Testing an unifying view of Gamma Ray Burst afterglows

TL;DR

This paper proposes a unifying model for GRB afterglows combining standard forward shock emission with a late prompt component, explaining diverse observational features and spectral behaviors.

Contribution

It introduces a combined model that accounts for complex optical and X-ray afterglow behaviors, including chromatic breaks and the absence of achromatic jet breaks.

Findings

Good agreement with observed light-curves despite diversity.

The late prompt component aligns with fallback accretion rates.

Spectral analysis confirms model consistency with observations.

Abstract

Four years after the launch the Swift satellite the nature of the Gamma Ray Bursts (GRBs) broadband afterglow behaviour is still an open issue ad the standard external shock fireball models cannot easily explain the puzzling combined temporal and spectral optical to X-ray behaviour of a large number of afterglows. We analysed the rest frame de-absorbed and K- corrected optical and X-ray multi-wavelength light-curves of a sample of 33 GRBs with known redshift and optical extinction at the host frame. We modelled their broadband behaviour as the sum of the standard forward shock emission due to the interaction of a fireball with the circum-burst medium and an additional component. We are able to obtain a good agreement with the observed light-curves despite their complexity and diversity and can also account for the lack of achromatic late times jet breaks in several GRBs and explain the presence of chromatic breaks. Even if the second component is treated in a phenomenological way, we can identify it as a "late prompt" emission due to a prolonged activity of the central engine produced by a mechanism similar to the one responsible for the early prompt emission. Our attempt can be considered as a first step towards the construction of a more physical scenario. A first important hint is that the "late prompt" temporal decay is intriguingly consistent with what expected with the the accretion rate of fallback material. In order to test our model also from the spectral point of view, we analysed the X-ray time resolved spectra and when possible the evolution of the optical to X-ray spectral energy distribution. All the events are found to be fully consistent with what predicted by our model.