X-ray polarization of the magnetar 1E 1841-045

TL;DR

This study presents the first X-ray polarization measurements of the magnetar 1E 1841-045 during an enhanced state, revealing polarization properties of its spectral components and supporting models involving Comptonized corona and resonant inverse Compton scattering.

Contribution

First spectropolarimetric analysis of a magnetar in an enhanced state, providing insights into emission mechanisms and polarization characteristics of different spectral components.

Findings

Polarization degree increases with energy, reaching up to 70% at 6-8 keV.

Soft and hard spectral components exhibit distinct polarization degrees and angles.

Model comparisons suggest Comptonized corona and inverse Compton scattering as plausible emission processes.

Abstract

We report on IXPE and NuSTAR observations beginning forty days after the 2024 outburst onset of magnetar 1E 1841-045, marking the first IXPE observation of a magnetar in an enhanced state. Our spectropolarimetric analysis indicates that both a blackbody (BB) plus double power-law (PL) and a double blackbody plus power-law spectral model fit the phase-averaged intensity data well, with a hard PL tail ($\Gamma$=1.19 and 1.35, respectively) dominating above $\approx 5$ keV. For the former model, we find the soft PL (the dominant component at soft energies) exhibits a polarization degree (PD) of $\approx 30\%$ while the hard PL displays a PD of $\approx 40\%$. Similarly, the cool BB of the 2BB+PL model possesses a PD of $\approx 15\%$ and a hard PL PD of $\approx 57\%$. For both models, each component has a polarization angle (PA) compatible with celestial north. Model-independent polarization analysis supports these results, wherein the PD increases from$ \approx 15\%$ to $\approx 70\%$ in the 2-3 keV and 6-8 keV ranges, respectively, while the PA remains nearly constant. We find marginal evidence for phase-dependent variability of the polarization properties, namely a higher PD at phases coinciding with the hard X-ray pulse peak. We compare the hard X-ray PL to the expectation from resonant inverse Compton scattering (RICS) and secondary pair cascade synchrotron radiation from primary high-energy RICS photons; both present reasonable spectropolarimetric agreement with the data, albeit, the latter more naturally. We suggest that the soft PL X-ray component may originate from a Comptonized corona in the inner magnetosphere.