Abstract

Context. The gamma-ray bursts hosts (GRBHs) are excellent targets to study the extinction properties of dust and its effects on the global emission of distant galaxies. The dust extinction curve is measured along the GRB afterglow line of sight and the analysis of the spectral energy distribution (SED) of the host galaxy gives access to the global dust attenuation of the stellar light. Aims. In this pilot study we gather information on dust extinction in GRBHs to compare the properties of the extinction curve to those of the dust obscuration affecting the total stellar light of the host galaxy. Assuming the extinction curve to be representative of the dust properties, we aim to investigate which dust-stars geometries and local dust distribution in the inter stellar medium (ISM) can reproduce the observed attenuation curve. Methods. We selected a sample of 30 GRBs for which the extinction curve along the GRB afterglow line-of-sight (l.o.s.) is measured in the rest-frame ultraviolet (UV) up to optical and we analysed the properties of the extinction curve as a function of the host galaxy properties. From these 30 GRBs, we selected seven GRBHs with a good rest-frame UV to near-infrared (NIR) spectral coverage for the host. The attenuation curve was derived by fitting the SEDs of the GRBH sample with the CIGALE SED fitting code. Different star formation histories (SFH) were studied to recover the star formation rates (SFR) derived using Hα luminosities. Implications for the dust-stars geometries in the ISM are inferred by a comparison with radiative transfer simulations. Results. The most extinguished GRBs are preferentially found in the more massive hosts and the UV bump is preferentially found in the most extinguished GRB l.o.s. Five out of seven hosts are best fitted with a recent burst of star formation, leading to lower stellar mass estimates than previously found. The average attenuation in the host galaxies is about 70% of the amount of extinction along the GRB l.o.s. We find a great variety in the derived attenuation curves of GRBHs, the UV slope can be similar, flatter or even steeper than the extinction curve slope. Half of the attenuation curves are consistent with the Calzetti attenuation law and there is evidence of a UV bump in only one GRBH. We find that the flatter (steeper) attenuation curves are found in galaxies with the highest (lowest) SFR and stellar masses. The comparison of our results with radiative transfer simulations leads to a uniform distribution of dust and stars in a very clumpy ISM for half the GRBHs and various dust-stars geometries for the second half of the sample.

Highlights

  • Stellar light in galaxies is absorbed and scattered in the interstellar medium by dust grains

  • Assuming the extinction curve to be representative of the dust properties, we aim to investigate which dust-stars geometries and local dust distribution in the inter stellar medium (ISM) can reproduce the observed attenuation curve

  • We selected a sample of 30 Gamma-ray bursts (GRBs) for which the extinction curve along the GRB afterglow line-of-sight (l.o.s.) is measured in the rest-frame ultraviolet (UV) up to optical and we analysed the properties of the extinction curve as a function of the host galaxy properties

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Summary

Introduction

Stellar light in galaxies is absorbed and scattered in the interstellar medium by dust grains. Most of the numerical simulations using radiative transfer models use the extinction law of local galaxies to characterise the dust properties and compute the attenuation curve one would observe for a given dust-stars geometry Gamma-ray bursts (GRBs) with their featureless power-law like spectrum shape of their afterglows are excellent probes of dust extinction in their host galaxies (Zafar et al 2011, 2018; Schady et al 2012; Covino et al 2013; Japelj et al 2015) Thanks to their extremely high luminosity (up to ∼1053 erg s−1) such studies can be extended to very high redshift.

Selection of the targets
SED of GRB afterglows
Modelling extinction processes
Selection criteria for GRB extinction curves
GRB host galaxies selection
GRB host galaxy properties
Golden sample for deriving GRBH attenuation curves
GRB and host properties
Importance of a rapid follow-up
Fitting the SED of the hosts
SED fitting method
GRBH 061121
GRBH 070802
GRBH 080605
GRBH 080607
GRBH 080805
GRBH 100814A
GRBH 120119A
Star formation activity and SFR-M comparison
Dust attenuation in GRBHs
Measure of the attenuation curve slopes
Variation of the slope with GRB host properties
General shape
Comparison of extinction and attenuation curves
Presence of the UV bump in the attenuation curves
Comparison with radiative transfer simulations
Conclusion
Findings

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