Magnetically driven coupling in relativistic radiation-mediated shocks

TL;DR

This paper investigates how magnetic fields influence the development of microturbulence in relativistic radiation-mediated shocks, providing thresholds for magnetic suppression of plasma instabilities relevant to cosmic explosions.

Contribution

It introduces a model to determine the critical magnetization parameter that suppresses kinetic instabilities in relativistic shocks with different plasma compositions.

Findings

Critical magnetization parameter $\sigma_c \\approx 10^{-7}$ for single ion plasma

Rapid growth of pair multiplicities with increasing magnetization

Suppression of plasma instabilities depends on plasma composition and magnetization

Abstract

The radiation drag in photon-rich environments of cosmic explosions can seed kinetic instabilities by inducing velocity spreads between relativistically streaming plasma components. Such microturbulence is likely imprinted on the breakout signals of radiation-mediated shocks. However, large-scale, transverse magnetic fields in the deceleration region of the shock transition can suppress the dominant kinetic instabilities by preventing the development of velocity separations between electron-positron pairs and a heavy ion species. We use a one-dimensional (1D) five-fluid radiative transfer code to generate self-consistent profiles of the radiation drag force and plasma composition in the deceleration region. For increasing magnetization, our models predict rapidly growing pair multiplicities and a substantial radiative drag developing self-similarly throughout the deceleration region. We extract the critical magnetization parameter $\sigma_{c}$, determining the limiting magnetic field strength at which a three-species plasma can develop kinetic instabilities before reaching the isotropized downstream. For a relativistic, single ion plasma drifting with $\gamma_{u} = 10$ in the upstream of a relativistic radiation-mediated shock, we find the threshold $\sigma_{c}\approx 10^{-7}$ for the onset of microturbulence. Suppression of plasma instabilities in the case of multi-ion composition would likely require much higher values of $\sigma_{c}$. Identifying high-energy signatures of microturbulence in shock-breakout signals and combining them with the magnetization limits provided in this work will allow a deeper understanding of the magnetic environment of cosmic explosions like supernovae, gamma-ray bursts, and neutron star binary mergers.