X-ray spectral analysis of the neutron star in SNR 1E 0102.2-7219

TL;DR

This study re-analyzed Chandra X-ray data of SNR 1E 0102.2-7219 to investigate the properties of a potential neutron star, finding spectral evidence consistent with a high magnetic field and high thermal luminosity, suggesting a magnetar-like object.

Contribution

It provides a detailed spectral analysis supporting the presence of a neutron star with a high magnetic field in SNR 1E 0102.2-7219, using advanced modeling and background correction.

Findings

Blackbody + power-law fits suggest a young pulsar-like neutron star.

Carbon atmosphere model with B=10^12 G best fits the spectra.

High thermal luminosity can be explained by magnetic field decay or slow cooling.

Abstract

We re-analysed numerous archival Chandra X-ray observations of the bright supernova remnant (SNR) 1E 0102.2-7219 in the Small Magellanic Cloud, to validate the detection of a neutron star (NS) in the SNR by Vogt et al. (2018). Careful attention to the background is necessary for this spectral analysis. We find that a blackbody + power-law model is a decent fit, suggestive of a relatively strong B field and synchrotron radiation, as in a normal young pulsar, though the thermal luminosity would be unusually high for young pulsars. Among realistic NS atmosphere models, a carbon atmosphere with B = 10^12 G best fits the observed X-ray spectra. Comparing its unusually high thermal luminosity (L_{bol} = 1.1^{+1.6}_{-0.5}*10^34 ergs/s) to other NSs, we find that its luminosity can be explained by the decay of an initially strong magnetic field (as in magnetars or high B-field pulsars) or by slower cooling after the supernova explosion. The nature of the NS in this SNR (and of others in the Magellanic Clouds) could be nicely confirmed by an X-ray telescope with an angular resolution like Chandra, but superior spectral resolution and effective area, such as the Lynx concept.