The Origin of the Prompt Emission for Short GRB 170817A: Photosphere Emission or Synchrotron Emission?

The first gravitational-wave event from the merger of a binary neutron star system (GW170817) was detected recently. The associated short gamma-ray burst (GRB 170817A) has a low isotropic luminosity (\(\sim 10^{47}\) erg s\( ^{-1}\)) and a peak energy \(E_{p}\sim 145\) keV during the initial main em...

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Published inarXiv.org
Main Authors Yan-Zhi, Meng, Jin-Jun, Geng, Bin-Bin, Zhang, Jun-Jie, Wei, Xiao, Di, Liang-Duan, Liu, Gao, He, Xue-Feng, Wu, En-Wei, Liang, Yong-Feng, Huang, Zi-Gao, Dai, Zhang, Bing
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 17.06.2018
Subjects
Binary stars
Blackbody
Computer simulation
Delay
Emission
Gamma ray bursts
Gamma rays
Gravitational waves
Line of sight
Lorentz factor
Luminosity
Markov chains
Monte Carlo simulation
Neutron stars
Photosphere
Physics - High Energy Astrophysical Phenomena
Synchrotron radiation
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Summary:The first gravitational-wave event from the merger of a binary neutron star system (GW170817) was detected recently. The associated short gamma-ray burst (GRB 170817A) has a low isotropic luminosity (\(\sim 10^{47}\) erg s\( ^{-1}\)) and a peak energy \(E_{p}\sim 145\) keV during the initial main emission between -0.3 and 0.4 s. The origin of this short GRB is still under debate, but a plausible interpretation is that it is due to the off-axis emission from a structured jet. We consider two possibilities. First, since the best-fit spectral model for the main pulse of GRB 170817A is a cutoff power law with a hard low-energy photon index (\(\alpha =-0.62_{-0.54}^{+0.49} \)), we consider an off-axis photosphere model. We develop a theory of photosphere emission in a structured jet and find that such a model can reproduce a low-energy photon index that is softer than a blackbody through enhancing high-latitude emission. The model can naturally account for the observed spectrum. The best-fit Lorentz factor along the line of sight is \(\sim 20\), which demands that there is a significant delay between the merger and jet launching. Alternatively, we consider that the emission is produced via synchrotron radiation in an optically thin region in an expanding jet with decreasing magnetic fields. This model does not require a delay of jet launching but demands a larger bulk Lorentz factor along the line of sight. We perform Markov Chain Monte Carlo fitting to the data within the framework of both models and obtain good fitting results in both cases.
ISSN:2331-8422
DOI:10.48550/arxiv.1801.01410