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Probing sub-eV Dark Matter decays with PTOLEMY

When the Dark Matter mass is below the eV-scale, its cosmological occupation number exceeds the ones of photons from the cosmic microwave background as well as of relic neutrinos. If such Dark Matter decays to pairs of neutrinos, it implies that experiments that seek the detection of the cosmic neut...

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Autores principales: Bondarenko, Kyrylo, Boyarsky, Alexey, Nikolic, Marco, Pradler, Josef, Sokolenko, Anastasia
Lenguaje:eng
Publicado: 2020
Materias:
Acceso en línea:https://dx.doi.org/10.1088/1475-7516/2021/03/089
http://cds.cern.ch/record/2748723
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author Bondarenko, Kyrylo
Boyarsky, Alexey
Nikolic, Marco
Pradler, Josef
Sokolenko, Anastasia
author_facet Bondarenko, Kyrylo
Boyarsky, Alexey
Nikolic, Marco
Pradler, Josef
Sokolenko, Anastasia
author_sort Bondarenko, Kyrylo
collection CERN
description When the Dark Matter mass is below the eV-scale, its cosmological occupation number exceeds the ones of photons from the cosmic microwave background as well as of relic neutrinos. If such Dark Matter decays to pairs of neutrinos, it implies that experiments that seek the detection of the cosmic neutrino background may as well be sensitive to this additional form of “dark radiation”. Here we study the prospects for detection taking into account various options for the forecasted performance of the future PTOLEMY experiment. From a detailed profile likelihood analysis we find that Dark Matter decays with lifetime as large as 104 Gyr or a sub-% Dark Matter fraction decaying today can be discovered. The prospects are facilitated by the distinct spectral event shape that is introduced from galactic and cosmological neutrino dark radiation fluxes. In the process we also clarify the importance of Pauli-blocking in the Dark Matter decay. The scenarios presented in this work can be considered early physics targets in the development of these instruments with relaxed demands on performance and energy resolution.
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institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2020
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spelling cern-27487232022-08-26T02:03:22Zdoi:10.1088/1475-7516/2021/03/089http://cds.cern.ch/record/2748723engBondarenko, KyryloBoyarsky, AlexeyNikolic, MarcoPradler, JosefSokolenko, AnastasiaProbing sub-eV Dark Matter decays with PTOLEMYhep-phParticle Physics - Phenomenologyastro-ph.COAstrophysics and AstronomyWhen the Dark Matter mass is below the eV-scale, its cosmological occupation number exceeds the ones of photons from the cosmic microwave background as well as of relic neutrinos. If such Dark Matter decays to pairs of neutrinos, it implies that experiments that seek the detection of the cosmic neutrino background may as well be sensitive to this additional form of “dark radiation”. Here we study the prospects for detection taking into account various options for the forecasted performance of the future PTOLEMY experiment. From a detailed profile likelihood analysis we find that Dark Matter decays with lifetime as large as 104 Gyr or a sub-% Dark Matter fraction decaying today can be discovered. The prospects are facilitated by the distinct spectral event shape that is introduced from galactic and cosmological neutrino dark radiation fluxes. In the process we also clarify the importance of Pauli-blocking in the Dark Matter decay. The scenarios presented in this work can be considered early physics targets in the development of these instruments with relaxed demands on performance and energy resolution.When the Dark Matter mass is below the eV-scale, its cosmological occupation number exceeds the ones of photons from the cosmic microwave background as well as of relic neutrinos. If such Dark Matter decays to pairs of neutrinos, it implies that experiments that seek the detection of the cosmic neutrino background may as well be sensitive to this additional form of "dark radiation". Here we study the prospects for detection taking into account various options for the forecasted performance of the future PTOLEMY experiment. From a detailed profile likelihood analysis we find that Dark Matter decays with lifetime as large as $10^4$ Gyr or a sub-% Dark Matter fraction decaying today can be discovered. The prospects are facilitated by the distinct spectral event shape that is introduced from galactic and cosmological neutrino dark radiation fluxes. In the process we also clarify the importance of Pauli-blocking in the Dark Matter decay. The scenarios presented in this work can be considered early physics targets in the development of these instruments with relaxed demands on performance and energy resolution.arXiv:2012.09704oai:cds.cern.ch:27487232020-12-17
spellingShingle hep-ph
Particle Physics - Phenomenology
astro-ph.CO
Astrophysics and Astronomy
Bondarenko, Kyrylo
Boyarsky, Alexey
Nikolic, Marco
Pradler, Josef
Sokolenko, Anastasia
Probing sub-eV Dark Matter decays with PTOLEMY
title Probing sub-eV Dark Matter decays with PTOLEMY
title_full Probing sub-eV Dark Matter decays with PTOLEMY
title_fullStr Probing sub-eV Dark Matter decays with PTOLEMY
title_full_unstemmed Probing sub-eV Dark Matter decays with PTOLEMY
title_short Probing sub-eV Dark Matter decays with PTOLEMY
title_sort probing sub-ev dark matter decays with ptolemy
topic hep-ph
Particle Physics - Phenomenology
astro-ph.CO
Astrophysics and Astronomy
url https://dx.doi.org/10.1088/1475-7516/2021/03/089
http://cds.cern.ch/record/2748723
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AT pradlerjosef probingsubevdarkmatterdecayswithptolemy
AT sokolenkoanastasia probingsubevdarkmatterdecayswithptolemy