Quasi-blackbody component and radiative efficiency of the prompt emission of gamma-ray bursts

TL;DR

This study analyzes the thermal component in gamma-ray burst prompt emission, revealing its temporal behavior, significant energy contribution, and potential to probe the physical properties of the GRB fireball.

Contribution

It provides the first detailed time-resolved analysis of the thermal photospheric component in a large sample of GRBs, linking thermal emission to fireball properties.

Findings

Thermal component peaks at hundreds of keV and shows characteristic temporal evolution.

Thermal photons contribute 30-50% of the prompt emission energy.

Thermal emission can be used to infer physical parameters of the GRB fireball.

Abstract

We perform time-resolved spectroscopy on the prompt emission in gamma-ray bursts (GRBs) and identify a thermal, photospheric component peaking at a temperature of a few hundreds keV. This peak does not necessarily coincide with the broad band (keV-GeV) power peak. We show that this thermal component exhibits a characteristic temporal behavior. We study a sample of 56 long bursts, all strong enough to allow time-resolved spectroscopy. We analyze the evolution of both the temperature and flux of the thermal component in 49 individual time-resolved pulses, for which the temporal coverage is sufficient, and find that the temperature is nearly constant during the first few seconds, after which it decays as a power law with a sample-averaged index of -0.68. The thermal flux first rises with an averaged power-law index of 0.63 after which it decays with an averaged index of -2. The break times are the same to within errors. We find that the ratio of the observed to the emergent thermal flux typically exhibits a monotoneous power-law increase during the entire pulse as well as during complex bursts. Thermal photons carry a significant fraction ($\sim$ 30 % to more than 50%) of the prompt emission energy (in the observed 25-1900 keV energy band), thereby significantly contributing to the high radiative efficiency. Finally, we show here that the thermal emission can be used to study the properties of the photosphere, hence the physical parameters of the GRB fireball.