Spectral properties of long and short Gamma-Ray Bursts: comparison between BATSE and Fermi bursts

Abstract

We compare the spectral properties of 227 Gamma Ray Bursts (GRBs) detected by the Fermi Gamma Ray Burst Monitor (GBM) up to February 2010 with those of bursts detected by the CGRO/BATSE instrument. Out of 227 Fermi GRBs, 166 have a measured peak energy Epeakobs of their () spectrum: of these 146 and 20 belong the long and short class, respectively. Fermi long bursts follow the correlations defined by BATSE bursts between their Epeakobs vs fluence and peak flux: as already shown for the latter ones, these correlations and their slopes do not originate from instrumental selection effects. Fermi/GBM bursts extend such correlations toward lower fluence/peak energy values with respect to BATSE ones whereas no GBM long burst with Epeakobs exceeding a few MeV is found, despite the possibility of detecting them. Again as for BATSE, 5% of long and almost all short GRBs detected by Fermi/GBM are outliers of the Epeak-isotropic equivalent energy ("Amati") correlation while no outlier (neither long nor short) of the Epeak-isotropic equivalent luminosity ("Yonetoku") correlation is found. Fermi long bursts have similar typical values of Epeakobs but a harder low energy spectral index with respect to all BATSE events, exacerbating the inconsistency with the limiting slopes of the simplest synchrotron emission models. Although the short GRBs detected by Fermi are still only a few, we confirm that their Epeakobs is greater and the low energy spectrum is harder than those of long ones. We discuss the robustness of these results with respect to observational biases induced by the differences between the GBM and BATSE instruments.