab produced by the collision of laser-induced blast-waves in a gas jet; Application to high-energy proton acceleration

Author

Marquès, J. -R., Loiseau, P., Bonvalet, J., Tarisien, M., d'Humières, E., Domange, J., Hannachi, F., Lancia, L., Larroche, O., Puyuelo-Valdes, P. Nicolaï P., Romagnani, L., Santos, J., and Tikhonchuk, V.

Subjects
Physics - Plasma Physics
Abstract

The generation of thin and high density plasma slabs at high repetition rate is a key issue for ultra-high intensity laser applications. We present a scheme to create such plasma slabs, based on the propagation and collision in a gas jet of two counter-propagating blast waves (BW). Each BW is launched by a sudden and local heating induced by a nanosecond laser beam that propagates along the side of the jet. The resulting cylindrical BW expands perpendicular to the beam. The shock front, bent by the gas jet density gradient, pushes and compresses the plasma toward the jet center. By using two parallel ns laser beams, this scheme enables to tailor independently two opposite sides of the jet, while avoiding the damage risks associated with counterpropagating laser beams. A parametric study is performed using two and three dimensional hydrodynamic, as well as kinetic simulations. The BWs bending combined with the collision in a stagnation regime increases the density by more than 10 times and generates a very thin (down to few microns), near to over-critical plasma slab with a high density contrast (> 100), and a lifetime of a few hundred picoseconds. Two dimensional particle-in-cell simulations are used to study the influence of plasma tailoring on proton acceleration by a high-intensity sub-picosecond laser pulse. Tailoring the plasma not only at the entrance but also the exit side of the ps-pulse enhances the proton beam collimation, increases significantly the number of high energy protons, as well as their maximum energy.

Published
2020
Full Text
View/download PDF

15. Collimated gamma-ray beams from structured laser-irradiated targets -- how to increase the efficiency without increasing the laser intensity

Author

Jansen, O., Wang, T., Gong, Z., Ribeyre, X., d'Humières, E., Stutman, D., Toncian, T., and Arefiev, A.

Subjects
Physics - Plasma Physics, Physics - Accelerator Physics, Physics - Applied Physics
Abstract

Using three-dimensional kinetic simulations, we examine the emission of collimated gamma-ray beams from structured laser-irradiated targets with a pre-filled cylindrical channel. The channel guides the incident laser pulse, enabling generation of a slowly evolving azimuthal plasma magnetic field that serves two key functions: to enhance laser-driven electron acceleration and to induce emission of gamma-rays by the energetic electrons. Our main finding is that the conversion efficiency of the laser energy into a beam of gamma-rays ($5^{\circ}$ opening angle) can be significantly increased without increasing the laser intensity by utilizing channels with an optimal density. The conversion efficiency into multi-MeV photons increases roughly linearly with the incident laser power $P$, as we increase $P$ from 1 PW to 4 PW while keeping the laser peak intensity fixed at $5 \times 10^{22}$ W/cm$^2$. This scaling is achieved by using an optimal range of plasma densities in the channel between 10 and $20 n_{cr}$, where $n_{cr}$ is the classical cutoff density for electromagnetic waves. The corresponding number of photons scales as $P^2$. One application that directly benefits from such a strong scaling is the pair production via two-photon collisions, with the number of generated pairs increasing as $P^4$ at fixed laser intensity., Comment: 15 pages, 14 figures

Published
2019
Full Text
View/download PDF

16. High-Energy Radiation and Pair Production by Coulomb Processes in Particle-In-Cell Simulations

Author

Martinez, B., Lobet, M., Duclous, R., d'Humières, E., and Gremillet, L.

