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A Semianalytic Afterglow with Thermal Electrons and Synchrotron Self-Compton Emission

Donald C. Warren, Maria Giovanna Dainotti, Maxim V. Barkov, Björn Ahlgren, Hirotaka Ito, Shigehiro Nagataki

2022The Astrophysical Journal21 citationsDOIOpen Access PDF

Abstract

Abstract We extend previous work on gamma-ray burst afterglows involving hot thermal electrons at the base of a shock-accelerated tail. Using a physically motivated electron distribution based on first-principles simulations, we compute the broadband emission from radio to TeV gamma rays. For the first time, we present the effects of a thermal distribution of electrons on synchrotron self-Compton emission. The presence of thermal electrons causes temporal and spectral structure across the entire observable afterglow, which is substantively different from models that assume a pure power-law distribution for the electrons. We show that early-time TeV emission is enhanced by more than an order of magnitude for our fiducial parameters, with a time-varying spectral index that does not occur for a pure power law of electrons. We further show that the X-ray closure relations take a very different, also time-dependent, form when thermal electrons are present; the shape traced out by the X-ray afterglows is a qualitative match to observations of the traditional decay phase.

Topics & Concepts

AfterglowPhysicsElectronSynchrotronThermalSynchrotron radiationPower lawAtomic physicsAstrophysicsGamma-ray burstNuclear physicsStatisticsMathematicsMeteorologyGamma-ray bursts and supernovaeAstrophysics and Cosmic PhenomenaPulsars and Gravitational Waves Research
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