A morphological analysis of gamma-ray burst early optical afterglows

Abstract

Within the framework of the external shock model of gamma-ray bursts (GRBs) afterglows, we perform a morphological analysis of the early optical lightcurves to directly constrain model parameters. We define four morphological types, i.e. the reverse shock dominated cases with/without the emergence of the forward shock peak (Type I/ Type II), and the forward shock dominated cases without/with m crossing the band (Type III/IV). We systematically investigate all the Swift GRBs that have optical detection earlier than 500 s and find 3/63 Type I bursts (4.8%), 12/63 Type II bursts (19.0%), 30/63 Type III bursts (47.6%), 8/63 Type IV bursts (12.7%) and 10/63 Type III/IV bursts (15.9%). We perform Monte Carlo simulations to constrain model parameters in order to reproduce the observations. We find that the favored value of the magnetic equipartition parameter in the forward shock (εBf) ranges from 10-6 to 10-2, and the reverse-to-forward ratio of εB (RB) is about 100. The preferred electron equipartition parameter εer,f value is 0.01, which is smaller than the commonly assumed value, e.g., 0.1. This could mitigate the so- called "efficiency problem" for the internal shock model, if εe during the prompt emission phase (in the internal shocks) is large (say, 0.1). The preferred RB value is in agreement with the results in previous works that indicates a moderately magnetized baryonic jet for GRBs.