Probing the interstellar medium toward GRB 221009A through X-ray dust scattering

TL;DR

This study uses X-ray dust-scattering rings around GRB 221009A to map the interstellar medium with high resolution, revise the GRB's X-ray fluence estimate, and analyze spectral variability related to Galactic absorption.

Contribution

It provides a detailed 3D mapping of the ISM around GRB 221009A using X-ray rings, improving upon optical/infrared dust maps and constraining host galaxy absorption.

Findings

Revised GRB soft X-ray fluence is ~35% lower than previous estimates.

Detected spectral variability due to different Galactic absorption in ring sectors.

Constrained host galaxy hydrogen column density to (3.7±0.3)×10^{21} cm^{-2}.

Abstract

The observation of 21 X-ray dust-scattering rings around the extraordinarily bright gamma-ray burst (GRB) 221009A provides a unique opportunity to study the interstellar medium (ISM) through which the X-ray radiation traveled in our Galaxy and, by difference, in the host galaxy as well. In particular, since the ring intensity and radius at a given time depend on the amount of dust and on its distance, respectively XMM-Newton and Swift images allowed us to map the ISM around the direction of the GRB with better resolution than in the existing optical and infrared-based 3D dust maps, both in the plane of the sky (few arcminutes) and along the line of sight (from $\simeq 1$ pc for dust clouds within 1 kpc to $\simeq 100$ pc for structures at distances larger than 10 kpc). As a consequence, we can revise prior estimates of the GRB soft X-ray fluence, obtaining a $\sim$35\% lower value, which, however, still indicates a substantial excess with respect to the extrapolation of the spectral models constrained by hard X-ray observations. Additionally, we detect significant spectral variability in two azimuthal sectors of the X-ray rings, which can be fully attributed to different Galactic absorption in these two directions. The comparison of the total hydrogen column density inferred from spectral fitting, with the Galactic contribution derived from the intensity of the X-ray rings, in the same sectors, allowed us to more robustly constrain the absorption in the host galaxy to $N_{\rm{H,z=0.151}}= (3.7\pm0.3)\,\times\,10^{21}\,\rm{cm^{-2}}$. This result is relevant not only to characterize the ISM of the host galaxy and to understand how the GRB radiation might have affected it, but also to model the broad-band spectrum of the GRB afterglow and to constrain the properties of a possible underlying supernova.