Abstract
Flares in the X-ray afterglow of gamma-ray bursts (GRBs) share more characteristics with the prompt emission than the afterglow, such as pulse profile and contained fluence. As a result, they are believed to originate from late-time activity of the central engine and can be used to constrain the overall energy budget. In this paper, we collect a sample of $19$ long GRBs observed by \emph{Swift}-XRT that contain giant flares in their X-ray afterglows. We fit this sample with a version of the magnetar propeller model, modified to include fallback accretion. This model has already successfully reproduced extended emission in short GRBs. Our best fits provide a reasonable morphological match to the light curves. However, $16$ out of $19$ of the fits require efficiencies for the propeller mechanism that approach $100\%$. The high efficiency parameters are a direct result of the high energy contained in the flares and the extreme duration of the dipole component, which forces either slow spin periods or low magnetic fields. We find that even with the inclusion of significant fallback accretion, in all but a few cases it is energetically challenging to produce prompt emission, afterglow and giant flares within the constraints of the rotational energy budget of a magnetar.
Highlights
Gamma-ray bursts (GRBs) are intense explosions that outshine any other source in the gamma-ray sky while they are active (Meszaros 2006)
Flares are a dramatic rebrightening in the X-ray light curve that are seen ∼ 30 − 105 seconds after the burst trigger (Burrows et al 2005b; Beniamini & Kumar 2016) and are observed in approximately half of all GRBs detected by Swift-X-ray Telescope (XRT) (O’Brien et al 2006; Curran et al 2008; Swenson & Roming 2014)
We test the feasibility of one of the most natural long-lived central engines: the magnetar model, in which the rotational energy of a highly-magnetised millisecond neutron star is released to the surrounding environment via its intense dipole field
Summary
Gamma-ray bursts (GRBs) are intense explosions that outshine any other source in the gamma-ray sky while they are active (Meszaros 2006). We use a Markov chain Monte Carlo (MCMC) simulation package (Foreman-Mackey et al 2013) to find the optimal values for our 9 free parameters: B - magnetic field strength of the magnetar; Pi - spin period of the magnetar; MD,i - disc mass; - RD - disc radius; - fallback timescale fraction; δ - fallback mass budget fraction; ηdip - dipole energy to luminosity conversion efficiency; ηprop - propeller energy to luminosity conversion efficiency; and 1/ fB - beaming fraction (please see Appendix A for a discussion of the correlations between these fitting parameters and why a degeneracy treatment is not required).
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