Detection of Low-energy Breaks in Gamma-Ray Burst Prompt Emission Spectra

TL;DR

This study analyzes low-energy spectral breaks in GRB prompt emission, revealing a common spectral break around a few keV and spectral slopes consistent with synchrotron radiation, challenging previous single power-law models.

Contribution

It introduces an empirical model capturing low-energy spectral breaks in GRBs, aligning observed slopes with synchrotron radiation predictions and providing new insights into prompt emission spectra.

Findings

Spectral breaks around a few keV are common in GRB prompt spectra.

Observed spectral slopes are consistent with synchrotron radiation expectations.

Traditional models often fail to fit the full 0.5-1000 keV spectra.

Abstract

The radiative process responsible for gamma-Ray Burst (GRB) prompt emission has not been identified yet. If dominated by fast-cooling synchrotron radiation, the part of the spectrum immediately below the $\nu F_\nu$ peak energy should display a power-law behavior with slope $\alpha_2=-3/2$, which breaks to a higher value $\alpha_1=-2/3$ (i.e. to a harder spectral shape) at lower energies. Prompt emission spectral data (usually available down to $\sim10-20\,$keV) are consistent with one single power-law behavior below the peak, with typical slope $\langle\alpha\rangle=-1$, higher than (and then inconsistent with) the expected value $\alpha_2=-3/2$. To better characterize the spectral shape at low energy, we analyzed 14 GRBs for which the Swift X-ray Telescope started observations during the prompt. When available, Fermi-GBM observations have been included in the analysis. For 67% of the spectra, models that usually give a satisfactory description of the prompt (e.g., the Band model) fail in reproducing the $0.5-1000\,$keV spectra: low-energy data outline the presence of a spectral break around a few keV.We then introduce an empirical fitting function that includes a low-energy power law $\alpha_1$, a break energy $E_{\rm break}$, a second power law $\alpha_2$, and a peak energy $E_{\rm peak}$. We find $\langle\alpha_1\rangle=-0.66$ ($ \rm \sigma=0.35$), $\langle \log (E_{\rm break}/\rm keV)\rangle=0.63$ ($ \rm \sigma=0.20$), $\langle\alpha_2\rangle=-1.46$ ($\rm \sigma=0.31$), and $\langle \log (E_{\rm peak}/\rm keV)\rangle=2.1$ ($ \rm \sigma=0.56$).The values $\langle\alpha_1\rangle$ and $\langle\alpha_2\rangle$ are very close to expectations from synchrotron radiation. In this context, $E_{\rm break}$ corresponds to the cooling break frequency.