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Bibliographic Details
Main Authors: Marret, Alexis, Ciardi, Andrea, Smets, Roch
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.18978
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author Marret, Alexis
Ciardi, Andrea
Smets, Roch
author_facet Marret, Alexis
Ciardi, Andrea
Smets, Roch
contents The non-thermal particles escaping from collisionless shocks into the surrounding medium can trigger a non-resonant streaming instability that converts parts of their drift kinetic energy into large amplitude magnetic field perturbations, and promote the confinement and acceleration of high energy cosmic rays. We present simulations of the instability using an hybrid-Particle-in-Cell approach including Monte Carlo collisions, and demonstrate that the development of the non-resonant mode is associated with important ion pressure anisotropies in the background plasma. Depending on the initial conditions, the anisotropies may act on the instability by lowering its growth and trigger secondary micro-instabilities. Introducing collisions with neutrals yield a strong reduction of the magnetic field amplification as predicted by linear fluid theory. In contrast, Coulomb collisions in fully ionized plasmas are found to mitigate the self-generated pressure anisotropies and promote the growth of the magnetic field.
format Preprint
id arxiv_https___arxiv_org_abs_2407_18978
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Interplay between the non-resonant streaming instability and self-generated pressure anisotropies
Marret, Alexis
Ciardi, Andrea
Smets, Roch
Plasma Physics
High Energy Astrophysical Phenomena
The non-thermal particles escaping from collisionless shocks into the surrounding medium can trigger a non-resonant streaming instability that converts parts of their drift kinetic energy into large amplitude magnetic field perturbations, and promote the confinement and acceleration of high energy cosmic rays. We present simulations of the instability using an hybrid-Particle-in-Cell approach including Monte Carlo collisions, and demonstrate that the development of the non-resonant mode is associated with important ion pressure anisotropies in the background plasma. Depending on the initial conditions, the anisotropies may act on the instability by lowering its growth and trigger secondary micro-instabilities. Introducing collisions with neutrals yield a strong reduction of the magnetic field amplification as predicted by linear fluid theory. In contrast, Coulomb collisions in fully ionized plasmas are found to mitigate the self-generated pressure anisotropies and promote the growth of the magnetic field.
title Interplay between the non-resonant streaming instability and self-generated pressure anisotropies
topic Plasma Physics
High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2407.18978