Fitting XMM-Newton Observations of the AXP 1RXS J170849.0-400910 with four magnetar surface emission models, and predictions for X-ray polarization observations with IXPE

TL;DR

This study introduces a new X-ray spectral fitting model for magnetars, tests it on archival data, and predicts how future IXPE polarization observations can distinguish between different surface emission models and test quantum electrodynamics effects.

Contribution

The paper presents a novel X-ray fitting model for magnetar surface emission and demonstrates its application to archival data, also forecasting the potential of IXPE polarization observations to differentiate models.

Findings

Fixed-ions condensed surface model best fits the data.

Magnetized atmosphere model poorly fits the data.

IXPE can distinguish high- and low-polarization emission models.

Abstract

Phase-resolved spectral and spectropolarimetric X-ray observations of magnetars present us with the opportunity to test models of the origin of the X-ray emission from these objects, and to constrain the properties of the neutron star surface and atmosphere. We present a new X-ray fitting model for magnetars that accounts for four different emission models including a blackbody emission model, a magnetized atmosphere model, and fixed-ions and free-ions surface emission models. We use the new model for a phase resolved fit of archival XMM-Newton observations of the magnetar 1RXS J170849.0-400910. We find that the fixed-ions condensed surface model gives the best description of the phase-resolved XMM-Newton spectra, followed by the blackbody and free-ions condensed surface models. The magnetized atmosphere model gives a poor description of the data and seems to be largely excluded. We use the new fitting model to evaluate the scientific potential of future spectropolarimetric observations of 1RXS J170849.0-400910 with the Imaging X-ray Polarimetry Explorer (IXPE) scheduled for launch in December 2021. Our simulations show that the IXPE observations of sources such as 1RXS J170849.0-400910 will allow us to cleanly distinguish between high-polarization (blackbody, magnetized atmosphere) and low-polarization (condensed surface) models. If the higher-polarization blackbody or magnetized atmosphere models apply, IXPE can easily prove QED effects based on a 200 ksec observation as studied here. Longer IXPE observation times will be needed for a clear detection in the case of the lower-polarization condensed surface models.