期刊
ASTROPHYSICAL JOURNAL
卷 947, 期 2, 页码 -出版社
IOP Publishing Ltd
DOI: 10.3847/1538-4357/acc57d
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In this paper, the dynamics and radiation physics of the afterglow of the rare event GRB 221009A are modeled in detail. By introducing a top-hat jet in an environment dominated by stellar winds, the observations of the afterglow associated with GRB 221009A over the first week are explained. The model predicts a luminous very high energy afterglow for GRB 221009A based on the synchrotron self-Compton process.
In this paper, we model the dynamics and radiation physics of the rarity event GRB 221009A afterglow in detail. By introducing a top-hat jet that propagates in an environment dominated by stellar winds, we explain the publicly available observations of afterglow associated with GRB 221009A over the first week. It is predicted that GRB 221009A emits a luminous very high energy afterglow based on the synchrotron self-Compton (SSC) process in our model. We show the broadband spectral energy distribution (SED) analysis results of GRB 221009A and find that the SSC radiation component of GRB 221009A is very bright in the 0.1-10 TeV band. The integrated SED shows that the SSC emission in the TeV band has detection sensitivity significantly higher than that of LHASSO, MAGIC, and CTA. However, since the release of further observations, deviations from the standard wind environment model have gradually shown up in data. For example, the late-time multiband afterglow cannot be consistently explained under the standard wind environment scenario. It may be necessary to consider modeling with a structured jet with complex geometry or a partial revision of the standard model. Furthermore, we find that the inclusion of GeV observations could break the degeneracy between model parameters, highlighting the significance of high-energy observations in determining accurate parameters for GRB afterglows.
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