AGM2015: Antineutrino Global Map 2015

Every second greater than 10 25 antineutrinos radiate to space from Earth, shining like a faint antineutrino star. Underground antineutrino detectors have revealed the rapidly decaying fission products inside nuclear reactors, verified the long-lived radioactivity inside our planet and informed sens...

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Bibliographic Details
Published in:Scientific reports 2015-09, Vol.5 (1), p.13945-13945, Article 13945
Main Authors: Usman, S.M., Jocher, G.R., Dye, S.T., McDonough, W.F., Learned, J.G.
Format: Article
Language:English
Subjects:
639/33/445/209
639/766/419/1131
Earth
Energy
Fission products
Fluctuations
Humanities and Social Sciences
Lithosphere
Mapping
multidisciplinary
Neutrinos
Nuclear reactors
Radioactivity
Reactors
Science
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Summary:Every second greater than 10 25 antineutrinos radiate to space from Earth, shining like a faint antineutrino star. Underground antineutrino detectors have revealed the rapidly decaying fission products inside nuclear reactors, verified the long-lived radioactivity inside our planet and informed sensitive experiments for probing fundamental physics. Mapping the anisotropic antineutrino flux and energy spectrum advance geoscience by defining the amount and distribution of radioactive power within Earth while critically evaluating competing compositional models of the planet. We present the Antineutrino Global Map 2015 (AGM2015), an experimentally informed model of Earth’s surface antineutrino flux over the 0 to 11 MeV energy spectrum, along with an assessment of systematic errors. The open source AGM2015 provides fundamental predictions for experiments, assists in strategic detector placement to determine neutrino mass hierarchy and aids in identifying undeclared nuclear reactors. We use cosmochemically and seismologically informed models of the radiogenic lithosphere/mantle combined with the estimated antineutrino flux, as measured by KamLAND and Borexino, to determine the Earth’s total antineutrino luminosity at . We find a dominant flux of geo-neutrinos, predict sub-equal crust and mantle contributions, with ~1% of the total flux from man-made nuclear reactors.
ISSN:2045-2322
2045-2322
DOI:10.1038/srep13945