A Reverse Shock in GRB 160509A
Abstract
We present the second multi-frequency radio detection of a reverse shock in a -ray burst. By combining our extensive radio observations of the Fermi-LAT GRB 160509A at up to days after the burst with Swift X-ray observations and ground-based optical and near-infrared data, we show that the afterglow emission comprises distinct reverse shock and forward shock contributions: the reverse shock emission dominates in the radio band at days, while the forward shock emission dominates in the X-ray, optical, and near-infrared bands. Through multi-wavelength modeling, we determine a circumburst density of cm, supporting our previous suggestion that a low-density circumburst environment is conducive to the production of long-lasting reverse shock radiation in the radio band. We infer the presence of a large excess X-ray absorption column, cm, and a high rest-frame optical extinction, mag. We identify a jet break in the X-ray light curve at d, and thus derive a jet opening angle of deg, yielding a beaming-corrected kinetic energy and radiated -ray energy of erg and erg (-keV, rest frame), respectively. Consistency arguments connecting the forward and reverse shocks suggest a deceleration time of s, a Lorentz factor of , and a reverse shock to forward shock fractional magnetic energy density ratio of .
Cite
@article{arxiv.1606.08873,
title = {A Reverse Shock in GRB 160509A},
author = {Tanmoy Laskar and Kate D. Alexander and Edo Berger and Wen-fai Fong and Raffaella Margutti and Isaac Shivvers and Peter K. G. Williams and Drejc Kopac and Shiho Kobayashi and Carole Mundell and Andreja Gomboc and WeiKang Zheng and Karl M. Menten and Melissa L. Graham and Alexei V. Filippenko},
journal= {arXiv preprint arXiv:1606.08873},
year = {2016}
}
Comments
8 pages, 2 tables, 4 figures. Submitted to ApJ