Cosmic Rays and Radiative Instabilities

TL;DR

This paper investigates how cosmic rays influence the stability of radiative interstellar media, revealing that their effects depend on the energy conversion efficiency and impact shock stability and overstability.

Contribution

It provides a fluid-based analysis of cosmic ray effects on radiative shock stability, highlighting conditions under which cosmic rays alter or do not alter stability.

Findings

Cosmic rays do not affect stability of uniform, static media against isobaric perturbations.

Cosmic rays influence stability against isentropic perturbations.

Low energy conversion efficiency leads to cosmic-ray dominated shocks without overstability.

Abstract

In the absence of magnetic fields and cosmic rays, radiative cooling laws with a range of dependences on temperature affect the stability of interstellar gas. For about four and a half decades, astrophysicists have recognised the importance of the thermal instablity for the formation of clouds in the interstellar medium. Even in the past several years, many papers have concerned the role of the thermal instability in the production of molecular clouds. About three and a half decades ago, astrophysicists investigating radiative shocks noticed that for many cooling laws such shocks are unstable. Attempts to address the effects of cosmic rays on the stablity of radiative media that are initially uniform or that have just passed through shocks have been made. The simplest approach to such studies involves the assumption that the cosmic rays behave as a fluid. Work based on such an approach is described. Cosmic rays have no effect on the stability of initially uniform, static media with respect to isobaric perturbations, though they do affect the stability of such media with respect to isentropic perturbations. The effect of cosmic rays on the stability of radiative shocked media depends greatly on the efficiency of the conversion of energy in accelerated cosmic rays into thermal energy in the thermalized fluid. If that efficiency is low, radiative cooling makes weak shocks propagating into upstream media with low cosmic-ray pressures more likely to be cosmic-ray dominated than adiabatic shocks of comparable strength. The cosmic-ray dominated shocks do not display radiative overstability. Highly efficient conversion of cosmic-ray energy into thermal energy leads shocked media to behave as they do when cosmic rays are absent.