Relation between the intrinsic and observed central engine activity time: implications for ultra-long GRBs

Abstract

The GRB central engine intrinsic activity time T ce is usually described through either the γ-ray duration T90 or through a generalized burst duration t burst which includes both the γ-ray emission and (when present) an extended flaring X-ray plateau. Here, we define a more specific operational description of T ce, and within the framework of the internal-external shock model, we develop a numerical code to study the relationship between T90 and T ce, as well as between t burst and T ce, for different initial conditions. We find that when T ce 104 s, late internal collisions or refreshed external collisions result in values of T 90 and t burst larger than T ce, usually by factors of 2-3. For T ce 104 s, the t burst is always a good estimator for T ce, while T90 can underpredict T ce when the late central engine activity is moderate. We find a clear bimodal distribution for T ce, based on our simulations as well as on the observational data for T90 and t burst. We suggest that t burst is a reliable measure for defining "ultra-long" GRBs. Bursts with T90 of order 103 s need not belong to a special population, while bursts with t burst > 104 s, where the late central engine activity is more moderate and shows up in X-rays, may represent a new population. These conclusions are insensitive to the initial conditions assumed in the models.