Growth of Beam-Plasma Instabilities in the Presence of Background Inhomogeneity

We explore how inhomogeneity in the background plasma number density alters the growth of electrostatic unstable wavemodes of beam-plasma systems. This is particularly interesting for blazar-driven beam-plasma instabilities, which may be suppressed by inhomogeneities in the intergalactic medium (IGM...

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Veröffentlicht in:	The Astrophysical journal 2018-05, Vol.859 (1), p.45
Hauptverfasser:	Shalaby, Mohamad, Broderick, Avery E., Chang, Philip, Pfrommer, Christoph, Lamberts, Astrid, Puchwein, Ewald
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Sprache:	eng
Schlagworte:	Astrophysics Blazars Density Growth rate Inhomogeneity instabilities Instability Intergalactic media Kinetic energy Langmuir waves Magnetohydrodynamic stability methods: numerical Particle in cell technique Plasma Plasma instabilities plasmas relativistic processes Stability waves
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creator	Shalaby, Mohamad Broderick, Avery E. Chang, Philip Pfrommer, Christoph Lamberts, Astrid Puchwein, Ewald
description	We explore how inhomogeneity in the background plasma number density alters the growth of electrostatic unstable wavemodes of beam-plasma systems. This is particularly interesting for blazar-driven beam-plasma instabilities, which may be suppressed by inhomogeneities in the intergalactic medium (IGM) as was recently claimed in the literature. Using high-resolution particle-in-cell simulations with the SHARP code, we show that the growth of the instability is local, i.e., regions with almost homogeneous background density will support the growth of the Langmuir waves even when they are separated by strongly inhomogeneous regions, resulting in an overall slower growth of the instability. We also show that if the background density is continuously varying, the growth rate of the instability is lower, although in all cases the system remains within the linear regime longer and the instability is not extinguished. In all cases, the beam loses approximately the same fraction of its initial kinetic energy in comparison to the uniform case at nonlinear saturation. Thus, inhomogeneities in the IGM are unlikely to suppress the growth of blazar-driven beam-plasma instabilities.
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J</addtitle><description>We explore how inhomogeneity in the background plasma number density alters the growth of electrostatic unstable wavemodes of beam-plasma systems. This is particularly interesting for blazar-driven beam-plasma instabilities, which may be suppressed by inhomogeneities in the intergalactic medium (IGM) as was recently claimed in the literature. Using high-resolution particle-in-cell simulations with the SHARP code, we show that the growth of the instability is local, i.e., regions with almost homogeneous background density will support the growth of the Langmuir waves even when they are separated by strongly inhomogeneous regions, resulting in an overall slower growth of the instability. We also show that if the background density is continuously varying, the growth rate of the instability is lower, although in all cases the system remains within the linear regime longer and the instability is not extinguished. In all cases, the beam loses approximately the same fraction of its initial kinetic energy in comparison to the uniform case at nonlinear saturation. 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subjects	Astrophysics Blazars Density Growth rate Inhomogeneity instabilities Instability Intergalactic media Kinetic energy Langmuir waves Magnetohydrodynamic stability methods: numerical Particle in cell technique Plasma Plasma instabilities plasmas relativistic processes Stability waves
title	Growth of Beam-Plasma Instabilities in the Presence of Background Inhomogeneity
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