Subjects
Physics - Plasma Physics
Abstract

We present a Monte Carlo implementation of the Bremsstrahlung, Bethe-Heitler and Coulomb Trident processes into the particle-in-cell (PIC) simulation framework. In order to address photon and electron-positron pair production in a wide range of physical conditions, we derive Bremsstrahlung and Bethe-Heitler cross sections taking account of screening effects in arbitrarily ionized plasmas. Our calculations are based on a simple model for the atomic Coulomb potential that describes shielding due to both bound electrons, free electrons and ions. We then describe a pairwise particle interaction algorithm suited to weighted PIC plasma simulations, for which we perform several validation tests. Finally, we carry out a parametric study of photon and pair production during high-energy electron transport through micrometric solid foils. Compared to the zero-dimensional model of J. Myatt et al. [Phys. Rev. E 76, 066409 (2009)], our integrated one-dimensional simulations pinpoint the importance of the electron energy losses resulting from the plasma expansion., Comment: 25 pages, 15 figures

Published
2019
Full Text
View/download PDF

17. Hard particle spectra of galactic X-ray sources by relativistic magnetic reconnection in laser lab

Author

Law, K. F. F., Abe, Y., Morace, A., Arikawa, Y., Sakata, S., Lee, S., Matsuo, K., Morita, H., Ochiai, Y., Liu, C., Yogo, A., Okamoto, K., Golovin, D., Ehret, M., Ozaki, T., Nakai, M., Sentoku, Y., Santos, J. J., d'Humières, E., Korneev, Ph., and Fujioka, S.

Subjects
Physics - Plasma Physics, Astrophysics - High Energy Astrophysical Phenomena
Abstract

Magnetic reconnection is a process whereby magnetic field lines in different directions "reconnect" with each other, resulting in the rearrangement of magnetic field topology together with the conversion of magnetic field energy into the kinetic energy (K.E.) of energetic particles. This process occurs in magnetized astronomical plasmas, such as those in the solar corona, Earth's magnetosphere, and active galactic nuclei, and accounts for various phenomena, such as solar flares, energetic particle acceleration, and powering of photon emission. In the present study, we report the experimental demonstration of magnetic reconnection under relativistic electron magnetization situation, along with the observation of power-law distributed outflow in both electron and proton energy spectra. Through irradiation of an intense laser on a "micro-coil", relativistically magnetized plasma was produced and magnetic reconnection was performed with maximum magnetic field 3 kT. In the downstream outflow direction, the non-thermal component is observed in the high-energy part of both electron and proton spectra, with a significantly harder power-law slope of the electron spectrum (p = 1.535 +/- 0.015) that is similar to the electron injection model proposed to explain a hard emission tail of Cygnus X-1, a galactic X-ray source with the same order of magnetization. The obtained result showed experimentally that the magnetization condition in the emitting region of a galactic X-ray source is sufficient to build a hard electron population through magnetic reconnection., Comment: 25 pages, 10 figures

Published
2019
Full Text
View/download PDF

18. Power Scaling for Collimated gamma-Ray Beams Generated by Structured Laser-Irradiated Targets and Its Application to Two-Photon Pair Production

Author

Wang, T, Ribeyre, X, Gong, Z, Jansen, O, d'Humieres, E, Stutman, D, Toncian, T, and Arefiev, A

Subjects
physics.plasm-ph, physics.acc-ph, physics.app-ph, Physical Sciences, Engineering
Abstract

Using three-dimensional kinetic simulations, we examine the emission ofcollimated gamma-ray beams from structured laser-irradiated targets with apre-filled cylindrical channel. The channel guides the incident laser pulse,enabling generation of a slowly evolving azimuthal plasma magnetic field thatserves two key functions: to enhance laser-driven electron acceleration and toinduce emission of gamma-rays by the energetic electrons. Our main finding isthat the conversion efficiency of the laser energy into a beam of gamma-rays($5^{\circ}$ opening angle) can be significantly increased without increasingthe laser intensity by utilizing channels with an optimal density. Theconversion efficiency into multi-MeV photons increases roughly linearly withthe incident laser power $P$, as we increase $P$ from 1 PW to 4 PW whilekeeping the laser peak intensity fixed at $5 \times 10^{22}$ W/cm$^2$. Thisscaling is achieved by using an optimal range of plasma densities in thechannel between 10 and $20 n_{cr}$, where $n_{cr}$ is the classical cutoffdensity for electromagnetic waves. The corresponding number of photons scalesas $P^2$. One application that directly benefits from such a strong scaling isthe pair production via two-photon collisions, with the number of generatedpairs increasing as $P^4$ at fixed laser intensity.

