Off-Axis Emission of Short GRB Jets from Double Neutron Star Mergers and GRB 170817A

TL;DR

This paper develops a framework for off-axis gamma-ray burst jet afterglow emission, applying it to GRB 170817A, and finds the observed emission is consistent with a jet viewed at 16-26 degrees off-axis with specific energy and density parameters.

Contribution

It introduces a comprehensive model for off-axis GRB jet afterglows and applies it to interpret the multi-wavelength observations of GRB 170817A, linking gravitational wave and electromagnetic signals.

Findings

The observed afterglow is consistent with a viewing angle of 16-26 degrees.

The jet energy is estimated between 10^{48.5} and 10^{49.5} erg.

External density around the merger is constrained to 10^{-5} to 10^{-1} cm^{-3}.

Abstract

The short-duration ($\lesssim2\;$s) GRB 170817A in the nearby ($D=40\;$Mpc) elliptical galaxy NGC 4993 is the first electromagnetic counterpart of the first gravitational wave (GW) detection of a binary neutron-star (NS-NS) merger. It was followed by optical, IR, and UV emission from half a day up to weeks after the event, as well as late time X-ray and radio emission. The early UV, optical, and IR emission showed a quasi-thermal spectrum suggestive of radioactive-decay powered kilonova-like emission. Comparison to kilonova models favors the formation of a short-lived ($\sim1\;$s) hypermassive NS, which is also supported by the $\Delta t\approx1.74\;$s delay between the GW chirp signal and the prompt GRB onset. However, the late onset of the X-ray (8.9$\;$days) and radio (16.4$\;$days) emission, together with the low isotropic equivalent $\gamma$-ray energy output ($E_{\rm\gamma,iso}\approx5\times10^{46}\;$erg), strongly suggest emission from a narrow relativistic jet viewed off-axis. Here we set up a general framework for off-axis GRB jet afterglow emission, comparing analytic and numerical approaches, and showing their general predictions for short-hard GRBs that accompany binary NS mergers. The prompt GRB emission suggests a viewing angle well outside the jet's core, and we compare the afterglow lightcurves expected in such a case to the X-ray to radio emission from GRB 170817A. We fit an afterglow off-axis jet model to the X-ray and radio data and find that the observations are explained by a viewing angle $\theta_{\rm obs}\approx16^\circ-26^\circ$, GRB jet energy $E\sim10^{48.5}-10^{49.5}~{\rm erg}$, and external density $n\sim10^{-5}-10^{-1}~{\rm cm}^{-3}$ for a $\xi_e\sim 0.1$ non-thermal electron acceleration efficiency.