IceCube Sensitivity for Low-Energy Neutrinos from Nearby Supernovae

IceCube Collaboration: R. Abbasi; Y. Abdou; T. Abu-Zayyad; M.; Ackermann; J. Adams; J. A. Aguilar; M. Ahlers; M. M. Allen; D. Altmann; K.; Andeen; J. Auffenberg; X. Bai; M. Baker; S. W. Barwick; V. Baum; R. Bay; J.; L. Bazo Alba; K. Beattie; J. J. Beatty; S. Bechet; J. K. Becker; K.-H.; Becker; M. L. Benabderrahmane; S. BenZvi; J. Berdermann; P. Berghaus; D.; Berley; E. Bernardini; D. Bertrand; D. Z. Besson; D. Bindig; M. Bissok; E.; Blaufuss; J. Blumenthal; D. J. Boersma; C. Bohm; D. Bose; S. B\"oser; O.; Botner; A. M. Brown; S. Buitink; K. S. Caballero-Mora; M. Carson; D. Chirkin,; B. Christy; F. Clevermann; S. Cohen; C. Colnard; D. F. Cowen; A. H. Cruz; Silva; M. V. D'Agostino; M. Danninger; J. Daughhetee; J. C. Davis; C. De; Clercq; T. Degner; L. Demir\"ors; F. Descamps; P. Desiati; G. de; Vries-Uiterweerd; T. DeYoung; J. C. Diaz-V\'elez; M. Dierckxsens; J. Dreyer,; J. P. Dumm; M. Dunkman; J. Eisch; R. W. Ellsworth; O. Engdeg{\aa}rd; S.; Euler; P. A. Evenson; O. Fadiran; A. R. Fazely; A. Fedynitch; J. Feintzeig,; T. Feusels; K. Filimonov; C. Finley; T. Fischer-Wasels; B. D. Fox; A.; Franckowiak; R. Franke; T. K. Gaisser; J. Gallagher; L. Gerhardt; L.; Gladstone; T. Gl\"usenkamp; A. Goldschmidt; J. A. Goodman; D. G\'ora; D.; Grant; T. Griesel; A. Gro{\ss}; S. Grullon; M. Gurtner; C. Ha; A. Haj Ismail,; A. Hallgren; F. Halzen; K. Han; K. Hanson; D. Heinen; K. Helbing; R.; Hellauer; S. Hickford; G. C. Hill; K. D. Hoffman; B. Hoffmann; A. Homeier; K.; Hoshina; W. Huelsnitz; J.-P. H\"ul{\ss}; P. O. Hulth; K. Hultqvist; S.; Hussain; A. Ishihara; E. Jakobi; J. Jacobsen; G. S. Japaridze; H. Johansson,; K.-H. Kampert; A. Kappes; T. Karg; A. Karle; P. Kenny; J. Kiryluk; F. Kislat,; S. R. Klein; H. K\"ohne; G. Kohnen; H. Kolanoski; L. K\"opke; S. Kopper; D.; J. Koskinen; M. Kowalski; T. Kowarik; M. Krasberg; G. Kroll; N. Kurahashi; T.; Kuwabara; M. Labare; K. Laihem; H. Landsman; M. J. Larson; R. Lauer; J.; L\"unemann; J. Madsen; A. Marotta; R. Maruyama; K. Mase; H. S. Matis; K.; Meagher; M. Merck; P. M\'esz\'aros; T. Meures; S. Miarecki; E. Middell; N.; Milke; J. Miller; T. Montaruli; R. Morse; S. M. Movit; R. Nahnhauer; J. W.; Nam; U. Naumann; D. R. Nygren; S. Odrowski; A. Olivas; M. Olivo; A.; O'Murchadha; S. Panknin; L. Paul; C. P\'erez de los Heros; J. Petrovic; A.; Piegsa; D. Pieloth; R. Porrata; J. Posselt; P. B. Price; G. T. Przybylski; K.; Rawlins; P. Redl; E. Resconi; W. Rhode; M. Ribordy; A. S. Richard; M.; Richman; J. P. Rodrigues; F. Rothmaier; C. Rott; T. Ruhe; D. Rutledge; B.; Ruzybayev; D. Ryckbosch; H.-G. Sander; M. Santander; S. Sarkar; K. Schatto,; T. Schmidt; A. Sch\"onwald; A. Schukraft; L. Schulte; A. Schultes; O. Schulz,; M. Schunck; D. Seckel; B. Semburg; S. H. Seo; Y. Sestayo; S. Seunarine; A.; Silvestri; K. Singh; A. Slipak; G. M. Spiczak; C. Spiering; M. Stamatikos; T.; Stanev; T. Stezelberger; R. G. Stokstad; A. St\"o{\ss}l; E. A. Strahler; R.; Str\"om; M. St\"uer; G. W. Sullivan; Q. Swillens; H. Taavola; I. Taboada; A.; Tamburro; A. Tepe; S. Ter-Antonyan; S. Tilav; P. A. Toale; S. Toscano; D.; Tosi; N. van Eijndhoven; J. Vandenbroucke; A. Van Overloop; J. van Santen; M.; Vehring; M. Voge; C. Walck; T. Waldenmaier; M. Wallraff; M. Walter; Ch.; Weaver; C. Wendt; S. Westerhoff; N. Whitehorn; K. Wiebe; C. H. Wiebusch; D.; R. Williams; R. Wischnewski; H. Wissing; M. Wolf; T. R. Wood; K. Woschnagg,; C. Xu; D. L. Xu; X. W. Xu; J. P. Yanez; G. Yodh; S. Yoshida; P. Zarzhitsky,; M. Zoll