Published
2020

19. Modeling the interaction of an ultra-high intensity laser pulse with nano-layered flat-top cone targets for ion acceleration

Author

Budrigă, O, d'Humières, E, Ionel, L E, Martiş, M, and Carabaş, M

Subjects
Physics - Plasma Physics
Abstract

We propose new nanotargets as nano-layered flat-top cone targets to be used for future laser-ion acceleration experiments at ELI-NP. We study their behaviour at the interaction with an ultra-high intensity laser pulse by performing Particle-In-Cell simulations. We analyze spatio-temporal the electromagnetic field based on the finite-difference time-domain method for a complementary description. We find the optimum diameter of the nanospheres and the proper nano-flat-top foil thickness for which one can obtain monoenergetic beams of very energetic ions with low angular divergence., Comment: 13 pages, 10 figures

Published
2018
Full Text
View/download PDF

20. Expansion of a radially symmetric blast shell into a uniformly magnetized plasma

Author

Dieckmann, M E, Moreno, Q, Doria, D, Romagnani, L, Sarri, G, Folini, D, Walder, R, Bret, A, d'Humieres, E, and Borghesi, M

Subjects
Physics - Plasma Physics
Abstract

The expansion of a thermal pressure-driven radial blast shell into a dilute ambient plasma is examined with two-dimensional PIC simulations. The purpose is to determine if laminar shocks form in a collisionless plasma that resemble their magnetohydrodynamic counterparts. The ambient plasma is composed of electrons with the temperature 2 keV and cool fully ionized nitrogen ions. It is permeated by a spatially uniform magnetic field. A forward shock forms between the shocked ambient medium and the pristine ambient medium, which changes from an ion acoustic one through a slow magnetosonic one to a fast magnetosonic shock with increasing shock propagation angles relative to the magnetic field. The slow magnetosonic shock that propagates obliquely to the magnetic field changes into a tangential discontinuity for a perpendicular propagation direction, which is in line with the magnetohydrodynamic model. The expulsion of the magnetic field by the expanding blast shell triggers an electron-cyclotron drift instability., Comment: 10 pages and 11 figures. Accepted for publication in the Physics of Plasmas

Published
2018
Full Text
View/download PDF

21. Quasi-perpendicular fast magnetosonic shock with wave precursor in collisionless plasma

Author

Moreno, Q., Dieckmann, M. E., Ribeyre, X., and d'Humières, E.

Subjects
Physics - Plasma Physics
Abstract

A one-dimensional particle-in-cell (PIC) simulation tracks a fast magnetosonic shock over time scales comparable to an inverse ion gyrofrequency. The magnetic pressure is comparable to the thermal pressure upstream. The shock propagates across a uniform background magnetic field with a pressure that equals the thermal pressure upstream at the angle 85$^\circ$ at a speed that is 1.5 times the fast magnetosonic speed in the electromagnetic limit. Electrostatic contributions to the wave dispersion increase its phase speed at large wave numbers, which leads to a convex dispersion curve. A fast magnetosonic precursor forms ahead of the shock with a phase speed that exceeds the fast magnetosonic speed by about $\sim 30 \%$. The wave is slower than the shock and hence it is damped., Comment: 4 pages, 3 figures

Published
2018
Full Text
View/download PDF

22. Synchrotron emission from nanowire-array targets irradiated by ultraintense laser pulses

Author

Martinez, B., D'Humières, E., and Gremillet, L.

Subjects
Physics - Plasma Physics
Abstract

We present a numerical study, based on two-dimensional particle-in-cell simulations, of the synchrotron emission induced during the interaction of femtosecond laser pulses of intensities $I=10^{21}-10^{23}\,\mathrm{Wcm}^{-2}$ with nanowire arrays. Through an extensive parametric scan on the target parameters, we identify and characterize several dominant radiation mechanisms, mainly depending on the transparency or opacity of the plasma produced by the wire expansion. At $I=10^{22}\,\mathrm{Wcm}^{-2}$, the emission of high-energy ($>10\,\mathrm{keV}$) photons attains a maximum conversion efficiency of $\sim 10\%$ for $36-50\,\mathrm{nm}$ wire widths and $1\,\mu\mathrm{m}$ interspacing. This maximum radiation yield is similar to that achieved in uniform plasma of same average (sub-solid) density, but nanowire arrays provide efficient radiation sources over a broader parameter range. We examine the variations of the photon spectra with the laser intensity and the wire material. Finally, we demonstrate that the radiation efficiency can be further enhanced by adding a plasma mirror at the backside of the nanowire array.

