Vacuum Polarization Effects in Baryon-Loaded Magnetar Bursts and Implications for X-ray Polarization

TL;DR

This paper develops a comprehensive framework to analyze vacuum polarization effects in baryon-loaded magnetar bursts, predicting X-ray polarization signatures that can reveal quantum electrodynamics phenomena and baryon content.

Contribution

It introduces a general model for vacuum resonance in a three-component plasma, including ions, electrons, and positrons, in magnetar bursts, expanding previous simpler models.

Findings

Establishes criteria for vacuum resonance in baryon-loaded plasmas.

Analyzes adiabatic and nonadiabatic mode conversions.

Predicts characteristic X-ray polarization signatures for observations.

Abstract

Magnetars provide natural laboratories for strong-field quantum electrodynamics processes, such as vacuum polarization, which gives rise to vacuum resonance together with the plasma response. We develop a general framework to describe vacuum resonance in a three-component plasma consisting of ions, electrons, and positrons, as expected in baryon-loaded magnetar bursts. By introducing a parametrization of the plasma composition, we establish the general criterion for the occurrence of vacuum resonance in such plasmas. Our analysis encompasses both Mikheyev-Smirnov-Wolfenstein-like adiabatic mode conversion and nonadiabatic eigenmode transition, highlighting their dependence on the plasma composition. Applying this framework to baryon-loaded fireballs in magnetar bursts, we estimate the characteristic X-ray polarization signatures. Detection of these polarizations will provide observational signatures of vacuum polarization as well as baryon loading in magnetar fireballs.