Evolution of an electron-positron plasma produced by induced gravitational collapse in binary-driven hypernovae

The binary-driven hypernova (BdHN) model has been introduced in the past years, to explain a subfamily of gamma-ray bursts (GRBs) with energies E iso ≥ 10 52 erg associated with type Ic supernovae. Such BdHNe have as progenitor a tight binary system composed of a carbon-oxigen (CO) core and a neutro...

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Main Authors: Melon Fuksman, J. D., Becerra, L., L. Bianco, C., Karlica, M., Kovacevic, M., Moradi, R., Muccino, M., B. Pisani, G., Primorac, D., A. Rueda, J., Ruffini, R., Vereshchagin, G. V., Wang, Y.
Format: Conference Proceeding
Language:English
Subjects:
Binary stars
Computational fluid dynamics
Ejecta
Ejection
Electron-positron plasmas
Evolution
Flares
Fluid flow
Gamma ray bursts
Gamma rays
Gravitation
Gravitational collapse
Hydrodynamics
Mathematical models
Supernovae
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Summary:The binary-driven hypernova (BdHN) model has been introduced in the past years, to explain a subfamily of gamma-ray bursts (GRBs) with energies E iso ≥ 10 52 erg associated with type Ic supernovae. Such BdHNe have as progenitor a tight binary system composed of a carbon-oxigen (CO) core and a neutron star undergoing an induced gravitational collapse to a black hole, triggered by the CO core explosion as a supernova (SN). This collapse produces an optically-thick e + e - plasma, which expands and impacts onto the SN ejecta. This process is here considered as a candidate for the production of X-ray flares, which are frequently observed following the prompt emission of GRBs. In this work we follow the evolution of the e + e - plasma as it interacts with the SN ejecta, by solving the equations of relativistic hydrodynamics numerically. Our results are compatible with the Lorentz factors estimated for the sources that produce the flares, of typically Γ ≲ 4.
ISSN:2100-014X
2101-6275
2100-014X
DOI:10.1051/epjconf/201816804009