Published
2018
Full Text
View/download PDF

23. Whispering gallery effect in relativistic optics

Author

Abe, Y., Law, K. -F. -F., Korneev, Ph., Fujioka, S., Kojima, S., Lee, S. -H., Sakata, S., Matsuo, K., Oshima, A., Morace, A., Arikawa, Y., Yogo, A., Nakai, M., Norimatsu, T., d'Humiéres, E., Santos, J. J., Kondo, K., Sunahara, A., Gus'kov, S., and Tikhonchuk, V.

Subjects
Physics - Plasma Physics
Abstract

A relativistic laser pulse, confined in a cylindrical target, performs multiple scattering along the target surface. The confinement property of the target results in a very effcient interaction. This proccess, which is just yet another example of the "whispering gallery" effect, may pronounce itself in plenty of physical phenomena, including surface grazing electron acceleration and generation of relativistic magnetized plasma structures.

Published
2018
Full Text
View/download PDF

24. Laser electron acceleration on curved surfaces

Author

Korneev, Ph., Abe, Y., Law, K. -F. -F., Bochkarev, S. G., Fujioka, S., Kojima, S., Lee, S. -H., Sakata, S., Matsuo, K., Oshima, A., Morace, A., Arikawa, Y., Yogo, A., Nakai, M., Norimatsu, T., d'Humiéres, E., Santos, J. J., Kondo, K., Sunahara, A., Bychenkov, V. Yu., Gus'kov, S., and Tikhonchuk, V.

Subjects
Physics - Plasma Physics, Physics - Accelerator Physics
Abstract

Electron acceleration by relativistically intense laser beam propagating along a curved surface allows to split softly the accelerated electron bunch and the laser beam. The presence of a curved surface allows to switch an adiabatic invariant of electrons in the wave instantly leaving the gained energy to the particles. The efficient acceleration is provided by the presence of strong transient quasistationary fields in the interaction region and a long efficient acceleration length. The curvature of the surface allows to select the accelerated particles and provides their narrow angular distribution. The mechanism at work is explicitly demonstrated in theoretical models and experiments.

Published
2017

25. Emergence of MHD structures in a collisionless PIC simulation plasma

Author

Dieckmann, M E, Folini, D, Walder, R, Romagnani, L, d'Humieres, E, Bret, A, Karlsson, T, and Ynnerman, A

Subjects
Physics - Plasma Physics
Abstract

The expansion of a dense plasma into a dilute plasma across an initially uniform perpendicular magnetic field is followed with a one-dimensional particle-in-cell (PIC) simulation over MHD time scales. The dense plasma expands in the form of a fast rarefaction wave. The accelerated dilute plasma becomes separated from the dense plasma by a tangential discontinuity at its back. A fast magnetosonic shock with the Mach number 1.5 forms at its front. Our simulation demonstrates how wave dispersion widens the shock transition layer into a train of nonlinear fast magnetosonic waves., Comment: 5 pages, 4 figures, accepted for publication in Physics of Plasmas

Published
2017
Full Text
View/download PDF

26. Acceleration of collimated 45 MeV protons by collisionless shocks driven in low-density, large-scale gradient plasmas by a 10^20 W/cm^2, 1 micron wavelength laser

Author

Antici, P., Boella, E., Chen, S. N., Andrews, D. S., Barberio, M., Böker, J., Cardelli, F., Feugeas, J. L., Glesser, M., Nicolaï, P., Romagnani, L., Sciscio, M., Starodubtsev, M., Willi, O., Kieffer, J. C., Tikhonchuk, V., Pépin, H., Silva, L. O., Humières, E. d, and Fuchs, J.

