Testing the newborn pulsar origin of ultrahigh energy cosmic rays with EeV neutrinos

Ke Fang; Kumiko Kotera; Kohta Murase; Angela V. Olinto

doi:10.1103/PhysRevD.90.103005

Testing the newborn pulsar origin of ultrahigh energy cosmic rays with EeV neutrinos

Ke Fang
, Kumiko Kotera
, Kohta Murase
, Angela V. Olinto

Research output: Contribution to journal › Article › peer-review

101 Scopus citations

Abstract

Fast-spinning newborn pulsars are intriguing candidate sources of ultrahigh-energy cosmic rays (UHECRs). The acceleration of particles with a given composition in a fraction of the extragalactic pulsar population can give a consistent explanation for the measurements of the Auger Observatory. We calculate the associated diffuse neutrino flux produced while particles cross the supernova ejecta surrounding the stars. We show that in the minimal pulsar scenarios that are compatible with the UHECR data, the effective optical depth to hadronuclear interactions is larger than unity at ultrahigh energies. Thus, even in the most pessimistic case, one expects energy fluxes of ∼0.1-1EeV neutrinos that should be detectable with IceCube or the Askaryan Radio Array within a decade.

Original language	English (US)
Article number	103005
Journal	Physical Review D - Particles, Fields, Gravitation and Cosmology
Volume	90
Issue number	10
DOIs	https://doi.org/10.1103/PhysRevD.90.103005
State	Published - Nov 14 2014

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Physics and Astronomy (miscellaneous)

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10.1103/PhysRevD.90.103005

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title = "Testing the newborn pulsar origin of ultrahigh energy cosmic rays with EeV neutrinos",

abstract = "Fast-spinning newborn pulsars are intriguing candidate sources of ultrahigh-energy cosmic rays (UHECRs). The acceleration of particles with a given composition in a fraction of the extragalactic pulsar population can give a consistent explanation for the measurements of the Auger Observatory. We calculate the associated diffuse neutrino flux produced while particles cross the supernova ejecta surrounding the stars. We show that in the minimal pulsar scenarios that are compatible with the UHECR data, the effective optical depth to hadronuclear interactions is larger than unity at ultrahigh energies. Thus, even in the most pessimistic case, one expects energy fluxes of ∼0.1-1EeV neutrinos that should be detectable with IceCube or the Askaryan Radio Array within a decade.",

author = "Ke Fang and Kumiko Kotera and Kohta Murase and Olinto, \{Angela V.\}",

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AU - Fang, Ke

AU - Kotera, Kumiko

AU - Murase, Kohta

AU - Olinto, Angela V.

PY - 2014/11/14

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N2 - Fast-spinning newborn pulsars are intriguing candidate sources of ultrahigh-energy cosmic rays (UHECRs). The acceleration of particles with a given composition in a fraction of the extragalactic pulsar population can give a consistent explanation for the measurements of the Auger Observatory. We calculate the associated diffuse neutrino flux produced while particles cross the supernova ejecta surrounding the stars. We show that in the minimal pulsar scenarios that are compatible with the UHECR data, the effective optical depth to hadronuclear interactions is larger than unity at ultrahigh energies. Thus, even in the most pessimistic case, one expects energy fluxes of ∼0.1-1EeV neutrinos that should be detectable with IceCube or the Askaryan Radio Array within a decade.

AB - Fast-spinning newborn pulsars are intriguing candidate sources of ultrahigh-energy cosmic rays (UHECRs). The acceleration of particles with a given composition in a fraction of the extragalactic pulsar population can give a consistent explanation for the measurements of the Auger Observatory. We calculate the associated diffuse neutrino flux produced while particles cross the supernova ejecta surrounding the stars. We show that in the minimal pulsar scenarios that are compatible with the UHECR data, the effective optical depth to hadronuclear interactions is larger than unity at ultrahigh energies. Thus, even in the most pessimistic case, one expects energy fluxes of ∼0.1-1EeV neutrinos that should be detectable with IceCube or the Askaryan Radio Array within a decade.

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Testing the newborn pulsar origin of ultrahigh energy cosmic rays with EeV neutrinos

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