Neutrino and cosmic-ray emission from multiple internal shocks in gamma-ray bursts

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Neutrino and cosmic-ray emission from multiple internal shocks in gamma-ray bursts. / Bustamante, Mauricio; Baerwald, Philipp; Murase, Kohta; Winter, Walter.

In: Nature Communications, Vol. 6, 6783, 09.09.2014.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Bustamante, M, Baerwald, P, Murase, K & Winter, W 2014, 'Neutrino and cosmic-ray emission from multiple internal shocks in gamma-ray bursts', Nature Communications, vol. 6, 6783. https://doi.org/10.1038/ncomms7783

APA

Bustamante, M., Baerwald, P., Murase, K., & Winter, W. (2014). Neutrino and cosmic-ray emission from multiple internal shocks in gamma-ray bursts. Nature Communications, 6, [6783]. https://doi.org/10.1038/ncomms7783

Vancouver

Bustamante M, Baerwald P, Murase K, Winter W. Neutrino and cosmic-ray emission from multiple internal shocks in gamma-ray bursts. Nature Communications. 2014 Sep 9;6. 6783. https://doi.org/10.1038/ncomms7783

Author

Bustamante, Mauricio ; Baerwald, Philipp ; Murase, Kohta ; Winter, Walter. / Neutrino and cosmic-ray emission from multiple internal shocks in gamma-ray bursts. In: Nature Communications. 2014 ; Vol. 6.

Bibtex

@article{cd3af88fbf1a49a981bdbe01226a138d,
title = "Neutrino and cosmic-ray emission from multiple internal shocks in gamma-ray bursts",
abstract = "Gamma-ray bursts are short-lived, luminous explosions at cosmological distances, thought to originate from relativistic jets launched at the deaths of massive stars. They are among the prime candidates to produce the observed cosmic rays at the highest energies. Recent neutrino data have, however, started to constrain this possibility in the simplest models with only one emission zone. In the classical theory of gamma-ray bursts, it is expected that particles are accelerated at mildly relativistic shocks generated by the collisions of material ejected from a central engine. We consider neutrino and cosmic-ray emission from multiple emission regions since these internal collisions must occur at very different radii, from below the photosphere all the way out to the circumburst medium, as a consequence of the efficient dissipation of kinetic energy. We demonstrate that the different messengers originate from different collision radii, which means that multi-messenger observations open windows for revealing the evolving GRB outflows.",
keywords = "astro-ph.HE, hep-ph",
author = "Mauricio Bustamante and Philipp Baerwald and Kohta Murase and Walter Winter",
year = "2014",
month = sep,
day = "9",
doi = "10.1038/ncomms7783",
language = "English",
volume = "6",
journal = "Nature Communications",
issn = "2041-1723",
publisher = "nature publishing group",

}

RIS

TY - JOUR

T1 - Neutrino and cosmic-ray emission from multiple internal shocks in gamma-ray bursts

AU - Bustamante, Mauricio

AU - Baerwald, Philipp

AU - Murase, Kohta

AU - Winter, Walter

PY - 2014/9/9

Y1 - 2014/9/9

N2 - Gamma-ray bursts are short-lived, luminous explosions at cosmological distances, thought to originate from relativistic jets launched at the deaths of massive stars. They are among the prime candidates to produce the observed cosmic rays at the highest energies. Recent neutrino data have, however, started to constrain this possibility in the simplest models with only one emission zone. In the classical theory of gamma-ray bursts, it is expected that particles are accelerated at mildly relativistic shocks generated by the collisions of material ejected from a central engine. We consider neutrino and cosmic-ray emission from multiple emission regions since these internal collisions must occur at very different radii, from below the photosphere all the way out to the circumburst medium, as a consequence of the efficient dissipation of kinetic energy. We demonstrate that the different messengers originate from different collision radii, which means that multi-messenger observations open windows for revealing the evolving GRB outflows.

AB - Gamma-ray bursts are short-lived, luminous explosions at cosmological distances, thought to originate from relativistic jets launched at the deaths of massive stars. They are among the prime candidates to produce the observed cosmic rays at the highest energies. Recent neutrino data have, however, started to constrain this possibility in the simplest models with only one emission zone. In the classical theory of gamma-ray bursts, it is expected that particles are accelerated at mildly relativistic shocks generated by the collisions of material ejected from a central engine. We consider neutrino and cosmic-ray emission from multiple emission regions since these internal collisions must occur at very different radii, from below the photosphere all the way out to the circumburst medium, as a consequence of the efficient dissipation of kinetic energy. We demonstrate that the different messengers originate from different collision radii, which means that multi-messenger observations open windows for revealing the evolving GRB outflows.

KW - astro-ph.HE

KW - hep-ph

U2 - 10.1038/ncomms7783

DO - 10.1038/ncomms7783

M3 - Journal article

VL - 6

JO - Nature Communications

JF - Nature Communications

SN - 2041-1723

M1 - 6783

ER -

ID: 184745690