Subjects
Physics - Plasma Physics
Abstract

A new type of proton acceleration stemming from large-scale gradients, low-density targets, irradiated by an intense near-infrared laser is observed. The produced protons are characterized by high-energies (with a broad spectrum), are emitted in a very directional manner, and the process is associated to relaxed laser (no need for high-contrast) and target (no need for ultra-thin or expensive targets) constraints. As such, this process appears quite effective compared to the standard and commonly used Target Normal Sheath Acceleration technique (TNSA), or more exploratory mechanisms like Radiation Pressure Acceleration (RPA). The data are underpinned by 3D numerical simulations which suggest that in these conditions Low Density Collisionless Shock Acceleration (LDCSA) is at play, which combines an initial Collisionless Shock Acceleration (CSA) to a boost procured by a TNSA-like sheath field in the downward density ramp of the target, which leads to an overall broad spectrum. Experiments performed at 10^20 W/cm^2 laser intensity show that LDCSA can accelerate, from ~1% critical density, mm-scale targets, up to 5x10^9 protons/MeV/sr/J with energies up to 45(+/- 5) MeV in a collimated (~6$^\circ$ half-angle) manner.

Published
2017

27. Collimated protons accelerated from an overdense gas jet irradiated by a 1 micron wavelength high-intensity short-pulse laser

Author

Chen, S. N., Vranic, M., Gangolf, T., Boella, E., Antici, P., Bailly-Grandvaux, M., Loiseau, P., Pépin, H., Revet, G., Santos, J. J., Schroer, A. M., Starodubtsev, M., Willi, O., Silva, L. O., Humières, E. d, and Fuchs, J.

Subjects
Physics - Plasma Physics
Abstract

We have investigated proton acceleration in the forward direction from a near-critical density hydrogen gas jet target irradiated by a high intensity (10^18 W/cm^2), short-pulse (5 ps) laser with wavelength of 1.054 micron. We observe the signature of shock acceleration driven by the laser pulse, leading to monoenergetic proton beams with small divergence in addition to the commonly used electron-sheath driven proton acceleration. The proton energies we obtained are modest (~MeV), but prospects for improvement are offered through tailoring the gas jet density profile. Also, we observe that this mechanism is very robust in producing those beams and thus can be considered as a future candidate in laser-driven ion sources driven by the upcoming next generation of multi-PW near-infrared lasers.

Published
2017

28. Stimulated Raman scattering in the relativistic regime in near-critical plasmas

Author

Moreau, J. G., d'Humières, E., Nuter, R., and Tikhonchuk, V. T.

Subjects
Physics - Plasma Physics
Abstract

Interaction of a high intensity short laser pulse with near-critical plasmas allows to achieve extremely high coupling efficiency and transfer laser energy to energetic ions. One dimensional Particle-In-Cell (PIC) simulations are considered to detail the processes involved in the energy transfer. A confrontation of the numerical results with the theory highlights a key role played by the process of stimulated Raman scattering in the relativistic regime. The interaction of a 1 ps laser pulse (I $\sim$ 6.10$^{18}$ W.cm$^2$) with an under-critical (0.5 $n_c$) homogeneous plasma leads to a very high plasma absorption reaching 68 % of the laser pulse energy. This permits a homogeneous electron heating all along the plasma and an efficient ion acceleration at the plasma edges and in cavities., Comment: 25 pages, 10 figures

Published
2016
Full Text
View/download PDF

29. Magnetization of laser-produced plasma in a chiral hollow target

Author

Korneev, Ph., Tikhonchuk, V., and d'Humières, E.

Subjects
Physics - Plasma Physics
Abstract

It is demonstrated that targets with a broken rotational symmetry may facilitate generation of a strong axial (poloidal) magnetic field. An intense laser beam irradiating such a target creates intense electron currents carrying vorticity and producing strong spontaneous magnetic fields. Combined with a laser electron acceleration, such targets may be used for generation and guiding of magnetized, collimated particle or plasma beams.

