External Shock in a Multi-Bursting Gamma-ray Burst: Energy Injection Phase induced by the Later Launched Ejecta

TL;DR

This paper investigates how later-launched ejecta in gamma-ray bursts interact with the external shock, affecting observed emission timing and providing explanations for observed optical delays and energy injection phenomena.

Contribution

It introduces a model linking the timing of ejecta interactions with external shocks to Lorentz factors and medium density, explaining observed delays and energy injections in GRBs.

Findings

The relation between collision and observation times depends on ejecta Lorentz factor and medium density.

Low Lorentz factor or density leads to larger collision times compared to observation times.

The model explains large optical delays and energy injection features in specific GRBs.

Abstract

Central engine of gamma-ray bursts (GRBs) may be intermittent and launch several episodes of ejecta separated by a long quiescent interval. In this scenario, an external shock is formed due to the propagation of the first launched ejecta into the circum-burst medium and the later launched ejecta may interact with the external shock at later period. Owing to the internal dissipation, the later launched ejecta may be observed at a later time ($t_{\rm{jet}}$). In this paper, we study the relation of $t_{\rm{b}}$ and $t_{\rm{jet}}$, where $t_{\rm{b}}$ is the collision time of the later launched ejecta with the formed external shock. It is found that the relation of $t_{\rm{b}}$ and $t_{\rm{jet}}$ depends on the bulk Lorentz factor ($\Gamma_{\rm{jet}}$) of the later launched ejecta and the density ($\rho$) of the circum-burst medium. If the value of $\Gamma_{\rm{jet}}$ or $\rho$ is low, the $t_{\rm{b}}$ would be significantly larger than $t_{\rm{jet}}$. However, the $t_{\rm{b}}\sim t_{\rm{jet}}$ can be found if the value of $\Gamma_{\rm{jet}}$ or $\rho$ is significantly large. Our results can explain the large lag of the optical emission relative to the $\gamma$-ray/X-ray emission in GRBs, e.g., GRB~111209A. For GRBs with a precursor, our results suggest that the energy injection into the external shock and thus more than one external-reverse shock may appear in the main prompt emission phase. According to our model, we estimate the Lorentz factor of the second launched ejecta in GRB~160625B.