Please use this identifier to cite or link to this item: http://hdl.handle.net/2381/18860
Title: Swift observations of GRB 060614: An anomalous burst with a well behaved afterglow
Authors: Mangano, V.
Troja, E.
La Parola V
Cusumano, G.
Mineo, T.
Holland, S. T.
Gehrels, N.
Holland, S. T.
Malesani, D.
Troja, E.
Osborne, J. P.
Troja, E.
Chincarini, G.
La Parola V
Guidorzi, C.
Romano, P.
Chincarini, G.
Campana, S.
Guidorzi, C.
Moretti, A.
Romano, P.
Tagliaferri, G.
Zhang, B.
Brown, P. J.
Burrows, D. N.
Grupe, D.
Roming, P. W. A.
Capalbi, M.
Giommi, P.
Perri, M.
Della Valle M
Pandey, S. B.
First Published: Jul-2007
Publisher: EDP Sciences for European Southern Observatory (ESO)
Citation: Astronomy & Astrophysics, 2007, 470 (1), pp. 105-118
Abstract: GRB 060614 is a remarkable gamma-ray burst (GRB) observed by Swift with puzzling properties, which challenge current progenitor models. In particular, the lack of any bright supernova (SN) down to very strict limits and the vanishing spectral lags during the whole burst are typical of short GRBs, strikingly at odds with the long (102 s) duration of this event. Here we present detailed spectral and temporal analysis of the Swift observations of GRB 060614. We show that the burst presents standard optical, ultraviolet and X-ray afterglows, detected beginning 4 ks after the trigger. An achromatic break is observed simultaneously in the optical and X-ray bands, at a time consistent with the break in the R-band light curve measured by the VLT. The achromatic behaviour and the consistent post-break decay slopes make GRB 060614 one of the best examples of a jet break for a Swift burst. The optical and ultraviolet afterglow light curves have also an earlier break at 29.7 $\pm$ 4.4 ks, marginally consistent with a corresponding break at 36.6 $\pm$ 2.4 ks observed in the X-rays. In the optical, there is strong spectral evolution around this break, suggesting the passage of a break frequency through the optical/ultraviolet band. The very blue spectrum at early times suggests this may be the injection frequency, as also supported by the trend in the light curves: rising at low frequencies, and decaying at higher energies. The early X-ray light curve (from 97 to 480 s) is well interpreted as the X-ray counterpart of the burst extended emission. Spectral analysis of the BAT and XRT data in the ~80 s overlap time interval show that the peak energy of the burst has decreased to as low as 8 keV at the beginning of the XRT observation. Spectral analysis of following XRT data shows that the peak energy of the burst continues to decrease through the XRT energy band and exits it at about 500 s after the trigger. The average peak energy $E_{\rm p}$ of the burst is likely below the BAT energy band (<24 keV at the 90% confidence level) but larger than 8 keV. The initial group of peaks observed by BAT (~5 s) is however distinctly harder than the rest of the prompt emission, with a peak energy of about 300 keV as measured by Konus Wind. Considering the time-averaged spectral properties, GRB 060614 is consistent with the $E_{\rm iso}-E_{\rm p}^{\rm rest}$, $E_{\gamma}-E_{\rm p}^{\rm rest}$, and $L_{\rm p,iso}-E_{\rm p}^{\rm rest}$ correlations.
DOI Link: 10.1051/0004-6361:20077232
ISSN: 0004-6361
eISSN: 1432-0746
Links: http://hdl.handle.net/2381/18860
http://www.aanda.org/articles/aa/abs/2007/28/aa7232-07/aa7232-07.html
Version: Publisher Version
Status: Peer-reviewed
Type: Journal Article
Rights: Copyright © 2007 ESO. Reproduced with permission from Astronomy & Astrophysics, © ESO.
Appears in Collections:Published Articles, Dept. of Physics and Astronomy

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