The saturation of the electron beam filamentation instability by the self-generated magnetic field and magnetic pressure gradient-driven electric field

TL;DR

This study uses particle-in-cell simulations to analyze how electron beam filamentation instability saturates through self-generated magnetic fields and pressure-driven electric fields, revealing size-dependent magnetic saturation and electron heating effects.

Contribution

It demonstrates the size dependence of magnetic field saturation and the role of electrostatic fields in filamentation instability, challenging existing magnetic trapping models.

Findings

Magnetic field amplitude at saturation scales with filament size.

Electrostatic forces oscillate around the magnetic pressure gradient force.

Larger filaments lead to increased electron heating and speed modulation.

Abstract

Two counter-propagating cool and equally dense electron beams are modelled with particle-in-cell (PIC) simulations. The electron beam filamentation instability is examined in one spatial dimension. The box length resolves one pair of current filaments. A small, a medium-sized and a large filament are considered and compared. The magnetic field amplitude at the saturation time of the filamentation instability is proportional to the filament size. It is demonstrated, that the force on the electrons imposed by the electrostatic field, which develops during the nonlinear stage of the instability, oscillates around a mean value that equals the magnetic pressure gradient force. The forces acting on the electrons due to the electrostatic and the magnetic field have a similar strength. The electrostatic field reduces the confining force close to the stable equilibrium of each filament and increases it farther away. The confining potential is not sinusoidal, as assumed by the magnetic trapping model, and it permits an overlap of current filaments (plasmons) with an opposite flow direction. The scaling of the saturation amplitude of the magnetic field with the filament size observed here thus differs from that expected from the magnetic trapping model. The latter nevertheless gives a good estimate for the magnetic saturation amplitude. The increase of the peak electrostatic and magnetic field amplitudes with the filament size implies, that the electrons heat up more and that the spatial modulation of their mean speed along the beam flow direction increases with the filament size.