Numerical simulations of energy transfer in counter-streaming plasmas

S. P. Davis; R. Capdessus; E. d'Humières; S. Jequier; I. Andriyash; V. Tikhonchuk

doi:10.1016/j.hedp.2012.11.009

Numerical simulations of energy transfer in counter-streaming plasmas

S. P. Davis
, R. Capdessus
, E. d'Humières
, S. Jequier
, I. Andriyash
, V. Tikhonchuk

Univ. Bordeaux

Research output: Contribution to journal › Article › peer-review

Abstract

Collisionless shock formation is investigated with large scale fully electromagnetic two-dimensional Particle-in-Cell numerical simulations. Two plasmas are colliding in the center of mass reference frame at sub-relativistic velocities. Their interaction leads to collisionless stochastic electron heating, ion slowing down and formation of a shock front. We focus here on the initial stage of evolution where electron heating is due to the Weibel-like micro-instability driven by the high-speed ion flow. A two stage process is described in the detailed analysis of our simulation results. Filament generation, followed by turbulent mixing, constitute the dominant mechanism for energy repartition. The global properties are illustrated by examination of single filament evolution in terms of energy/particle density and fields.

Original language	English
Pages (from-to)	231-238
Number of pages	8
Journal	High Energy Density Physics
Volume	9
Issue number	1
DOIs	https://doi.org/10.1016/j.hedp.2012.11.009
Publication status	Published - 1 Mar 2013
Externally published	Yes

Keywords

Electron heating
Fast ion streams
Weibel instability

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10.1016/j.hedp.2012.11.009

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abstract = "Collisionless shock formation is investigated with large scale fully electromagnetic two-dimensional Particle-in-Cell numerical simulations. Two plasmas are colliding in the center of mass reference frame at sub-relativistic velocities. Their interaction leads to collisionless stochastic electron heating, ion slowing down and formation of a shock front. We focus here on the initial stage of evolution where electron heating is due to the Weibel-like micro-instability driven by the high-speed ion flow. A two stage process is described in the detailed analysis of our simulation results. Filament generation, followed by turbulent mixing, constitute the dominant mechanism for energy repartition. The global properties are illustrated by examination of single filament evolution in terms of energy/particle density and fields.",

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T1 - Numerical simulations of energy transfer in counter-streaming plasmas

AU - Davis, S. P.

AU - Capdessus, R.

AU - d'Humières, E.

AU - Jequier, S.

AU - Andriyash, I.

AU - Tikhonchuk, V.

PY - 2013/3/1

Y1 - 2013/3/1

N2 - Collisionless shock formation is investigated with large scale fully electromagnetic two-dimensional Particle-in-Cell numerical simulations. Two plasmas are colliding in the center of mass reference frame at sub-relativistic velocities. Their interaction leads to collisionless stochastic electron heating, ion slowing down and formation of a shock front. We focus here on the initial stage of evolution where electron heating is due to the Weibel-like micro-instability driven by the high-speed ion flow. A two stage process is described in the detailed analysis of our simulation results. Filament generation, followed by turbulent mixing, constitute the dominant mechanism for energy repartition. The global properties are illustrated by examination of single filament evolution in terms of energy/particle density and fields.

AB - Collisionless shock formation is investigated with large scale fully electromagnetic two-dimensional Particle-in-Cell numerical simulations. Two plasmas are colliding in the center of mass reference frame at sub-relativistic velocities. Their interaction leads to collisionless stochastic electron heating, ion slowing down and formation of a shock front. We focus here on the initial stage of evolution where electron heating is due to the Weibel-like micro-instability driven by the high-speed ion flow. A two stage process is described in the detailed analysis of our simulation results. Filament generation, followed by turbulent mixing, constitute the dominant mechanism for energy repartition. The global properties are illustrated by examination of single filament evolution in terms of energy/particle density and fields.

KW - Electron heating

KW - Fast ion streams

KW - Weibel instability

UR - https://www.scopus.com/pages/publications/84873914532

U2 - 10.1016/j.hedp.2012.11.009

DO - 10.1016/j.hedp.2012.11.009

M3 - Article

AN - SCOPUS:84873914532

SN - 1574-1818

VL - 9

SP - 231

EP - 238

JO - High Energy Density Physics

JF - High Energy Density Physics

IS - 1

ER -

Numerical simulations of energy transfer in counter-streaming plasmas

Abstract

Keywords

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