2019
DOI: 10.1088/1475-7516/2019/11/046
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Decaying dark matter at IceCube and its signature on High Energy gamma experiments

Abstract: The origin of neutrino flux observed in IceCube is still mainly unknown. Typically two flux components are assumed, namely: atmospheric neutrinos and an unknown astrophysical term. In principle the latter could also contain a top-down contribution coming for example from decaying dark matter. In this case one should also expect prompt and secondary gamma's as well. This leads to the possibility of a multimessenger analysis based on the simultaneous comparison of the Dark Matter hypothesis both with neutrino an… Show more

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Cited by 39 publications
(45 citation statements)
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References 127 publications
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“…Independent of UV motivations, there is a clear reason to consider searching for such DM: the robust experimental program to probe astrophysical messengers at higher energies. Many instruments can probe heavy DM, including HAWC [32], IceCube [5,[33][34][35][36][37][38], ANTARES [39,40], Pierre Auger Observatory [41][42][43][44], Telescope Array [45,46], and in the future CTA [47,48], LHAASO [49,50], IceCube-Gen2 [51], and KM3NET [52,53]. Taken together, these experiments demonstrate that in the coming years we will continue to probe the universe at higher energies and to greater sensitivities.…”
Section: Introductionmentioning
confidence: 97%
“…Independent of UV motivations, there is a clear reason to consider searching for such DM: the robust experimental program to probe astrophysical messengers at higher energies. Many instruments can probe heavy DM, including HAWC [32], IceCube [5,[33][34][35][36][37][38], ANTARES [39,40], Pierre Auger Observatory [41][42][43][44], Telescope Array [45,46], and in the future CTA [47,48], LHAASO [49,50], IceCube-Gen2 [51], and KM3NET [52,53]. Taken together, these experiments demonstrate that in the coming years we will continue to probe the universe at higher energies and to greater sensitivities.…”
Section: Introductionmentioning
confidence: 97%
“…We extend the analysis to masses at lower energies up to 100 GeV for annihilating DM, and find that even at lower energies, the APS analysis offers a robust way to interpret the neutrino sky [13]. Both instruments will be sensitive to the present 7.5-year HESE best-fit of the decaying DM component [14], shown with a black stars in the figure . As the APS analysis relies on angular information only, it is robust against any degeneracies in the neutrino energy spectrum expected from astrophysical sources as well as in DM particles.…”
Section: Dark Matter Neutrino Skymentioning
confidence: 93%
“…In the context of explaining the IceCube results, this scenario has been discussed in particular in Refs. [255][256][257][258][259][260]. The entire observed neutrino spectrum from tens of TeV to tens of PeV cannot be explained in this way, because the energy distribution of the decay products is noticeably narrower, but this mechanism can explain the observed flux at some energies.…”
Section: Models Of the Galactic Flux Componentmentioning
confidence: 97%