Your search keyword '"Bellei C"' showing total 4 results

1. Species separation and kinetic effects in collisional plasma shocks.

Author

Bellei, C., Rinderknecht, H., Zylstra, A., Rosenberg, M., Sio, H., Petrasso, R., Wilks, S. C., and Amendt, P. A.

Subjects

*PLASMA shock waves, *THEORY of wave motion, *ELECTRIC fields, *ION temperature, *GEOMETRY

Abstract

The properties of collisional shock waves propagating in uniform plasmas are studied with ionkinetic calculations, in both slab and spherical geometry and for the case of one and two ion species. Despite the presence of an electric field at the shock front-and in contrast to the case where an interface is initially present [C. Bellei et al., Phys. Plasmas 20, 044702 (2013)]- essentially no ion reflection at the shock front is observed due to collisions, with a probability of reflection ≲10-4 for the cases presented. A kinetic two-ion-species spherical convergent shock is studied in detail and compared against an average-species calculation, confirming effects of species separation and differential heating of the ion species at the shock front. The effect of different ion temperatures on the DT and D3He fusion reactivity is discussed in the fluid limit and is estimated to be moderately important. [ABSTRACT FROM AUTHOR]

Published

2014

2. Fast ignition: Dependence of the ignition energy on source and target parameters for particle-in-cell-modelled energy and angular distributions of the fast electrons.

Author

Bellei, C., Divol, L., Kemp, A. J., Key, M. H., Larson, D. J., Strozzi, D. J., Marinak, M. M., Tabak, M., and Patel, P. K.

Subjects

*COMBUSTION, *PARAMETER estimation, *ANGULAR distribution (Nuclear physics), *PARTICLES (Nuclear physics), *ELECTRONS, *NUCLEAR fuels, *ELECTRIC fields

Abstract

The energy and angular distributions of the fast electrons predicted by particle-in-cell (PIC) simulations differ from those historically assumed in ignition designs of the fast ignition scheme. Using a particular 3D PIC calculation, we show how the ignition energy varies as a function of source-fuel distance, source size, and density of the pre-compressed fuel. The large divergence of the electron beam implies that the ignition energy scales with density more weakly than the ρ-2 scaling for an idealized beam [S. Atzeni, Phys. Plasmas 6, 3316 (1999)], for any realistic source that is at some distance from the dense deuterium-tritium fuel. Due to the strong dependence of ignition energy with source-fuel distance, the use of magnetic or electric fields seems essential for the purpose of decreasing the ignition energy. [ABSTRACT FROM AUTHOR]

Published

2013

3. Proton trajectories and electric fields in a laser-accelerated focused proton beam.

Author

Foord, M. E., Bartal, T., Bellei, C., Key, M., Flippo, K., Stephens, R. B., Patel, P. K., McLean, H. S., Jarrott, L. C., Wei, M. S., and Beg, F. N.

Subjects

PROTON beams, PARTICLE tracks (Nuclear physics), ELECTRIC fields, LASER beams, COMPARATIVE studies, ENERGY density, PARTICLES (Nuclear physics)

Abstract

The focusing properties of a laser generated proton beam have been investigated using hemispherical targets in both freestanding and enclosed cone-shaped geometries. The proton trajectories and focusing were strongly affected by the electric fields in the beam, bending the trajectories near the axis. In the cone targets, a sheath field effectively channels the proton beam through the open cone tip, substantially improving the beam focusing from ≈90 μm to ≈55 μm diameter for protons with energies >3 MeV. The proton generation and focusing were modeled using 2D hybrid particle-in-cell simulations, which compared well with the experimental results. Simulations predict further improvement in focusing with more uniform target illumination. These results are of significant interest to proton fast ignition and other high energy density physics applications. [ABSTRACT FROM AUTHOR]

Published

2012

4. The potential role of electric fields and plasma barodiffusion on the inertial confinement fusion database.

Author

Amendt, Peter, Wilks, S. C., Bellei, C., Li, C. K., and Petrasso, R. D.

Subjects

ELECTRIC fields, PLASMA dynamics, INERTIAL confinement fusion, ELECTRIC charge, MECHANICAL shock, STAGNATION point

Abstract

The generation of strong, self-generated electric fields (GV/m) in direct-drive, inertial-confinement-fusion (ICF) capsules has been reported [Rygg et al., Science 319, 1223 (2008); Li et al., Phys. Rev. Lett. 100, 225001 (2008)]. A candidate explanation for the origin of these fields based on charge separation across a plasma shock front was recently proposed [Amendt et al., Plasma Phys. Controlled Fusion 51 124048 (2009)]. The question arises whether such electric fields in imploding capsules can have observable consequences on target performance. Two well-known anomalies come to mind: (1) an observed ≈2× greater-than-expected deficit of neutrons in an equimolar D3He fuel mixture compared with hydrodynamically equivalent D [Rygg et al., Phys. Plasmas 13, 052702 (2006)] and DT [Herrmann et al., Phys. Plasmas 16, 056312 (2009)] fuels, and (2) a similar shortfall of neutrons when trace amounts of argon are mixed with D in indirect-drive implosions [Lindl et al., Phys. Plasmas 11, 339 (2004)]. A new mechanism based on barodiffusion (or pressure gradient-driven diffusion) in a plasma is proposed that incorporates the presence of shock-generated electric fields to explain the reported anomalies. For implosions performed at the Omega laser facility [Boehly et al., Opt. Commun. 133, 495 (1997)], the (low Mach number) return shock has an appreciable scale length over which the lighter D ions can diffuse away from fuel center. The depletion of D fuel is estimated and found to lead to a corresponding reduction in neutrons, consistent with the anomalies observed in experiments for both argon-doped D fuels and D3He equimolar mixtures. The reverse diffusional flux of the heavier ions toward fuel center also increases the pressure from a concomitant increase in electron number density, resulting in lower stagnation pressures and larger imploded cores in agreement with gated, self-emission, x-ray imaging data. [ABSTRACT FROM AUTHOR]

Published

2011