A numerical jet model for the prompt emission of gamma-ray bursts
Abstract
Gamma-ray bursts (GRBs) are known to be highly collimated events, and are mostly detectable when they are seen on-axis or very nearly on-axis. However, GRBs can be seen from off-axis angles, and the recent detection of a short GRB associated to a gravitational wave event has conclusively shown such a scenario. The observer viewing angle plays an important role in the observable spectral shape and the energetic of such events. We present a numerical model which is based on the single-pulse approximation with emission from a top-hat jet and has been developed to investigate the effects of the observer viewing angle. We assume a conical jet parametrized by a radius R jet, half-opening angle θ jet, a comoving-frame emissivity law and an observer viewing angle θ obs, and then study the effects for the conditions θ obs < θ jet and θ obs >θ jet. We present results considering a smoothly broken power-law emissivity law in jet comoving frame, albeit the model implementation easily allows to consider other emissivity laws. We find that the relation E i p E iso0.5 (Amati relation) is naturally obtained from pure relativistic kinematic when 10 and θ obs < θ jet; on the contrary, when θ obs > θ jet it results E i p E iso0.25. Using data from literature for a class of well-know sub-energetic GRBs, we show that their position in the E i p-E iso plane is consistent with event observed off-axis. The presented model is developed as a module to be integrated in spectral fitting software package XSPEC and can be used by the scientific community.
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