Distributions of Gamma-Ray Bursts and Blazars in the L p-E p Plane and Possible Implications for their Radiation Physics

Abstract

We present a spectral analysis for a sample of redshift known GRBs observed with Fermi/GBM. Together with the results derived from our systematical spectral energy distribution modeling with the leptonic models for a Fermi/LAT blazar sample, we compare the distributions of the GRBs and the blazars by plotting the synchrotron peak luminosity (L s) and the corresponding peak photon energy E s of blazars in the L p-E p plane of GRBs, where L p and E p are the peak luminosity and peak photon energy of the GRB time-integrated f spectrum, respectively. The GRBs are in the high-L p, high-E p corner of the plane and a tight L p-E p relation is found, i.e., L p E p2.13+0.54-0.46. Both FSRQs and LBLs are clustered in the low-E p, low-L p corner. IBLs and HBLs have E s 2× 10-3 - 102 keV and L s 1044 - 1047 erg s-1, but no dependence of L s on E s is found. We show that the tight Lp-Ep relation of GRBs is potentially explained with the synchrotron radiation of fast-cooling electrons in a highly magnetized ejecta, and the weak anti-correlation of L s-E s for FSRQs and LBLs may be attributed to synchrotron radiation of slow-cooling electrons in a moderately magnetized ejecta. The distributions of IBLs and HBLs in the L p-E p plane may be interpreted with synchrotron radiation of fast-cooling electrons in a matter-dominated ejecta. These results may present a unified picture for the radiation physics of relativistic jets in GRBs and blazars within the framework of the leptonic synchrotron radiation models.