On the External Inverse Compton Scattering off the Prompt Emission in GRB 221009A

TL;DR

This paper models the external inverse Compton scattering process in GRB 221009A, revealing how prompt emission influences early TeV afterglow and identifying the dominant emission mechanisms during different phases.

Contribution

It provides a detailed analysis of the EIC process considering anisotropy and the ratio of dissipation to shock radii, offering new insights into TeV emission origins in GRBs.

Findings

EIC dominates early TeV afterglow emission.

The EIC scattering rate varies by a factor of ~2 with radius ratio.

Gamma-gamma absorption is insufficient to explain early TeV rise.

Abstract

The light curve of the TeV emission in GRB 221009A displays a smooth transition from an initial rapid rise to a slower rise and eventually a decay phase. The smooth temporal profile of the TeV emission suggests that it mainly results from an external shock. The temporal overlap between the prompt KeV-MeV emission and the early TeV afterglow indicates that external inverse Compton scattering (EIC) between the prompt KeV-MeV photons and the afterglow electrons is inevitable. Since the energy density of the prompt emission is much higher than that of the afterglow during the early phase, the EIC process dominates the cooling of afterglow electrons. The EIC scattering rate is influenced by the anisotropy of the seed photon field, which depends on the radii of the internal dissipation ($R_{\rm dis}$), where the prompt emission is produced, and that of the external shock ($R_{\rm ext}$), where the afterglow emission is produced. We investigate the EIC process for different values of $R_{\rm dis}/R_{\rm ext}$. We find that, for varying \( R_{\rm dis}/R_{\rm ext} \), the EIC scattering rate can differ by a factor of $\sim 2$. For GRB 221009A, the EIC emission is dominated during the early rising phase of the TeV afterglow. It then transitions to a phase dominated by the synchrotron self-Compton (SSC) emission as the intensity of the prompt emission decreases. Additionally, we investigate the effect of $\gamma \gamma$ absorption in the TeV afterglow caused by prompt MeV photons and find that it is insufficient to explain the early rapid rise in the TeV afterglow, even in the case of $R_{\rm dis}/R_{\rm ext} \sim 1$.