Illuminating the Darkest Gamma-Ray Bursts with Radio Observations

TL;DR

This paper combines multi-wavelength observations to analyze dark gamma-ray bursts, revealing high extinction, dense environments, and typical energy outputs, emphasizing the importance of radio data in understanding these obscured cosmic events.

Contribution

It demonstrates how radio observations can precisely locate dark GRBs and determine their properties, highlighting the role of high extinction and dense environments in their nature.

Findings

Dark GRBs exhibit high optical extinction (A_V > 5.3 and 8.5 mag).

Both bursts show large neutral hydrogen column densities (N_H > 10^22/cm^2).

The afterglows are consistent with collimated outflows in dense wind media.

Abstract

We present X-ray, optical, near-infrared, and radio observations of GRBs 110709B and 111215A, as well as optical and near-IR observations of their host galaxies. The combination of X-ray detections and deep optical/near-infrared limits establish both bursts as "dark". Sub-arcsecond positions enabled by radio detections lead to robust host galaxy associations, with optical detections that indicate z < 4 (110709B) and 1.8 < z < 2.7 (111215A). Using the radio and X-ray data for each burst we find that GRB 110709B requires A_V > 5.3 mag and GRB 111215A requires A_V > 8.5 mag (z=2), among the largest extinction values inferred for dark bursts to-date. The two bursts also exhibit large neutral hydrogen column densities (N_H > 10^22/cm^2; z=2) as inferred from their X-ray spectra, in agreement with the trend for dark GRBs. Finally, we find that for both bursts the afterglow emission is best explained by a collimated outflow with a total beaming-corrected energy of E_gamma+E_K ~ 7-9 x 10^51 erg (z=2) expanding into a wind medium with a high density (n~100-350 cm^-3 at 10^17 cm). While the energy release is typical of long GRBs, the inferred density may be indicative of larger mass loss rates for GRB progenitors in dusty (and hence metal rich) environments. This study establishes the critical role of radio observations in determining the origin and properties of dark GRBs. Observations with the JVLA and ALMA will provide a sample with sub-arcsecond positions and robust host associations that will help shed light on obscured star formation and the role of metallicity in GRB progenitors.