Probing magnetar emission mechanisms with spectropolarimetry

TL;DR

This paper predicts the X-ray polarization signatures of magnetars using realistic emission models, highlighting how polarization observations can distinguish between different surface and magnetospheric emission scenarios.

Contribution

It provides the first detailed polarization predictions for magnetars incorporating comprehensive physics, aiding future X-ray polarimetry observations.

Findings

Different surface models produce similar spectra but distinct polarization signatures.

Polarization observations can differentiate between atmospheric and condensed surface scenarios.

Hard X-ray scattering explains the rising emission in quiescent magnetars.

Abstract

Over the next year, a new era of observations of compact objects in X-ray polarization will commence. Among the key targets for the upcoming Imaging X-ray Polarimetry Explorer mission, will be the magnetars 4U 0142+61 and 1RXS J170849.0-400910. Here we present the first detailed predictions of the expected polarization from these sources that incorporate realistic models of emission physics at the surface (gaseous or condensed), the temperature distribution on the surface, general relativity, quantum electrodynamics and scattering in the magnetosphere, and also account for the broadband spectral energy distribution of these sources from below 1 keV to nearly 100 keV. We find that either atmospheres or condensed surfaces can account for the emission at a few keV; in both cases either a small hot polar cap or scattering is required to account for the emission at 5-10 keV, and above 10 keV scattering by a hard population of electrons can account for the rising power in the hard X-rays observed in many magnetars in quiescence. Although these different scenarios result in very similar spectral energy distributions, they generate dramatically different polarization signatures from 2-10 keV, which is the range of sensitivity of the Imaging X-ray Polarimetry Explorer. Observations of these sources in X-ray polarization will therefore probe the emission from magnetars in an essentially new way.