The Galactic dust-to-metals ratio and metallicity using gamma-ray bursts

TL;DR

This study uses gamma-ray burst afterglows to measure the Galactic dust-to-metals ratio and metallicity, providing new constraints and insights into the ISM composition and its variation across the Galaxy.

Contribution

It introduces a novel method combining X-ray absorption and dust maps to determine the Galactic dust-to-metals ratio and metallicity, refining previous estimates.

Findings

The Galactic dust-to-metals ratio is consistent with previous measurements.

The metallicity in the Galaxy is approximately 0.25 dex higher than the solar value.

The dust-to-gas ratio correlates with total gas column density, influenced by metallicity gradients.

Abstract

The metallicity and dust-to-metals ratio of the Galaxy are fundamental parameters in understanding the ISM, but there is still uncertainty surrounding these parameters. In this paper, the dust-to-metals ratio in the Galaxy is determined using the photoelectric absorption of the X-ray afterglows of a sample of several hundred gamma-ray bursts (GRBs) to determine the metal column density in combination with Galactic dust maps to determine the line-of-sight dust extinction through the Galaxy in the direction of the GRB. GRB afterglows often have large extragalactic soft X-ray absorptions and therefore the GRB sample's upper-bound will define the Galactic dust-to-metals relation. Using a two-dimensional two-sample KS test, we determine this upper-bound and so derive the dust-to-metals ratio of the Galaxy. We find N_H = 2.2^{+0.3}_{-0.4}e21 cm^-2 A_V assuming solar, Anders & Grevesse (1989), metallicity. This result is consistent with previous findings using bright X-ray sources in the Galaxy. Using the same technique but substituting the HI maps from the Leiden-Argentine-Bonn survey for the dust maps, allows us to place a limit on the metallicity in the Galaxy. We find a metallicity consistent with the Anders & Grevesse (1989) solar values often used in X-ray fitting. Based on this and previous studies, we suggest that the metallicity of a typical ISM sightline through the Galaxy is ~0.25 dex higher than the current best estimate of the solar metallicity. We further show that the dust-to-gas ratio seems to be correlated with the total gas column density, and that this may be due to the metallicity gradient observed toward the Galactic centre. Based on the non-constant nature of the dust-to-gas ratio, we propose that the dust column density, at N_H = 2.2e21 cm^-2 A_V, represents a better proxy for the soft X-ray absorption column density than HI maps.