Published
2016
Full Text
View/download PDF

30. Pair creation in collision of $\gamma$--ray beams produced with high intensity lasers

Author

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

Subjects
Physics - Instrumentation and Detectors, Physics - Optics, Physics - Plasma Physics
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 $\gamma$--ray sources, estimate the expected number of electron--positron pairs and competing processes by using numerical simulations including quantum electrodynamic effects.

Published
2015
Full Text
View/download PDF

31. Laser-driven platform for generation and characterization of strong quasi-static magnetic fields

Author

Santos, J. J., Bailly-Grandvaux, M., Giuffrida, L., Forestier-Colleoni, P., Fujioka, S., Zhang, Z., Korneev, Ph., Bouillaud, R., Dorard, S., Batani, D., Chevrot, M., Cross, J., Crowston, R., Dubois, J. -L., Gazave, J., Gregori, G., d'Humières, E., Hulin, S., Ishihara, K., Kojima, S., Loyez, E., Marquès, J. -R., Morace, A., Nicolaï, Ph., Peyrusse, O., Poyé, A., Raffestin, D., Ribolzi, J., Roth, M., Schaumann, G., Serres, F., Tikhonchuk, V. T., Vacar, Ph., and Woolsey, N.

Subjects
Physics - Plasma Physics
Abstract

Quasi-static magnetic-fields up to $800\,$T are generated in the interaction of intense laser pulses ($500\,$J, $1\,$ns, $10^{17}\,$W/cm$^2$) with capacitor-coil targets of different materials. The reproducible magnetic-field peak and rise-time, consistent with the laser pulse duration, were accurately inferred from measurements with GHz-bandwidth inductor pickup coils (B-dot probes). Results from Faraday rotation of polarized optical laser light and deflectometry of energetic proton beams are consistent with the B-dot probe measurements at the early stages of the target charging, up to $t\approx 0.35\,$ns, and then are disturbed by radiation and plasma effects. The field has a dipole-like distribution over a characteristic volume of $1\,$mm$^3$, which is coherent with theoretical expectations. These results demonstrate a very efficient conversion of the laser energy into magnetic fields, thus establishing a robust laser-driven platform for reproducible, well characterized, generation of quasi-static magnetic fields at the kT-level, as well as for magnetization and accurate probing of high-energy-density samples driven by secondary powerful laser or particle beams., Comment: 16 pages, 7 figures

Published
2015

32. Amplified short-wavelength light scattered by relativistic electrons in the laser-induced optical lattice

Author

Andriyash, I. A., Tikhonchuk, V. T., Malka, V., d'Humières, E., and Balcou, Ph.

Subjects
Physics - Optics, Physics - Plasma Physics
Abstract

The scheme of the XUV/X-ray free electron laser based on the optical undulator created by two overlapped transverse laser beams is analyzed. A kinetic theoretical description and an ad hoc numerical model are developed to account for the finite energy spread, angular divergence and the spectral properties of the electron beam in the optical lattice. The theoretical findings are compared to the results of the one- and three-dimensional numerical modeling with the spectral free electron laser code PLARES., Comment: submitted to Phys. Rev. ST Accel. Beams

Published
2014

33. Giga-Gauss scale quasistatic magnetic field generation in an 'escargot' target

Author

Korneev, Ph., d'Humieres, E., and Tikhonchuk, V.

Subjects
Physics - Plasma Physics
Abstract

A simple setup for the generation of ultra-intense quasistatic magnetic fields, based on the generation of electron currents with a predefined geometry in a curved 'escargot' target, is proposed and analysed. Particle-In-Cell simulations and qualitative estimates show that giga-Gauss scale magnetic fields may be achieved with existent laser facilities. The described mechanism of the strong magnetic field generation may be useful in a wide range of applications, from laboratory astrophysics to magnetized ICF schemes., Comment: Submitted to PRL. arXiv admin note: text overlap with arXiv:1409.5246

Published
2014
Full Text
View/download PDF

34. Short Intense Laser Pulse Collapse in Near-Critical Plasma

Author

Sylla, F., Flacco, A., Kahaly, S., Veltcheva, M., Lifschitz, A., d'Humières, E., Tikhonchuk, V., and Malka, V.

