Revisiting the Spectral-Energy Correlations of GRBs with Fermi Data I: Model-wise Properties
Abstract
Gamma-ray bursts (GRBs) exhibit a diversity of spectra. Several spectral models (e.g., Band, cutoff power-law, and blackbody) and their hybrid versions (e.g., Band+blackbody) have been widely used to fit the observed GRB spectra. Here, we attempt to collect all the bursts detected by Fermi-GBM with known redshifts from July 2008 to May 2022, motivated to (i) provide a parameter catalog independent from the official Fermi/GBM team and (ii) achieve a ``clean" model-based GRB spectral-energy correlation analysis. A nearly complete GRB sample was created, containing 153 such bursts (136 long gamma-ray bursts and 17 short gamma-ray bursts). Using the sample and by performing detailed spectral analysis and model comparisons, we investigate two GRB spectral-energy correlations: the cosmological rest-frame peak energy (E p,z) of the F prompt emission spectrum correlated with (i) the isotropic-bolometric-equivalent emission energy Eγ, iso (the Amati relation), and (ii) the isotropic-bolometric-equivalent peak luminosity L p, iso (the Yonetoku relation). From a linear regression analysis, a tight correlation between E p,z and Eγ, iso (and Lγ, iso) is found for both the Band-like and CPL-like bursts. More interestingly, the CPL-like bursts do not fall on the Band-like burst Amati and Yonetoku correlations, suggesting distinct radiation processes, and pointing towards the fact that these spectral-energy correlations are tightly reliant on the model-wise properties.
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