Jet simulations and gamma-ray burst afterglow jet breaks

TitleJet simulations and gamma-ray burst afterglow jet breaks
Publication TypeJournal Article
Year of Publication2011
AuthorsH.J van Eerten, Z. Meliani, R Wijers, R. Keppens
JournalMonthly Notices of the Royal Astronomical Society
Volume410
Issue3
Number3
Pagination2016-2024
Date PublishedFeb
Type of ArticleArticle
ISBN Number0035-8711
Keywords990510, ADAPTIVE MESH REFINEMENT, DYNAMICS, EMISSION, ENERGETICS, EXPANSION, FIREBALL, gamma-ray burst: general, gamma-ray burst: individual: GRB030329, GRB, hydrodynamics, LIGHT CURVES, MODEL, radiation mechanisms: non-thermal, RELATIVISTIC BLAST WAVES, shock waves, X-rays: general
Abstract

The conventional derivation of the gamma-ray burst afterglow jet break time uses only the blast wave fluid Lorentz factor and therefore leads to an achromatic break. We show that in general gamma-ray burst afterglow jet breaks are chromatic across the self-absorption break. Depending on circumstances, the radio jet break may be postponed significantly. Using high-accuracy adaptive mesh fluid simulations in one dimension, coupled to a detailed synchrotron radiation code, we demonstrate that this is true even for the standard fireball model and hard-edged jets. We confirm these effects with a simulation in two dimensions. The frequency dependence of the jet break is a result of the angle dependence of the emission, the changing optical depth in the self-absorbed regime and the shape of the synchrotron spectrum in general. In the optically thin case the conventional analysis systematically overestimates the jet break time, leading to inferred opening angles that are underestimated by a factor of similar to 1.3 and explosion energies that are underestimated by a factor of similar to 1.7, for explosions in a homogeneous environment. The methods presented in this paper can be applied to adaptive mesh simulations of arbitrary relativistic fluid flows. All analysis presented here makes the usual assumption of an on-axis observer.

DOI10.1111/j.1365-2966.2010.17582.X
Division

FP

Department

CPP-HT

PID

78ceb1c75f24d1972ecca20ef703ce10

Alternate TitleMon. Not. Roy. Astron. Soc.
LabelOA

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