Comprehensive Statistical Analysis of Initial Lorentz Factor and Jet Opening Angle of Gamma-Ray Bursts

Abstract

The initial Lorentz factor (0) and jet half-opening angle (θ jet) of gamma-ray bursts (GRBs) are critical physical parameters for understanding the dynamical evolution of relativistic jets and the true energy release of GRBs. We compile a sample of 89 GRBs that exhibit an onset bump feature in their early optical or GeV light curves, 42 of which also display a jet break feature, and derive their 0 and θ jet values. Using this sample, we re-eaxmine the correlations between 0 and the prompt emission parameters (isotropic energy E iso, peak luminosity L iso, and peak energy E p). Our results confirm the previously reported 0-E iso (L iso), 0-E p,z, and E iso (L iso)-E p-0 relations for both homogeneous interstellar medium (ISM) and wind density profiles (Wind). Notably, we find that the short GRB 090510 complies with the 0-E iso relation, but significantly deviates from the 0-L iso and 0-E p,z relations. We systematically investigate the influence of θ jet on 0 and find a weak dependence. Additionally, we report, for the first time, three new three-parameter correlations, i.e., E iso (or L iso, E p,z)-0-θ jet correlations. In addition, we further explore the relations between the initial Lorentz factor and the jet-corrected energy. We also find that the jet-corrected correlations remain significant, suggesting that these relations are intrinsic to the physical nature of GRBs. However, the increased dispersion after correction implies that underlying differences persist among individual GRBs.