Particle acceleration mechanisms

TL;DR

This paper reviews mechanisms for producing non-thermal electrons in galaxy clusters, focusing on shock, turbulence, and plasma wave acceleration, and discusses their roles in hard X-ray and radio emissions.

Contribution

It compares two scenarios for non-thermal radiation production, highlighting the limitations of non-thermal Bremsstrahlung and emphasizing the importance of episodic relativistic electron injection.

Findings

Non-thermal tails from non-thermal Bremsstrahlung are short-lived and can't explain radio emission.

Relativistic electron injection from galaxies or AGN can produce observable non-thermal radiation.

Steady state electron spectra may not match observations without short escape times.

Abstract

We review the possible mechanisms for production of non-thermal electrons which are responsible for non-thermal radiation in clusters of galaxies. Our primary focus is on non-thermal Bremsstrahlung and inverse Compton scattering, that produce hard X-ray emission. We briefly review acceleration mechanisms and point out that in most astrophysical situations, and in particular for the intracluster medium, shocks, turbulence and plasma waves play a crucial role. We consider two scenarios for production of non-thermal radiation. The first is hard X-ray emission due to non-thermal Bremsstrahlung by nonrelativistic particles. Non-thermal tails are produced by accelerating electrons from the background plasma with an initial Maxwellian distribution. However, these tails are accompanied by significant heating and they are present for a short time of <10^6 yr, which is also the time that the tail will be thermalised. Such non-thermal tails, even if possible, can only explain the hard X-ray but not the radio emission which needs GeV or higher energy electrons. For these and for production of hard X-rays by the inverse Compton model, we need the second scenario where there is injection and subsequent acceleration of relativistic electrons. It is shown that a steady state situation, for example arising from secondary electrons produced from cosmic ray proton scattering by background protons, will most likely lead to flatter than required electron spectra or it requires a short escape time of the electrons from the cluster. An episodic injection of relativistic electrons, presumably from galaxies or AGN, and/or episodic generation of turbulence and shocks by mergers can result in an electron spectrum consistent with observations but for only a short period of less than one billion years.