Subjects
Physics - Plasma Physics
Abstract

It is observed that the interaction of an intense ultra-short laser pulse with an overdense gas jet results in the pulse collapse and the deposition of a significant part of energy in a small and well localized volume in the rising part of the gas jet, where the electrons are efficiently accelerated and heated. A collisionless plasma expansion over 150 microns at a sub-relativistic velocity (~c/3) has been optically monitored in time and space, and attributed to the quasistatic field ionization of the gas associated to the hot electron current. Numerical simulations in good agreement with the observations suggest the acceleration in the collapse region of relativistic electrons, along with the excitation of a sizeable magnetic dipole that sustains the electron current over several picoseconds. Perspectives of ion beam generation at high repetition rate directly from gas jets are discussed.

Published
2012
Full Text
View/download PDF

42. Energetic α -particle sources produced through proton-boron reactions by high-energy high-intensity laser beams

Author

Bonvalet, J., primary, Nicolaï, Ph., additional, Raffestin, D., additional, D'humieres, E., additional, Batani, D., additional, Tikhonchuk, V., additional, Kantarelou, V., additional, Giuffrida, L., additional, Tosca, M., additional, Korn, G., additional, Picciotto, A., additional, Morace, A., additional, Abe, Y., additional, Arikawa, Y., additional, Fujioka, S., additional, Fukuda, Y., additional, Kuramitsu, Y., additional, Habara, H., additional, and Margarone, D., additional

Published
2021
Full Text
View/download PDF

43. Proton acceleration by collisionless shocks using a supersonic H2 gas-jet target and high-power infrared laser pulses

Author

Puyuelo-Valdes, P., primary, Henares, J. L., additional, Hannachi, F., additional, Ceccotti, T., additional, Domange, J., additional, Ehret, M., additional, d'Humieres, E., additional, Lancia, L., additional, Marquès, J.-R., additional, Ribeyre, X., additional, Santos, J. J., additional, Tikhonchuk, V., additional, and Tarisien, M., additional

Published
2019
Full Text
View/download PDF

44. Leveraging extreme laser-driven magnetic fields for gamma-ray generation and pair production

Author

Jansen, O., Wang, T., Stark, D. J., D'Humieres, E., (0000-0001-7986-3631) Toncian, T., Arefiev, A. V., Jansen, O., Wang, T., Stark, D. J., D'Humieres, E., (0000-0001-7986-3631) Toncian, T., and Arefiev, A. V.

Abstract

he ability of an intense laser pulse to propagate in a classically over-critical plasma through the phenomenon of relativistic transparency is shown to facilitate the generation of strong plasma magnetic fields. Particle-in-cell simulations demonstrate that these fields significantly enhance the radiation rates of the laser-irradiated electrons, and furthermore they collimate the emission so that a directed and dense beam of multi-MeV gamma-rays is achievable. This capability can be exploited for electron-positron pair production via the linear Breit-Wheeler process by colliding two such dense beams. Presented simulations show that more than 103 pairs can be produced in such a setup, and the directionality of the positrons can be controlled by the angle of incidence between the beams.

Published
2018

46. Whispering gallery effect in relativistic optics, "Письма в Журнал экспериментальной и теоретической физики"

Author

Abe, Y., primary, Law, F K.F.F., additional, Korneev, Ph., additional, Fujioka, S., additional, Kojima, S., additional, Lee, S.-H., additional, Sakata, S., additional, Matsuo, K., additional, Oshima, A., additional, Morace, A., additional, Arikawa, Y., additional, Yogo, A., additional, Nakai, M., additional, Norimatsu, T., additional, D’Humieres, E., additional, Santos, J. J., additional, Кондо, К., additional, Sunahara, A., additional, Gus’kov, S., additional, and Tikhonchuk, V., additional

Published
2018
Full Text
View/download PDF

48. Unraveling resistive versus collisional contributions to relativistic electron beam stopping power in cold-solid and in warm-dense plasmas

