Constraining the Structure of GRB Jets Through the log(N)-log(S) Distribution
Abstract
A general formalism is developed for calculating the luminosity function and the expected number N of observed GRBs above a peak photon flux S for any GRB jet structure. This new formalism directly provides the true GRB rate without the need for a `correction factor'. We apply it to the uniform jet (UJ) and universal structured jet (USJ) models for the structure of GRB jets and perform fits to the observed log(N)-log(S) distribution from the GUSBAD catalog which contains 2204 BATSE bursts. A core angle θc and an outer edge at θmax are introduced for the structured jet, and a finite range of half-opening angles θmin≤θj≤θmax is assumed for the uniform jets. The efficiency εγ for producing gamma-rays, and the energy per solid angle ε in the jet are allowed to vary with θj (the viewing angle θobs) in the UJ (USJ) model, εγθ-b and εθ-a. We find that a single power-law luminosity function provides a good fit to the data. Such a luminosity function arises naturally in the USJ model, while in the UJ model it implies a power-law probability distribution for θj, P(θj)θj-q. The value of q cannot be directly determined from the fit to the observed log(N)-log(S) distribution, and an additional assumption on the value of a or b is required. Alternatively, an independent estimate of the true GRB rate would enable one to determine a, b and q. The implied values of θc (or θmin) and θmax are close to the current observational limits. The true GRB rate for the USJ model is found to be RGRB(z=0)=0.86+0.14-0.05 Gpc-3 yr-1.
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