Empirical Constraints on Cosmological Gamma-Ray Bursts
arXiv:astro-ph/9401019 · doi:10.1086/187311
Abstract
We place empirical constraints on the physical properties of $γ-$ray burst events at cosmological distances. In particular we derive probability distributions for the radiation energy $E_γ$, the minimum Lorentz factor $γ_{\rm min}$, the maximum baryonic mass $M_{\rm max}$ and the upper bound on the surrounding gas density $n_{\rm max}$ in the events, based on 169 bursts from the first BATSE catalog. Using peak flux as a distance indicator we probe bursts where the constraints are stronger than average. The resulting variance and skewness of the cosmological probability distributions are calculated in addition to their mean values: $\langle E_γ\rangle=4\times 10^{51} h^{-2} {\rm erg}$, $\langle γ_{\rm min}\rangle= 5\times 10^2$, $\langle M_{\rm max}\rangle=10^{-5}ξ^{-1} M_\odot$, and $\langle (γ/γ_{\rm min})^{-5} n_{\rm max}\rangle\lsim 10^{2} ξ^{-1}{\rm cm^{-3}}$, where $ξ$ is the fraction of the total energy which is converted to $γ-$rays. The distribution of burst energies ends at about $10^{53} {\rm erg}$, close to the binding energy of a neutron star.
13 pages, TEX, 2 figures can be obtained from woods@cfata3.harvard.edu