Relativistic X-ray reflection from the accreting millisecond X-ray pulsar IGR J17498-2921

TL;DR

This paper reports the first detection of relativistic X-ray reflection features in the spectrum of the accreting millisecond X-ray pulsar IGR J17498-2921, providing insights into the accretion disk, magnetic field, and burst properties.

Contribution

It presents the first observation of reflection features in IGR J17498-2921 using NuSTAR, constraining the inner disk radius, system inclination, and magnetic field strength.

Findings

Detection of relativistic reflection features in the spectrum.

Upper limit on the inner disk radius of 6-9 R_ISCO.

Confirmation of thermonuclear X-ray bursts.

Abstract

The accreting millisecond X-ray pulsar IGR J17498-2921 went into X-ray outburst on April 13-15, 2023, for the first time since its discovery on August 11, 2011. Here, we report on the first follow-up \nustar{} observation of the source, performed on April 23, 2023, around ten days after the peak of the outburst. The \nustar{} spectrum of the persistent emission ($3-60$ \kev{} band) is well described by an absorbed blackbody with a temperature of $kT_{bb}=1.61\pm 0.04$\kev{}, most likely arising from the NS surface and a Comptonization component with power-law index $\Gamma=1.79\pm0.02$, arising from a hot corona at $kT_{e}=16\pm 2$ keV. The X-ray spectrum of the source shows robust reflection features which have not been observed before. We use a couple of self-consistent reflection models, {\tt relxill} and {\tt relxillCp}, to fit the reflection features. We find an upper limit to the inner disc radius of $ 6\: R_{ISCO}$ and $ 9\: R_{ISCO}$ from {\tt relxill} and {\tt relxillCp} model, respectively. The inclination of the system is estimated to be $\simeq 40\degr$ from both reflection models. Assuming magnetic truncation of the accretion disc, the upper limit of magnetic field strength at the pole of the NS is found to be $B\lesssim 1.8\times 10^{8}$ G. Furthermore, the \nustar{} observation revealed two type I X-ray bursts and the burst spectroscopy confirms the thermonuclear nature of the burst. The blackbody temperature reaches nearly $2.2$ keV at the peak of the burst.