GRB 080928 afterglow imaging and spectro-polarimetry

TL;DR

This study presents optical polarimetric observations of GRB 080928's afterglow, revealing evolving polarization levels and insights into jet structure and magnetic fields, highlighting the importance of spectro-polarimetry in understanding gamma-ray bursts.

Contribution

First spectro-polarimetric analysis of GRB 080928's afterglow, demonstrating polarization evolution and implications for jet geometry and magnetic field configuration.

Findings

Polarization grew to ~4.5% on the second night.

Afterglow light curve deviates from standard models.

Evidence suggests a homogeneous jet observed at an intermediate angle.

Abstract

Among the large variety of astrophysical sources that we can observe, gamma-ray bursts (GRBs) are the most energetic of the whole Universe. The definition of a general picture describing the physics behind GRBs has always been a compelling task, but the results obtained so far from observations have revealed a puzzling landscape. The lack of a clear, unique paradigm calls for further observations and additional, independent techniques for this purpose. Polarimetry constitutes a very useful example as it allows us to investigate some features of the source such as the geometry of the emitting region and the magnetic field configuration. To date, only a handful of bursts detected by space telescopes have been accompanied by ground-based spectro-polarimetric follow-up, and therefore such an analysis of more GRBs is of crucial importance in order to increase the sample of bursts with multi-epoch polarisation analysis. In this work, we present the analysis of the GRB 080928 optical afterglow, with observations performed with the ESO-VLT FORS1 instrument. We find that the GRB optical afterglow was not significantly polarised on the first observing night. The polarisation degree ($P$) grew on the following night to a level of $P \sim$ 4.5%, giving evidence of polarised radiation at a 4 $\sigma$ confidence level. The GRB 080928 light curve is not fully consistent with standard afterglow models, making any comparison with polarimetric models partly inconclusive. The most conservative interpretation is that the GRB emission was characterised by a homogeneous jet and was observed at an angle of 0.6 $< \theta_{obs}/\theta_{jet} <$ 0.8. Moreover, the non-zero polarisation degree on the second night suggests the presence of a dominant locally ordered magnetic field in the emitting region.