Multiple Components in the Broadband $\gamma$-ray Emission of the Short GRB 160709A

TL;DR

This paper analyzes the complex gamma-ray emission components of short GRB 160709A, revealing thermal and nonthermal contributions, their physical parameters, and implications for jet-environment interactions.

Contribution

It identifies and characterizes multiple emission components in GRB 160709A, including a thermal photospheric component and additional nonthermal components, with detailed physical parameter estimation.

Findings

Thermal component dominates during 0.12 s with high temperature (~340 keV).

Nonthermal components are dominant in early and late phases.

Closure relation analysis suggests jet interacts with interstellar medium.

Abstract

GRB 160709A is one of the few bright short gamma-ray bursts detected by both the Gamma-ray Burst Monitor and the Large Area Telescope on board the $Fermi$ $Gamma$-$ray$ $Space$ $Telescope$. The $\gamma$-ray prompt emission of GRB 160709A is adequately fitted by combinations of three distinct components: (i) a nonthermal component described by a power law (PL) with a high-energy exponential cutoff, (ii) a thermal component modeled with a Planck function, and (iii) a second nonthermal component shaped by an additional PL crossing the whole $\gamma$-ray spectrum. While the thermal component dominates during $\sim$ 0.12 s of the main emission episode of GRB 160709A with an unusually high temperature of $\sim$ 340 keV, the nonthermal components dominate in the early and late time. The thermal component is consistent with the photospheric emission resulting in the following parameters: the size of the central engine, $R_{0}$ = $3.8 \substack{+5.9 \\ -1.8}$ $\times 10^{8}$ cm, the size of the photosphere, R$_{ph}$ = $7.4 \substack{+0.8 \\ -1.2}$ $\times 10^{10}$ cm, and a bulk Lorentz factor, $\Gamma$ = $728 \substack{+75 \\ -93}$ assuming a redshift of 1. The slope of the additional PL spectrum stays unchanged throughout the burst duration; however, its flux decreases continuously as a function of time. A standard external shock model has been tested for the additional PL component using the relation between the temporal and spectral indices (the closure relation). Each set of spectral and temporal indices from two energy bands (200 keV--40 MeV and 100 MeV--10 GeV) satisfies a distinct closure relation. From the closure relation test we derived the index for the electron spectral distribution, $p$ = 2.5 $\pm$ 0.1. The interaction of the jet with the interstellar environment is preferred over the interaction with the wind medium.