Author

Vauzour, B, Debayle, A, Vaisseau, X, Hulin, S, Schlenvoigt, H, Batani, D, Baton, S, Honrubia, J, Nicolai, P, Beg, F, Benocci, R, Chawla, S, Coury, M, Dorchies, F, Fourment, C, D'Humieres, E, Jarrot, L, Mckenna, P, Rhee, Y, Tikhonchuk, V, Volpe, L, Yahia, V, Santos, J, Vauzour B., Debayle A., Vaisseau X., Hulin S., Schlenvoigt H. -P., Batani D., Baton S. D., Honrubia J. J., Nicolai Ph., Beg F. N., Benocci R., Chawla S., Coury M., Dorchies F., Fourment C., D'Humieres E., Jarrot L. C., McKenna P., Rhee Y. J., Tikhonchuk V. T., Volpe L., Yahia V., Santos J. J., Vauzour, B, Debayle, A, Vaisseau, X, Hulin, S, Schlenvoigt, H, Batani, D, Baton, S, Honrubia, J, Nicolai, P, Beg, F, Benocci, R, Chawla, S, Coury, M, Dorchies, F, Fourment, C, D'Humieres, E, Jarrot, L, Mckenna, P, Rhee, Y, Tikhonchuk, V, Volpe, L, Yahia, V, Santos, J, Vauzour B., Debayle A., Vaisseau X., Hulin S., Schlenvoigt H. -P., Batani D., Baton S. D., Honrubia J. J., Nicolai Ph., Beg F. N., Benocci R., Chawla S., Coury M., Dorchies F., Fourment C., D'Humieres E., Jarrot L. C., McKenna P., Rhee Y. J., Tikhonchuk V. T., Volpe L., Yahia V., and Santos J. J.

Abstract

We present results on laser-driven relativistic electron beam propagation through aluminum samples, which are either solid and cold or compressed and heated by laser-induced shock. A full numerical description of fast electron generation and transport is found to reproduce the experimental absolute K-alpha yield and spot size measurements for varying target thicknesses, and to sequentially quantify the collisional and resistive electron stopping powers. The results demonstrate that both stopping mechanisms are enhanced in compressed Al samples and are attributed to the increase in the medium density and resistivity, respectively. For the achieved time-and space-averaged electronic current density, < j(h)> similar to 8 x 10(10) A/cm(2) in the samples, the collisional and resistive stopping powers in warm and compressed Al are estimated to be 1.5 keV/mu m and 0.8 keV/mu m, respectively. By contrast, for cold and solid Al, the corresponding estimated values are 1.1 keV/mu m and 0.6 keV/mu m. Prospective numerical simulations involving higher j(h) show that the resistive stopping power can reach the same level as the collisional one. In addition to the effects of compression, the effect of the transient behavior of the resistivity of Al during relativistic electron beam transport becomes progressively more dominant, and for a significantly high current density, j(h) similar to 10(12) A/cm(2), cancels the difference in the electron resistive stopping power (or the total stopping power in units of areal density) between solid and compressed samples. Analytical calculations extend the analysis up to j(h) = 10(14) A/cm(2) (representative of the full-scale fast ignition scenario of inertial confinement fusion), where a very rapid transition to the Spitzer resistivity regime saturates the resistive stopping power, averaged over the electron beam duration, to values of similar to 1 keV/mu m. (C) 2014 AIP Publishing LLC.

Published
2014

49. Emergence of MHD structures in a collisionless PIC simulation plasma

Author

Dieckmann, M. E., Folini, D., Walder, R., Romagnani, L., d'Humieres, E., Bret, A., Karlsson, Tomas, Ynnerman, A., Dieckmann, M. E., Folini, D., Walder, R., Romagnani, L., d'Humieres, E., Bret, A., Karlsson, Tomas, and Ynnerman, A.

Abstract

The expansion of a dense plasma into a dilute plasma across an initially uniform perpendicular magnetic field is followed with a one-dimensional particle-in-cell simulation over magnetohydrodynamics time scales. The dense plasma expands in the form of a fast rarefaction wave. The accelerated dilute plasma becomes separated from the dense plasma by a tangential discontinuity at its back. A fast magnetosonic shock with the Mach number 1.5 forms at its front. Our simulation demonstrates how wave dispersion widens the shock transition layer into a train of nonlinear fast magnetosonic waves., QC 20171123

Published
2017
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results