High-energy neutrino signatures of dark matter

Buckley, Matthew R.; Spolyar, Douglas; Freese, Katherine; Murayama, Hitoshi

doi:10.1103/physrevd.81.016006

Cited by 50 publications

(47 citation statements)

References 81 publications

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“…[2,3], and encompasses the experimental resolution of the neutrino detectors. (We note that future measurement by IceCube+DeepCore will lead to sensitive limits at high energy [61,62].) At low energies E ν 100 MeV, the relevant data come from the diffuse supernova neutrino background (DSNB) search performed by the SK experiment [63].…”

Section: B Decay Into Neutrinosmentioning

confidence: 99%

Lifetime constraints for late dark matter decay

2010

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We consider a class of late-decaying dark-matter models, in which a dark matter particle decays to a heavy stable daughter of approximately the same mass, together with one or more relativistic particles which carry away only a small fraction of the parent rest mass. Such decays can affect galactic halo structure and evolution, and have been invoked as a remedy to some of the small-scale structure-formation problems of cold dark matter. There are existing stringent limits on the dark matter lifetime if the decays produce photons. By considering examples in which the relativistic decay products instead consist of neutrinos or electron-position pairs, we derive stringent limits on these scenarios for a wide range of dark matter masses. We thus eliminate a sizable portion of the parameter space for these late-decay models if the dominant decay channel involves Standard Model final states.PACS numbers: 95.35.+d, 95.85.Pw, 98.62.Gq, 98.70.Vc

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Section: B Decay Into Neutrinosmentioning

confidence: 99%

Lifetime constraints for late dark matter decay

2010

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“…This will allow the galactic neutrino flux to be measured and compared against the atmospheric neutrino flux, providing a constraint on dark matter decays and annihilations. Recent work [47,48] by some of the authors shows that IceCube+DeepCore will be able to significantly constrain the parameter space of decays to µ + µ − , and rule out decays to τ + τ − and annihilation to µ + µ − as possible sources of the anomalies in less than five years of running.…”

Section: Introductionmentioning

confidence: 99%

Cascade events at IceCube + DeepCore as a definitive constraint on the dark matter interpretation of the PAMELA and Fermi anomalies

et al. 2010

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Dark matter decaying or annihilating into µ + µ − or τ + τ − has been proposed as an explanation for the e ± anomalies reported by PAMELA and Fermi. Recent analyses show that IceCube, supplemented by DeepCore, will be able to significantly constrain the parameter space of decays to µ + µ − , and rule out decays to τ + τ − and annihilations to µ + µ − in less than five years of running. These analyses rely on measuring track-like events in IceCube+DeepCore from down-going ν µ . In this paper we show that by instead measuring cascade events, which are induced by all neutrino flavors, IceCube+DeepCore can rule out decays to µ + µ − in only three years of running, and rule out decays to τ + τ − and annihilation to µ + µ − in only one year of running. These constraints are highly robust to the choice of dark matter halo profile and independent of dark matter-nucleon cross section.arXiv:0911.5188v4 [hep-ph]

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“…But, the presence of additional astrophysical sources can change the situation [137]. Independent of the gravitino model, it has been pointed out that the decays of the dark matter particle could be new signals for unification where the dark matter candidate decays through dimension-six operators suppressed by two powers of GUT scale [138][139][140]. Finally, there has also been some discussion about the possibilities of dark matter consisting of two particles, out of which one is the decaying partner.…”

Section: The Interpretationsmentioning

confidence: 96%

Results from PAMELA, ATIC and FERMI: Pulsars or dark matter?

2011

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It is well known that dark matter dominates the dynamics of galaxies and clusters of galaxies. Its constituents remain a mystery despite an assiduous search for them over the past three decades. Recent results from the satellite-based PAMELA experiment show an excess in the positron fraction at energies between 10 and 100 GeV in the secondary cosmic ray spectrum. Other experiments, namely ATIC, HESS and FERMI, show an excess in the total electron (e + + e − ) spectrum for energies greater than 100 GeV. These excesses in the positron fraction as well as the electron spectrum can arise in local astrophysical processes like pulsars, or can be attributed to the annihilation of the dark matter particles. The latter possibility gives clues to the possible candidates for the dark matter in galaxies and other astrophysical systems. In this article, we give a report of these exciting developments.

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High-energy neutrino signatures of dark matter

Cited by 50 publications

References 81 publications

Lifetime constraints for late dark matter decay

Lifetime constraints for late dark matter decay

Cascade events at IceCube + DeepCore as a definitive constraint on the dark matter interpretation of the PAMELA and Fermi anomalies

Results from PAMELA, ATIC and FERMI: Pulsars or dark matter?

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