Numerical Modeling of Gamma-Ray Burst Spectra

The model of gamma-ray burst (GRB) from magnetorotational supernova after its explosion is proposed in order to investigate burst gamma radiation spectrum. Formation and radiative acceleration of the collimated jet inside the channel in the Compton plasma cloud formed around the metallic core is con...

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Vydáno v:Lobachevskii journal of mathematics Ročník 46; číslo 1; s. 121 - 132
Hlavní autoři: Lartsev, A. I., Lukin, V. V.
Médium: Journal Article
Jazyk:angličtina
Vydáno: Moscow Pleiades Publishing 01.01.2025
Springer Nature B.V
Témata:
Acceleration
Algebra
Analysis
Approximation
Black body radiation
Elastic scattering
Energy
Flow velocity
Fluid mechanics
Gamma ray astronomy
Gamma ray bursts
Gamma rays
Gas dynamics
Geometry
Graphics processing units
Hydrodynamics
Light speed
Mathematical Logic and Foundations
Mathematical models
Mathematics
Mathematics and Statistics
Numerical models
Photons
Plasma
Plasma clouds
Probability Theory and Stochastic Processes
Radiation
Radiation pressure
Radiative transfer
Relativistic effects
Relativistic velocity
Spectra
Three dimensional models
mathematical modelling
2010 Mathematics Subject Classification: 65M08
gamma-ray burst
relativistic jet
radiation transfer
Compton scattering
computational astrophysics
ISSN:1995-0802, 1818-9962
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Shrnutí:The model of gamma-ray burst (GRB) from magnetorotational supernova after its explosion is proposed in order to investigate burst gamma radiation spectrum. Formation and radiative acceleration of the collimated jet inside the channel in the Compton plasma cloud formed around the metallic core is considered. The observed spectrum is proposed to be the result of rising from the star and cloud photons scattering during the relativistic stream acceleration. These phenomena are described by a three-dimensional model of relativistic radiative hydrodynamics including the full radiative transfer equation with scattering integral. Due to relativistic speed of the flow one need to use a Compton scattering model that takes into account the change in photon frequency when colliding with fast-moving electrons. To obtain numerical solution of the radiation gas dynamics equations the splitting method is used. For the radiative transfer equation with scattering the short characteristics method is used, and for the relativistic hydrodynamics the Godunov-type one. The algorithm is designed for tetrahedral meshes and adapted for computations on cluster systems with graphics processing units. The central object radiation pressure accelerated the matter up to 90 of the light speed and the observed spectrum shifted from black-body radiation to the X-ray range. The spectra for observator different points of view are calculated.
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ISSN:1995-0802
1818-9962
DOI:10.1134/S1995080224608373