Optical and X-ray early follow-up of ANTARES neutrino alerts

S. Adrian-Martinez; M. Ageron; A. Albert; I. Al Samarai; M. Andre; G.; Anton; M. Ardid; J.-J. Aubert; B. Baret; J. Barrios-Marti; S. Basa; V.; Bertin; S. Biagi; C. Bogazzi; R. Bormuth; M. Bou-Cabo; M.C. Bouwhuis; R.; Bruijn; J. Brunner; J. Busto; A. Capone; L. Caramete; J. Carr; T. Chiarusi,; M. Circella; R. Coniglione; H. Costantini; P. Coyle; A. Creusot; I. Dekeyser,; A. Deschamps; G. De Bonis; C. Distefano; C. Donzaud; D. Dornic; D. Drouhin,; A. Dumas; T. Eberl; D. Elsasser; A. Enzenhofer; K. Fehn; I. Felis; P.; Fermani; F. Folger; L.A. Fusco; S. Galata; P. Gay; S. Gei{\ss}elsoder; K.; Geyer; V. Giordano; A. Gleixner; R. Gracia-Ruiz; K. Graf; H. van Haren; A.J.; Heijboer; Y. Hello; J.J. Hernandez-Rey; A. Herrero; J. Ho{\ss}l; J.; Hofestadt; C. Hugon; C.W James; M. de Jong; M. Kadler; O. Kalekin; U. Katz,; D. Kie{\ss}ling; P. Kooijman; A. Kouchner; I. Kreykenbohm; V. Kulikovskiy; R.; Lahmann; G. Lambard; D. Lattuada; D. Lefevre; E. Leonora; S. Loucatos; S.; Mangano; M. Marcelin; A. Margiotta; J.A. Martinez-Mora; S. Martini; A.; Mathieu; T. Michael; P. Migliozzi; A. Moussa; C. Mueller; M. Neff; E. Nezri,; G.E. Pavalas; C. Pellegrino; C. Perrina; P. Piattelli; V. Popa; T. Pradier,; C. Racca; G. Riccobene; R. Richter; K. Roensch; A. Rostovtsev; M. Saldana; D.; F. E. Samtleben; M. Sanguineti; P. Sapienza; J. Schmid; J. Schnabel; S.; Schulte; F. Sch\"ussler; T. Seitz; C. Sieger; M. Spurio; J.J.M. Steijger; Th.; Stolarczyk; A. Sanchez-Losa; M. Taiuti; C. Tamburini; A. Trovato; M.; Tselengidou; C. Tonnis; D. Turpin; B. Vallage; C. Vallee; V. Van Elewyck; M.; Vecchi; E. Visser; D. Vivolo; S. Wagner; J. Wilms; J.D. Zornoza; J. Zuniga,; A. Klotz; M. Boer; A. Le Van Suu; C. Akerlof; W. Zheng; P. Evans; N. Gehrels,; J. Kennea; J.P. Osborne; D.M. Coward

arXiv:1508.01180·astro-ph.HE·March 16, 2016

Optical and X-ray early follow-up of ANTARES neutrino alerts

S. Adrian-Martinez, M. Ageron, A. Albert, I. Al Samarai, M. Andre, G., Anton, M. Ardid, J.-J. Aubert, B. Baret, J. Barrios-Marti, S. Basa, V., Bertin, S. Biagi, C. Bogazzi, R. Bormuth, M. Bou-Cabo, M.C. Bouwhuis, R., Bruijn, J. Brunner, J. Busto, A. Capone, L. Caramete, J. Carr

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TL;DR

This paper presents a multi-messenger follow-up program combining ANTARES neutrino alerts with optical and X-ray observations to identify transient astrophysical sources, but no counterparts were detected in the analyzed data.

Contribution

Developed the TAToO follow-up system that rapidly triggers optical and X-ray telescopes after neutrino detections to search for transient sources.

Findings

01

No optical or X-ray counterparts found for 49 neutrino alerts.

02

Upper limits on transient source brightness were established.

03

The probability to exclude gamma-ray burst origins was calculated for each alert.

Abstract

High-energy neutrinos could be produced in the interaction of charged cosmic rays with matter or radiation surrounding astrophysical sources. Even with the recent detection of extraterrestrial high-energy neutrinos by the IceCube experiment, no astrophysical neutrino source has yet been discovered. Transient sources, such as gamma-ray bursts, core-collapse supernovae, or active galactic nuclei are promising candidates. Multi-messenger programs offer a unique opportunity to detect these transient sources. By combining the information provided by the ANTARES neutrino telescope with information coming from other observatories, the probability of detecting a source is enhanced, allowing the possibility of identifying a neutrino progenitor from a single detected event. A method based on optical and X-ray follow-ups of high-energy neutrino alerts has been developed within the ANTARES…

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