On Spectral Peak Energy of Swift Gamma-Ray Bursts

Abstract

Owing to narrow energy band of Swift/BAT, several urgent issues are required to pay more attentions but unsolved so far. We systematically study the properties of a refined sample of 283 Swift/BAT gamma-ray bursts with well-measured spectral peak energy (E p) at a high confidence level larger than 3σ. It is interestingly found that duration (T90) distribution of Swift bursts still exhibits an evident bimodality with a more reliable boundary of T901.06 s instead of 2 s for previously contaminated samples including bursts without well-peaked spectra, which is very close to 1.27 s and 0.8 s suggested by some authors for Fermi/GBM and Swift/BAT catalogs, respectively. The Swift/BAT short and long bursts have comparable mean E p values of 87+112-49 and 85+101-46 keV in each, similar to what found for both types of BATSE bursts, which manifests the traditional short-hard/long-soft scheme may not be tenable for the certain energy window of a detector. In statistics, we also investigate the consistency of distinct methods for the E p estimates and find that Bayesian approach and BAND function can always give consistent evaluations. In contrast, the frequently-used cut-off power-law model matches two other methods for lower E p and will overestimate the E p more than 70\% as E p>100 keV. Peak energies of X-ray flashes, X-ray rich bursts and classical gamma-ray bursts could have an evolutionary consequence from thermal-dominated to non-thermal-dominated radiation mechanisms. Finally, we find that the E p and the observed fluence (Sγ) in the observer frame are correlated as Ep [Sγ/(10-5 erg\ cm-2)]0.28× 117.5+44.7-32.4 keV proposed to be an useful indicator of GRB peak energies.