Softness Ratio of SWIFT Gamma-ray Bursts and Relevant Correlations

TL;DR

This study analyzes a large sample of Swift-detected gamma-ray bursts, revealing strong correlations among their energetic and spectral properties, and shows that X-ray flashes, X-ray rich bursts, and classical GRBs follow similar patterns, with implications for cosmology.

Contribution

It introduces new correlations involving softness ratio and spectral parameters, demonstrating their applicability across different GRB types and enhancing understanding of GRB properties.

Findings

Strong correlations among $E_{iso}$, $L_p$, and $T_{90,rest}$.

Two tight correlations involving softness ratio and peak energy.

XRFs, XRRs, and C-GRBs all follow these correlations.

Abstract

The properties of X-ray flashes (XRFs) and X-ray rich gamma-ray bursts (XRRs) as compared with classical gamma-ray bursts (C-GRBs) have been widely discussed during the \emph{Swift} era. It has been proposed that XRFs and XRRs are low-energy extensions of the GRB population so that they should follow similar correlations. To further examine this idea, we collect a sample of $303$ GRBs detected by \emph{Swift} over the past two decades, all of which have reliable redshifts and spectral parameters. The bursts are classified into XRFs, XRRs, and C-GRBs based on their softness ratio (SR), which is calculated by dividing the $25-50$ keV fluence with the $50-100$ keV fluence. A strong correlation is found among the isotropic energy $E_{\mathrm{iso}}$, peak luminosity $L_{\mathrm{p}}$, and rest frame burst duration $T_{90, \mathrm{rest}}$, i.e., $E_{\mathrm{iso}} \propto L_{\mathrm{p}}^{0.88\pm0.02} T_{90, \mathrm{rest}}^{0.58\pm0.02}$. Additionally, two tight three-parameter correlations involving SR and the rest-frame peak energy $E_{\mathrm{p}}$ are also derived, i.e. $E_{\mathrm{p}} \propto E_{\mathrm{iso}}^{0.20\pm0.02} \mathrm{SR}^{-2.27\pm0.15}$ and $E_{\mathrm{p}} \propto L_{\mathrm{p}}^{0.17\pm0.02} \mathrm{SR}^{-2.33\pm0.14}$. It is interesting to note that XRFs, XRRs, and C-GRBs all follow the above correlations. The implications of these correlations and their potential application in cosmology are discussed.