Modeling of the Gamma Ray Burst photospheric emission: Monte Carlo simulation of the GRB prompt emission, numerical results and discussion

IF 1.8 4区 物理与天体物理 Q3 ASTRONOMY & ASTROPHYSICS
Amina Trabelsi, Mourad Fouka, Saad Ouichaoui, Amel Belhout
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Abstract

We have carried out a detailed study of the Gamma-Ray Burst (GRB) photospheric emission model predicting a quasi-blackbody spectrum slightly broader than a Planck function. This model was suggested within the relativistic fireball dynamics for interpreting a still not well understood thermal component in the GRB prompt emission, recently observed by the GBM (Gamma-ray Burst Monitor) on board the Fermi space telescope. We propose a Monte Carlo (M C) code for elucidating the observed spectrum, the outflow dynamics and its geometry for a basic and a structured plasma jets whose parameters are implemented. The code involves a simulation part describing the photon propagation assuming an unpolarized, non-dissipative relativistic outflow and a data analysis part for exploring main photospheric emission properties such as the energy, arrival time and observed flux of the simulated seed photons and the photospheric radius. Computing the latter two observables by numerical integration, we obtained values very concordant with the M C simulated results. Fitting Band functions to the photon spectra generated by this method, we derived best-fit values of the photon indices matching well those featuring the observed spectra for most typical GRBs, but corresponding to fit functions inconciliable with blackbody spectral shapes. Various derived results are reported, compared to previous ones and discussed. They show to be very sensitive to the structure of the Lorentz factor that plays a crucial role in determining the presence and strength of geometrical effects. The latter manifest themselves by large broadenings of the simulated spectra featured by multiple peak energies consistently with GRB observations. They are assumed, with multiple Compton scattering, to produce bumps pointed out at very low photon energies. The interpretation of GRB observations is further performed via a Band spectral analysis using the RMFIT software. Finally, developments of this work are put into perspective.

Abstract Image

伽马射线暴光层发射建模:伽马射线暴瞬时发射的蒙特卡罗模拟、数值结果和讨论
我们对伽马射线暴(Gramma-Ray Burst,GRB)光层发射模型进行了详细研究,该模型预测了一个比普朗克函数稍宽的准黑体光谱。该模型是在相对论火球动力学中提出的,用于解释伽马射线暴瞬时发射中仍未被很好理解的热成分,最近费米太空望远镜上的伽马射线暴监测器(GBM)观测到了这一现象。我们提出了一种蒙特卡洛(M C)代码,用于阐明观测到的光谱、流出动力学以及基本等离子体射流和结构等离子体射流的几何形状,其参数已经实现。该代码包括一个模拟部分和一个数据分析部分,前者用于描述假设为非极化、非耗散相对论外流的光子传播,后者用于探索主要的光层发射特性,如模拟种子光子的能量、到达时间和观测通量以及光层半径。通过数值积分计算后两个观测值,我们得到了与 M C 模拟结果非常一致的数值。根据这种方法生成的光子光谱拟合波段函数,我们得出了光子指数的最佳拟合值,这些值与大多数典型 GRB 的观测光谱非常吻合,但与黑体光谱形状不吻合的拟合函数相对应。报告了各种推导结果,并与以前的结果进行了比较和讨论。这些结果表明,它们对洛伦兹因子的结构非常敏感,而洛伦兹因子在确定几何效应的存在和强度方面起着至关重要的作用。后者表现为模拟光谱的大幅展宽,其特征是与 GRB 观测结果一致的多峰值能量。假定它们与多重康普顿散射一起,在极低的光子能量下产生凸起。通过使用 RMFIT 软件进行带状光谱分析,进一步解释了 GRB 观测结果。最后,对这项工作的发展进行了展望。
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来源期刊
Astrophysics and Space Science
Astrophysics and Space Science 地学天文-天文与天体物理
CiteScore
3.40
自引率
5.30%
发文量
106
审稿时长
2-4 weeks
期刊介绍: Astrophysics and Space Science publishes original contributions and invited reviews covering the entire range of astronomy, astrophysics, astrophysical cosmology, planetary and space science and the astrophysical aspects of astrobiology. This includes both observational and theoretical research, the techniques of astronomical instrumentation and data analysis and astronomical space instrumentation. We particularly welcome papers in the general fields of high-energy astrophysics, astrophysical and astrochemical studies of the interstellar medium including star formation, planetary astrophysics, the formation and evolution of galaxies and the evolution of large scale structure in the Universe. Papers in mathematical physics or in general relativity which do not establish clear astrophysical applications will no longer be considered. The journal also publishes topically selected special issues in research fields of particular scientific interest. These consist of both invited reviews and original research papers. Conference proceedings will not be considered. All papers published in the journal are subject to thorough and strict peer-reviewing. Astrophysics and Space Science features short publication times after acceptance and colour printing free of charge.
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