Constraining the contribution of Gamma-Ray Bursts to the high-energy   diffuse neutrino flux with 10 years of ANTARES data

ANTARES Collaboration: A. Albert; M. Andr\'e; M. Anghinolfi; G. Anton,; M. Ardid; J.-J. Aubert; J. Aublin; B. Baret; S. Basa; B. Belhorma; V. Bertin,; S. Biagi; M. Bissinger; J. Boumaaza; M. Bouta; M.C. Bouwhuis; H.; Br\^anza\c{s}; R. Bruijn; J. Brunner; J. Busto; A. Capone; L. Caramete; J.; Carr; S. Celli; M. Chabab; T. N. Chau; R. Cherkaoui El Moursli; T. Chiarusi,; M. Circella; A. Coleiro; M. Colomer-Molla; R. Coniglione; P. Coyle; A.; Creusot; A. F. D\'iaz; G. de Wasseige; A. Deschamps; C. Distefano; I. Di; Palma; A. Domi; C. Donzaud; D. Dornic; D. Drouhin; T. Eber; N. El Khayati; A.; Enzenh\"ofer; A. Ettahiri; P. Fermani; G. Ferrara; F. Filippini; L. Fusco; P.; Gay; H. Glotin; R. Gozzini; K. Graf; C. Guidi; S. Hallmann; H. van Haren,; A.J. Heijboer; Y. Hello; J.J. Hern\'andez-Rey; J. H\"o{\ss}l; J. Hofest\"adt,; F. Huang; G. Illuminati; C. W. James; M. de Jong; P. de Jong; M. Jongen; M.; Kadler; O. Kalekin; U. Katz; N.R. Khan-Chowdhury; A. Kouchner; I.; Kreykenbohm; V. Kulikovskiy; R. Lahmann; R. Le Breton; D. Lef\`evre; E.; Leonora; G. Levi; M. Lincetto; D. Lopez-Coto; S. Loucatos; G. Maggi; J.; Manczak; M. Marcelin; A. Margiotta; A. Marinelli; J.A. Mart\'inez-Mora; S.; Mazzou; K. Melis; P. Migliozzi; M. Moser; A. Moussa; R. Muller; L. Nauta; S.; Navas; E. Nezri; A. Nu\~nez-Casti\~neyra; B. O'Fearraigh; M. Organokov; G.E.; P\u{a}v\u{a}la\c{s}; C. Pellegrino; M. Perrin-Terrin; P. Piattelli; C.; Poir\`e; V. Popa; T. Pradier; N. Randazzo; S. Reck; G. Riccobene; A. Romanov,; A. S\'anchez-Losa; D. F. E. Samtleben; M. Sanguineti; P. Sapienza; J.; Schnabe; F. Sch\"ussler; M. Spurio; Th. Stolarczyk; B. Strandberg; M. Taiuti,; Y. Tayalati; T. Thakore; S.J. Tingay; B. Vallage; V. Van Elewyck; F. Versari,; S. Viola; D. Vivolo; J. Wilms; A. Zegarelli; J.D. Zornoza; J. Z\'u\~niga

arXiv:2008.02127·astro-ph.HE·December 21, 2020

Constraining the contribution of Gamma-Ray Bursts to the high-energy diffuse neutrino flux with 10 years of ANTARES data

ANTARES Collaboration: A. Albert, M. Andr\'e, M. Anghinolfi, G. Anton,, M. Ardid, J.-J. Aubert, J. Aublin, B. Baret, S. Basa, B. Belhorma, V. Bertin,, S. Biagi, M. Bissinger, J. Boumaaza, M. Bouta, M.C. Bouwhuis, H., Br\^anza\c{s}, R. Bruijn, J. Brunner, J. Busto, A. Capone

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TL;DR

This study uses 10 years of ANTARES data to constrain the contribution of Gamma-Ray Bursts to the high-energy diffuse neutrino flux, finding it to be less than 10%, thus limiting their role as primary sources.

Contribution

The paper provides the first comprehensive analysis of ANTARES data to limit the neutrino flux contribution from GRBs within the internal shock model framework.

Findings

01

No neutrino events detected in coincidence with GRBs.

02

GRB contribution to diffuse neutrino flux is constrained to less than 10%.

03

Model parameters significantly affect neutrino flux predictions.

Abstract

Addressing the origin of the astrophysical neutrino flux observed by IceCube is of paramount importance. Gamma-Ray Bursts (GRBs) are among the few astrophysical sources capable of achieving the required energy to contribute to such neutrino flux through p $γ$ interactions. In this work, ANTARES data have been used to search for upward going muon neutrinos in spatial and temporal coincidence with 784 GRBs occurred from 2007 to 2017. For each GRB, the expected neutrino flux has been calculated in the framework of the internal shock model and the impact of the lack of knowledge on the majority of source redshifts and on other intrinsic parameters of the emission mechanism has been quantified. It is found that the model parameters that set the radial distance where shock collisions occur have the largest impact on neutrino flux expectations. In particular, the bulk Lorentz factor of the…

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