Abstract

We consider a sample of 10 gamma-ray bursts with long-lasting ( ≳ 102 s) emission detected by <it>Fermi</it>/Large Area Telescope and for which X-ray data around 1 d are also available. We assume that both the X-rays and the GeV emission are produced by electrons accelerated at the external forward shock, and show that the X-ray and the GeV fluxes lead to very different estimates of the initial kinetic energy of the blast wave. The energy estimated from GeV is on average ∼50 times larger than the one estimated from X-rays. We model the data (accounting also for optical detections around 1 d, if available) to unveil the reason for this discrepancy and find that good modelling within the forward shock model is always possible and leads to two possibilities: (i) either the X-ray emitting electrons (unlike the GeV emitting electrons) are in the slow-cooling regime or (ii) the X-ray synchrotron flux is strongly suppressed by Compton cooling, whereas, due to the Klein–Nishina suppression, this effect is much smaller at GeV energies. In both cases the X-ray flux is no longer a robust proxy for the blast wave kinetic energy. On average, both cases require weak magnetic fields (10−6 ≲ ε<inf><it>B</it></inf> ≲ 10−3) and relatively large isotropic kinetic blast wave energies <f>$10^{53}\\rm \\,erg < {\\it E}_{0,kin} < 10^{55}\\rm \\,erg$</f> corresponding to large lower limits on the collimated energies, in the range <f>$10^{52}\\rm \\,erg < {\\it E}_{\\theta ,kin} < 5\\times 10^{52}\\rm \\,erg$</f> for an ISM (interstellar medium) environment with <it>n</it> ∼ 1 cm−3 and <f>$10^{52}\\rm \\,erg < {\\it E}_{\\theta ,kin} < 10^{53}\\rm \\,erg$</f> for a wind environment with <it>A</it><inf>*</inf> ∼ 1. These energies are larger than those estimated from the X-ray flux alone, and imply smaller inferred values of the prompt efficiency mechanism, reducing the efficiency requirements on the still uncertain mechanism responsible for prompt emission.