High energy emission of GRB 130427A: evidence for inverse Compton radiation

Abstract

A nearby super-luminous burst GRB 130427A was simultaneously detected by six γ-ray space telescopes ( Swift, Fermi-GBM/LAT, Konus-Wind, SPI-ACS/INTEGRAL, AGILE and RHESSI) and by three RAPTOR full-sky persistent monitors. The isotropic γ-ray energy release is of 1054 erg, rendering it the most powerful explosion among the GRBs with a redshift z≤ 0.5. The emission above 100 MeV lasted about one day and four photons are at energies greater than 40 GeV. We show that the count rate of 100 MeV-100 GeV emission may be mainly accounted for by the forward shock synchrotron radiation and the inverse Compton radiation likely dominates at GeV-TeV energies. In particular, an inverse Compton radiation origin is established for the (95.3,~47.3,~41.4,~38.5,~32) GeV photons arriving at t (243,~256.3,~610.6,~3409.8,~34366.2) s after the trigger of Fermi-GBM. Interestingly, the external-inverse-Compton-scattering of the prompt emission (the second episode, i.e., t 120-260 s) by the forward-shock-accelerated electrons is expected to produce a few γ-rays at energies above 10 GeV, while five were detected in the same time interval. A possible unified model for the prompt soft γ-ray, optical and GeV emission of GRB 130427A, GRB 080319B and GRB 090902B is outlined. Implication of the null detection of >1 TeV neutrinos from GRB 130427A by IceCube is discussed.