Ústav technické a experimentální fyziky Institute of Experimental and Applied Physics

Microphysics and dynamics of the gamma-ray burst 121024A

NázevTitle
Microphysics and dynamics of the gamma-ray burst 121024AMicrophysics and dynamics of the gamma-ray burst 121024A
Druh výsledkuResult type
Článek v časopiseJournal article
AutořiAuthors
K. Varela, H. van Eerten, J. Greiner, R. Filgas
DOIDOI
10.1051/0004-6361/201526260
Časopis / citaceJournal / citation
Astronomy & Astrophysics. 2016, 2016(589), ISSN 1432-0746.
RokYear
2016
JazykLanguage
eng
WoSWoS
000375318300049
ScopusScopus
2-s2.0-84964577720
RIVRIV
RIV/68407700:21670/16:00308305!RIV17-MSM-21670___
ProjektProject
Porovnání syntetických světelných křivek optických dosvitů gama záblesků s pozorovanými daty z detektoru GRONDComparing synthetic lightcurves of GRB afterglows with observational data from GROND.

AbstraktAbstract

Aims. The aim of the study is to constrain the physics of gamma-ray bursts (GRBs) by analysing the multi-wavelength afterglow data set of GRB 121024A that covers the full range from radio to X-rays. Methods. Using multi-epoch broad-band observations of the GRB 121024A afterglow, we measured the three characteristic break frequencies of the synchrotron spectrum. We used six epochs of combined XRT and GROND data to constrain the temporal slopes, the dust extinction, the X-ray absorption, and the spectral slope with high accuracy. Two more epochs of combined data from XRT, GROND, APEX, CARMA, and EVLA were used to set constraints on the break frequencies and therefore on the micro-physical and dynamical parameters. Results. The XRT and GROND light curves show a simultaneous and achromatic break at around 49 ks. As a result, the crossing of the synchrotron cooling break is no suitable explanation for the break in the light curve. The multi-wavelength data allow us to test two plausible scenarios explaining the break: a jet break, and the end of energy injection. The jet-break scenario requires a hard electron spectrum, a very low cooling break frequency, and a non-spreading jet. The energy injection avoids these problems, but requires is an element of(e) > 1 (k = 2), spherical outflow, and is an element of(B) < 10(-9). Conclusions. In light of the extreme microphysical parameters required by the energy-injection model, we favour a jet-break scenario where nu(m) < nu(sa) to explain the observations. This scenario gives physically meaningful microphysical parameters, and it also naturally explains the reported detection of linear and circular polarisation.

Aims. The aim of the study is to constrain the physics of gamma-ray bursts (GRBs) by analysing the multi-wavelength afterglow data set of GRB 121024A that covers the full range from radio to X-rays. Methods. Using multi-epoch broad-band observations of the GRB 121024A afterglow, we measured the three characteristic break frequencies of the synchrotron spectrum. We used six epochs of combined XRT and GROND data to constrain the temporal slopes, the dust extinction, the X-ray absorption, and the spectral slope with high accuracy. Two more epochs of combined data from XRT, GROND, APEX, CARMA, and EVLA were used to set constraints on the break frequencies and therefore on the micro-physical and dynamical parameters. Results. The XRT and GROND light curves show a simultaneous and achromatic break at around 49 ks. As a result, the crossing of the synchrotron cooling break is no suitable explanation for the break in the light curve. The multi-wavelength data allow us to test two plausible scenarios explaining the break: a jet break, and the end of energy injection. The jet-break scenario requires a hard electron spectrum, a very low cooling break frequency, and a non-spreading jet. The energy injection avoids these problems, but requires is an element of(e) > 1 (k = 2), spherical outflow, and is an element of(B) < 10(-9). Conclusions. In light of the extreme microphysical parameters required by the energy-injection model, we favour a jet-break scenario where nu(m) < nu(sa) to explain the observations. This scenario gives physically meaningful microphysical parameters, and it also naturally explains the reported detection of linear and circular polarisation.