Solar atmospheric neutrinos: A new neutrino floor for dark matter searches

As is well known, dark matter direct detection experiments will ultimately be limited by a “neutrino floor,” due to the scattering of nuclei by MeV neutrinos from, e.g., nuclear fusion in the Sun. Here we point out the existence of a new neutrino floor that will similarly limit indirect detection wi...

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Bibliographic Details
Published in:Physical review. D 2017-11, Vol.96 (10), Article 103006
Main Authors: Ng, Kenny C. Y., Beacom, John F., Peter, Annika H. G., Rott, Carsten
Format: Article
Language:English
Subjects:
Cosmic rays
Dark matter
Energy dissipation
Floors
Neutrinos
Nuclear fusion
Sensitivity
Solar atmosphere
Solar magnetic field
Sun
Weakly interacting massive particles
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Summary:As is well known, dark matter direct detection experiments will ultimately be limited by a “neutrino floor,” due to the scattering of nuclei by MeV neutrinos from, e.g., nuclear fusion in the Sun. Here we point out the existence of a new neutrino floor that will similarly limit indirect detection with the Sun, due to high-energy neutrinos from cosmic-ray interactions with the solar atmosphere. We have two key findings. First, solar atmospheric neutrinos ≲1  TeV cause a sensitivity floor for standard weakly interacting massive particles (WIMP) scenarios, for which higher-energy neutrinos are absorbed in the Sun. This floor will be reached once the present sensitivity is improved by just 1 order of magnitude. Second, for neutrinos ≳1  TeV, which can be isolated by muon energy loss rate, solar atmospheric neutrinos should soon be detectable in IceCube. Discovery will help probe the complicated effects of solar magnetic fields on cosmic rays. These events will be backgrounds to WIMP scenarios with long-lived mediators, for which higher-energy neutrinos can escape from the Sun.
ISSN:2470-0010
2470-0029
DOI:10.1103/PhysRevD.96.103006