Luminosity--time and luminosity--luminosity correlations for GRB prompt and afterglow plateau emissions

Abstract

We present an analysis of 123 Gamma-ray bursts (GRBs) with known redshifts possessing an afterglow plateau phase. We reveal that La-T*a correlation between the X-ray luminosity La at the end of the plateau phase and the plateau duration, T*a, in the GRB rest frame has a power law slope different, within more than 2 σ, from the slope of the prompt Lf-T*f correlation between the isotropic pulse peak luminosity, Lf, and the pulse duration, T*f, from the time since the GRB ejection. Analogously, we show differences between the prompt and plateau phases in the energy-duration distributions with the afterglow emitted energy being on average 10\% of the prompt emission. Moreover, the distribution of prompt pulse versus afterglow spectral indexes do not show any correlation. In the further analysis we demonstrate that the Lpeak-La distribution, where Lpeak is the peak luminosity from the start of the burst, is characterized with a considerably higher Spearman correlation coefficient, =0.79, than the one involving the averaged prompt luminosity, Lprompt-La, for the same GRB sample, yielding =0.60. Since some of this correlation could result from the redshift dependences of the luminosities, namely from their cosmological evolution we use the Efron-Petrosian method to reveal the intrinsic nature of this correlation. We find that a substantial part of the correlation is intrinsic. We apply a partial correlation coefficient to the new de-evolved luminosities showing that the intrinsic correlation exists.