The extinction properties of long GRB host galaxies from H and He I recombination lines

TL;DR

This paper presents a self-consistent method using hydrogen and helium recombination lines across optical and near-infrared spectra to better understand dust extinction in long GRB host galaxies, reducing systematic errors.

Contribution

It introduces a new approach that minimizes systematic errors in measuring dust properties of GRB hosts by combining wide wavelength coverage and suitable instrumentation.

Findings

Improved accuracy in determining dust extinction parameters.

Successful application to GRB 060218 host galaxy data.

Demonstrated enhancement over previous flux measurements.

Abstract

In this paper we show how a self-consistent treatment of hydrogen and helium emission line fluxes of the hosts of long gamma-ray bursts can result in improved understanding of the dust properties in these galaxies. In particular, we find that even with modest signal to noise spectroscopy we can differentiate different values for R_V, the ratio of total to selective extinction. The inclusion of Paschen and Brackett lines, even at low signal to noise, greatly increase the accuracy of the derived reddening. This method is often associated with strong systematic errors, caused by the need for multiple instruments to cover the wide wavelength range, the requirement to separate stellar hydrogen absorption from the nebular emission, and because of the dependancy of the predicted line fluxes on the electron temperature. We show how these three systematic errors can be negated, by using suitable instrumentation (in particular X-shooter on the Very Large Telescope) and wide wavelength coverage. We demonstrate this method using an extensive optical and near-infrared spectroscopic campaign of the host galaxy of gamma-ray burst 060218 (SN 2006aj), obtained with FORS1, UVES and ISAAC on the VLT, covering a broad wavelength range with both high and low spectral resolution. We contrast our findings of this source with X-shooter data of a star forming region in the host of GRB 100316D, and show the improvement over existing published fluxes of long GRB hosts.