Possible Gamma-Ray Burst radio detections by the Square Kilometre Array. New perspectives

TL;DR

The paper evaluates the potential of the Square Kilometre Array to detect and study Gamma Ray Bursts in radio frequencies, emphasizing its ability to extend observations and improve understanding of GRB physics.

Contribution

It presents an estimation of GRB radio detection rates with SKA, based on a large catalog, and discusses the potential for multi-wavelength observations to constrain GRB models.

Findings

SKA could detect a significant number of GRBs in radio frequencies.

Estimated detection rates depend on GRB fluence and SKA sensitivity.

Results align with current observational capabilities.

Abstract

The next generation interferometric radio telescope, the Square Kilometre Array (SKA), which will be the most sensitive and largest radio telescope ever constructed, could greatly contribute to the detection, survey and characterization of Gamma Ray Bursts (GRBs). By the SKA, it will be possible to perform the follow up of GRBs even for several months. This approach would be extremely useful to extend the Spectrum Energetic Distribution (SED) from the gamma to the to radio band and would increase the number of radio detectable GRBs. In principle, the SKA could help to understand the physics of GRBs by setting constraints on theoretical models. This goal could be achieved by taking into account multiple observations at different wavelengths in order to obtain a deeper insight of the sources. Here, we present an estimation of GRB radio detections, showing that the GRBs can really be observed by the SKA. The approach that we present consists in determining blind detection rates derived by a very large sample consisting of merging several GRB catalogues observed by current missions as Swift, Fermi, Agile and INTEGRAL and by previous missions as BeppoSAX, CGRO, GRANAT, HETE-2, Ulysses and Wind. The final catalogue counts 7516 distinct sources. We compute the fraction of GRBs that could be observed by the SKA at high and low frequencies, above its observable sky. Considering the planned SKA sensitivity and through an extrapolation based on previous works and observations, we deduce the minimum fluence in the range 15-150 keV. This is the energy interval where a GRB should emit to be detectable in the radio band by the SKA. Results seem consistent with observational capabilities.