The origin of icecube's neutrinos: Cosmic ray accelerators embedded in star forming calorimeters

Research output: Chapter in Book/Report/Conference proceedingChapter

Abstract

The IceCube collaboration reports a detection of extra-terrestrial neutrinos. The isotropy and flavor content of the signal, and the coincidence, within current uncertainties, of the 50 TeV to 2 PeV flux and the spectrum with the Waxman- Bahcall bound, suggest a cosmological origin of the neutrinos, related to the sources of ultra-high energy, <1010 GeV, cosmic-rays (UHECR). The most natural explanation of the UHECR and neutrino signals is that both are produced by the same population of cosmological sources, producing CRs (likely protons) at a similar rate, E2dn˙ /dE α E0, over the [1 PeV, 1011 GeV] energy range, and residing in "calorimetric" environments, like galaxies with high star formation rates, in which E/Z < 100 PeV CRs lose much of their energy to pion production. A tenfold increase in the effective mass of the detector at ≥ 100 TeV is required in order to significantly improve the accuracy of current measurements, to enable the detection of a few bright nearby starburst "calorimeters", and to open the possibility of identifying the CR sources embedded within the calorimeters, by associating neutrinos with photons accompanying transient events responsible for their generation. Source identification and a large neutrino sample may enable one to use astrophysical neutrinos to constrain new physics models.

Original languageEnglish
Title of host publicationNeutrino Astronomy
Subtitle of host publicationCurrent Status, Future Prospects
EditorsThomas Gaisser, Albrecht Karle
PublisherWorld Scientific Publishing Co.
Chapter3
Pages33-45
Number of pages13
ISBN (Electronic)9789814759410
ISBN (Print)9789814759403
DOIs
StatePublished - May 2017

All Science Journal Classification (ASJC) codes

  • General Physics and Astronomy

Fingerprint

Dive into the research topics of 'The origin of icecube's neutrinos: Cosmic ray accelerators embedded in star forming calorimeters'. Together they form a unique fingerprint.

Cite this