arXiv:1108.0171·astro-ph.HE·April 26, 2017

IceCube Sensitivity for Low-Energy Neutrinos from Nearby Supernovae

IceCube Collaboration: R. Abbasi, Y. Abdou, T. Abu-Zayyad, M., Ackermann, J. Adams, J. A. Aguilar, M. Ahlers, M. M. Allen, D. Altmann, K., Andeen, J. Auffenberg, X. Bai, M. Baker, S. W. Barwick, V. Baum, R. Bay, J., L. Bazo Alba, K. Beattie, J. J. Beatty, S. Bechet, J. K. Becker

PDF

1 Repo

TL;DR

IceCube can detect low-energy neutrinos from nearby supernovae with high sensitivity, providing valuable data on supernova dynamics, neutrino properties, and potential exotic phenomena like black hole formation.

Contribution

This paper demonstrates IceCube's capability to detect MeV neutrinos from supernovae, extending its use beyond high-energy neutrino astronomy to supernova monitoring.

Findings

01

Sensitivity matches megaton-scale detectors for galactic supernovae

02

Detects subtle features in supernova neutrino burst timing

03

Potential to observe supernova signatures like neutronization burst

Abstract

This paper describes the response of the IceCube neutrino telescope located at the geographic South Pole to outbursts of MeV neutrinos from the core collapse of nearby massive stars. IceCube was completed in December 2010 forming a lattice of 5160 photomultiplier tubes that monitor a volume of ~ 1 cubic kilometer in the deep Antarctic ice for particle induced photons. The telescope was designed to detect neutrinos with energies greater than 100 GeV. Owing to subfreezing ice temperatures, the photomultiplier dark noise rates are particularly low. Hence IceCube can also detect large numbers of MeV neutrinos by observing a collective rise in all photomultiplier rates on top of the dark noise. With 2 ms timing resolution, IceCube can detect subtle features in the temporal development of the supernova neutrino burst. For a supernova at the galactic center, its sensitivity matches that of a…

Peer Reviews

No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.

Code & Models

Repositories

IceCubeOpenSource/ASTERIA
none

Videos

No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.