X-ray and GeV afterglows and sub-TeV emission of GRB 180720B

TL;DR

This paper models the multi-wavelength afterglow of GRB 180720B within the BdHN I framework, explaining X-ray, GeV, and sub-TeV emissions through processes involving a binary progenitor, a black hole, and a neutron star.

Contribution

It provides a comprehensive physical model linking the GRB's afterglow emissions to the binary progenitor system and black hole physics, including new insights into the origin of sub-TeV emission.

Findings

Determined the black hole's mass and spin from GeV emission.

Explained the X-ray afterglow as pulsar-like emission from the neutron star.

Proposed a glitch event as the source of sub-TeV emission.

Abstract

GRB 180720B, observed by {\it Fermi}-GBM, with redshift $z=0.653$, isotropic energy $E_{\rm iso}=5.92\times 10^{53}$ erg, and X-ray afterglow observed by the XRT onboard the Neil Gehrels Swift satellite, is here classified as a Binary-driven Hypernova I (BdHN I). BdHN I are long GRBs with a binary progenitor composed of a carbon-oxygen core (CO$_{\rm core}$) and a neutron star (NS) companion with orbital period $\sim 5$ min. The gravitational collapse of the CO$_{\rm core}$ generates a supernova (SN) and a new NS ($\nu$NS) at its center. The SN hypercritical accretion onto the companion NS triggers its gravitational collapse forming a black hole (BH). An electrodynamical process near the BH horizon leads to the long-lasting GeV emission with power-law luminosity $L_{\rm GeV}\propto t^{-1.19\pm0.04}$, powered by the BH rotational energy. Correspondingly, we determine the BH mass and spin. The $\nu$NS via its pulsar-like emission and fallback accretion injects energy into the magnetized SN ejecta generating synchrotron radiation. This explains the \textit{long-lasting} X-ray afterglow with power-law luminosity $L_X \propto t^{-1.48\pm 0.32}$, energized by the $\nu$NS rotational energy. We apply this to GRB 180720B determining the $\nu$NS magnetic field and spin. We also analyze the GRB 180720B emission observed by the High-Energy Stereoscopic System (H.E.S.S.), at $100$-$440$ GeV energies, $10.1$-$12.1$ h after the Fermi-GBM trigger. We propose that this \textit{short-term} radiation of energy $2.4\times 10^{50}$ erg and duration $\sim 10^3$ s, is powered by a "glitch" event that suddenly injects relativistic electrons into the $\nu$NS magnetosphere during its slowing down phase.