On a GRB afterglow model consistent with hypernovae observations

Abstract

We describe the afterglows of the long gamma-ray-burst (GRB) 130427A within the context of a binary-driven hypernova (BdHN). The afterglows originate from the interaction between a newly born neutron star (), created by an Ic supernova (SN), and a mildly relativistic ejecta of a hypernova (HN). Such a HN in turn results from the impact of the GRB on the original SN Ic. The mildly relativistic expansion velocity of the afterglow ( 3) is determined, using our model independent approach, from the thermal emission between 196~s and 461~s. The power-law in the optical and X-ray bands of the afterglow is shown to arise from the synchrotron emission of relativistic electrons in the expanding magnetized HN ejecta. Two components contribute to the injected energy: the kinetic energy of the mildly relativistic expanding HN and the rotational energy of the fast rotating highly magnetized . We reproduce the afterglow in all wavelengths from the optical (1014~Hz) to the X-ray band (1019~Hz) over times from 604~s to 5.18× 106~s relative to the Fermi-GBM trigger. Initially, the emission is dominated by the loss of kinetic energy of the HN component. After 105~s the emission is dominated by the loss of rotational energy of the , for which we adopt an initial rotation period of 2~ms and a dipole plus quadrupole magnetic field of \! 7× 1012~G or \! 1014~G. This scenario with a progenitor composed of a CO core and a NS companion differs from the traditional ultra-relativistic-jetted treatments of the afterglows originating from a single black hole.