The radio flare and multi-wavelength afterglow of the short GRB 231117A: energy injection from a violent shell collision

Abstract

We present the early radio detection and multi-wavelength modeling of the short gamma-ray burst (GRB) 231117A at redshift z=0.257. The Australia Telescope Compact Array automatically triggered a 9-hour observation of GRB 231117A at 5.5 and 9 GHz following its detection by the Neil Gehrels Swift Observatory just 1.3 hours post-burst. Splitting this observation into 1-hour time bins, the early radio afterglow exhibited flaring, scintillating and plateau phases. The scintillation allowed us to place the earliest upper limit (<10 hours) on the size of a GRB blast wave to date, constraining it to <1×1016 cm. Multi-wavelength modeling of the full afterglow required a period of significant energy injection between 0.02 and 1 day. The energy injection was modeled as a violent collision of two shells: a reverse shock passing through the injection shell explains the early radio plateau, while an X-ray flare is consistent with a shock passing through the leading impulsive shell. Beyond 1 day, the blast wave evolves as a classic decelerating forward shock with an electron distribution index of p=1.660.01. Our model also indicates a jet-break at 2 days, and a half-opening angle of θj=16.6 1.1. Following the period of injection, the total energy is ζ18 times the initial impulsive energy, with a final collimation-corrected energy of EKf5.7×1049 erg. The minimum Lorentz factors this model requires are consistent with constraints from the early radio measurements of >35 to >5 between 0.1 and 1 day. These results demonstrate the importance of rapid and sensitive radio follow-up of GRBs for exploring their central engines and outflow behaviour.