The faster the narrower: characteristic bulk velocities and jet opening angles of Gamma Ray Bursts

Abstract

The jet opening angle thetajet and the bulk Lorentz factor Gamma0 are crucial parameters for the computation of the energetics of Gamma Ray Bursts (GRBs). From the ~30 GRBs with measured thetajet or Gamma0 it is known that: (i) the real energetic Egamma, obtained by correcting the isotropic equivalent energy Eiso for the collimation factor ~thetajet2, is clustered around 1050-1051 erg and it is correlated with the peak energy Ep of the prompt emission and (ii) the comoving frame E'p and E'gamma are clustered around typical values. Current estimates of Gamma0 and thetajet are based on incomplete data samples and their observed distributions could be subject to biases. Through a population synthesis code we investigate whether different assumed intrinsic distributions of Gamma0 and thetajet can reproduce a set of observational constraints. Assuming that all bursts have the same E'p and E'gamma in the comoving frame, we find that Gamma0 and thetajet cannot be distributed as single power-laws. The best agreement between our simulation and the available data is obtained assuming (a) log-normal distributions for thetajet and Gamma0 and (b) an intrinsic relation between the peak values of their distributions, i.e thetajet2.5*Gamma0=const. On average, larger values of Gamma0 (i.e. the "faster" bursts) correspond to smaller values of thetajet (i.e. the "narrower"). We predict that ~6% of the bursts that point to us should not show any jet break in their afterglow light curve since they have sin(thetajet)<1/Gamma0. Finally, we estimate that the local rate of GRBs is ~0.3% of all local SNIb/c and ~4.3% of local hypernovae, i.e. SNIb/c with broad-lines.