http://arxiv.org/abs/1901.04925
The characteristics of the spectral evolution for the prompt emission of gamma-ray bursts (GRBs), which is closely related to the radiation mechanism (synchrotron or photosphere), is still an unsolved subject. Here, by performing the detailed time-resolved spectral fitting of GRB 131231A, which has a very bright and well-defined single pulse, some interesting spectral evolution features have been found. (i) Both the low-energy spectral index $\alpha$ and the peak energy $E_{\rm pk}$ exhibit the ‘flux-tracking’ pattern. (ii) The parameter relations, i.e., $F$(the energy flux)-$\alpha$, $F$-$E_{\rm pk}$, and $E_{\rm pk}$-$\alpha$, along with the analogous Yonetoku $E_{\rm pk}$-$L_{\gamma,\rm iso}$ relation for the different time-resolved spectra, show strong monotonous (positive) correlations, both in the rising and the decaying phases. (iii) The values of $\alpha$ do not exceed the synchrotron limit ($\alpha$= -2/3) in all slices across the pulse, favoring the synchrotron origin. Such distinct features previously unidentified call for physical interpretations. We argue that the one-zone synchrotron emission model with the emitter streaming away from the central engine can explain all these special spectral evolution characteristics.
L. Li, J. Geng, Y. Meng, et. al.
Wed, 16 Jan 19
8/76
Comments: 14 pages, 8 figures, 2 tables, submitted to ApJL
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