A Novel Relationship Between Gamma Ray Burst Duration And Photospheric Radius

Abstract

Long Gamma Ray Bursts (lGRBs) are associated with jets in Type Ic broadline supernovae. The Collapsar model provides a theoretical framework for the jet formation from the core collapse of a massive star in such supernovae. The GRB can only be produced after a successful jet break out from the star. Under this formalism the GRB duration (t90) has been hypothesized to be the difference between the central engine activity duration (teng) and the jet breakout time (tbo), that is t90 = teng - tbo. This disallows t90 > teng and puts a lower bound on successful lGRB jet central engine duration (teng > tbo), various numerical simulations have shown otherwise. This study considers a photospheric GRB emission from a relativistic jet punching out of a Wolf-Rayet-like star. We use the bolometric lightcurve generated to calculate the lGRB duration (t90) for varying engine duration. We find for longer engine duration the lGRB lightcurve reflects the jet profile and t90 ≈ teng. While for shorter engine duration, the t90 has photospheric radius (Rph) dependence. This can be modeled by a relation, t90 = t90eng + 0.03(Rphc), where c is the speed of light, with a lower bound on t90 for a successful lGRB. This relation should be most relevant for possible low-luminous lGRBs originating from a collapsar with central engine duration comparable to the jet breakout time.

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