Litcius/Paper detail

The cosmic ray-driven streaming instability in astrophysical and space plasmas

Alexandre Marcowith, Allard Jan van Marle, Illya Plotnikov

2021Physics of Plasmas34 citationsDOIOpen Access PDF

Abstract

Energetic non-thermal particles, or cosmic rays, are a major component of astrophysical plasmas next to magnetic fields, radiation, and thermal gas. Cosmic rays are usually sub-dominant in density but carry as much pressure as the thermal plasma background. In some cases, cosmic rays drift at faster speeds with respect to the normal modes' phase speeds of the background plasma. Because of this, cosmic rays are a strong source of free energy that causes new classes of kinetic or convective instabilities. Recent years have seen the development of intense analytical and numerical efforts to analyze the onset of an instability produced by the motion of these particles at fast bulk speeds: this is the streaming instability. The streaming instability has been applied to different space plasmas and astrophysical contexts like strong shocks, jets, or in interstellar and intergalactic medium studies. Streaming instabilities participate in the production of magnetic turbulence at scales corresponding to the gyroradius of the particles. By scattering off their self-generated waves, cosmic rays are coupled to the background thermal plasma. This mechanism is able to self-confine cosmic rays around sources and launch winds out of the disk of the galaxy, hence impacting galactic matter dynamics and ultimately the galactic star formation rate. We discuss a few science cases, which should be accessible in the near future for analytical calculations and numerical simulations.

Topics & Concepts

PhysicsStreaming instabilityCosmic rayInstabilityAstrophysicsPlasmaGyroradiusAstrophysical plasmaInterstellar mediumGalaxyAstronomyComputational physicsMechanicsSolar SystemNuclear physicsPlanetesimalAstrophysics and Cosmic PhenomenaSolar and Space Plasma DynamicsGamma-ray bursts and supernovae