Unveiling the Multifaceted GRB 200613A: Prompt Emission Dynamics, Afterglow Evolution, and the Host Galaxy's Properties

Abstract

We present our optical observations and multi-wavelength analysis of the GRB\,200613A detected by Fermi satellite. Time-resolved spectral analysis of the prompt γ-ray emission was conducted utilizing the Bayesian block method to determine statistically optimal time bins. Based on the Bayesian Information Criterion (BIC), the data generally favor the Band+Blackbody (short as BB) model. We speculate that the main Band component comes from the Blandford-Znajek mechanism, while the additional BB component comes from the neutrino annihilation process. The BB component becomes significant for a low-spin, high-accretion rate black hole central engine, as evidenced by our model comparison with the data. The afterglow light curve exhibits typical power-law decay, and its behavior can be explained by the collision between the ejecta and constant interstellar medium (ISM). Model fitting yields the following parameters: EK,iso = (2.04+11.8-1.50)× 1053 erg, 0=354+578-217, p=2.09+0.02-0.03, n18=(2.04+9.71-1.87)× 102 cm-3, θj=24.0+6.50-5.54 degree, εe=1.66+4.09-1.39)× 10-1 and εB=(7.76+48.5-5.9)× 10-6. In addition, we employed the public Python package Prospector perform a spectral energy distribution (SED) modeling of the host galaxy. The results suggest that the host galaxy is a massive galaxy ((M / M)=11.75+0.10-0.09) with moderate star formation rate (SFR=22.58+13.63-7.22 M/yr). This SFR is consistent with the SFR of 34.2 M yr-1 derived from the [OII] emission line in the observed spectrum.

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