Implication of Jet Physics from MeV Line Emission of GRB 221009A

Ultra-relativistic jets are believed to play important role in producing prompt emission and afterglow of gamma-ray burst (GRB), but the nature of the jet is poorly known owing to the lacking of decisive features observed in the prompt emission. A series of bright, narrow and regularly-evolving MeV emission line detected in the brightest-of-all-time GRB 221009A provide unprecedented opportunity to probe GRB jet physics. The time evolution of the central energy of the line with power-law index -1 is naturally explained by high-latitude curvature effect. Under the assumption that the line emission is generated in the prompt emission by e^± pair production, cooling and annihilation in the jet, we can strictly constrain jet physics with observed line emission properties. We find the radius of the emission region is r∼10^16cm. The narrow line width of 10% implies that pairs cool fast down to non-relativistic state within a time of tenth of the dynamical time. This requires a magnetic-field energy density much larger than the prompt gamma-ray energy density in the jet, implying a magnetic field dominated jet. The temporal behavior of line flux suggests some angle dependence of line emission. We also discuss the difficulties of other scenarios to interpret the observed emission line.