Mean opacities of a strongly magnetized high temperature plasma

TL;DR

This paper computes mean opacities of strongly magnetized plasmas relevant to X-ray pulsars, accounting for magnetic effects, vacuum polarization, and electron-positron pairs, providing data and formulas for modeling emission regions.

Contribution

It presents detailed calculations of Rosseland and Planck mean opacities in strongly magnetized plasmas, including effects of vacuum polarization and pairs, with practical tabular data and approximate formulas.

Findings

Magnetic Planck opacity is significantly lower than non-magnetic at low temperatures.

Opacity increases dramatically at higher temperatures due to cyclotron processes.

Electron-positron pairs greatly enhance Rosseland opacity at high temperatures.

Abstract

Geometry and dynamical structure of emission regions in accreting pulsars are shaped by the interplay between gravity, radiation, and strong magnetic field, which significantly affects the opacities of a plasma and radiative pressure under such extreme conditions. Quantitative consideration of magnetic plasma opacities is, therefore, an essential ingredient of any self-consistent modeling of emission region structure of X-ray pulsars. We present results of computations of the Rosseland and Planck mean opacities of a strongly magnetized plasma with a simple chemical composition,namely the solar hydrogen/helium mix. We consider all relevant specific opacities of the magnetized plasma including vacuum polarization effect and contribution of electron-positron pairs where the pair number density is computed in the thermodynamic equilibrium approximation. The magnetic Planck mean opacity determines the radiative cooling of an optically thin strongly magnetized plasma. It is by factor of three smaller than non-magnetic Planck opacity at $k_{\rm B}T < 0.1\,E_{\rm cyc}$ and increases by a factor of $10^2 - 10^4$ at $k_{\rm B}T > 0.3\,E_{\rm cyc}$ due to cyclotron thermal processes. We propose a simple approximate expression which has sufficient accuracy for the magnetic Planck opacity description. We provide the Rosseland opacity in a tabular form computed in the temperature range 1 - 300 keV, magnetic field range $3 \times 10^{10} - 10^{15}$ G, and a broad range of plasma densities. We demonstrate that the scattering on the electron-positron pairs increases the Rosseland opacity drastically at temperatures >50 keV in the case of mass densities typical for accretion channel in X-ray pulsars.