Abstract
Since the report of the PeV-TeV neutrinos by the IceCube Collaboration, various particle physics models have been proposed to explain the neutrino spectrum by dark matter particles decaying into neutrinos and other Standard Model particles.In such scenarios, simultaneous $\gamma$-ray emission is commonly expected. Therefore, multi-messenger connections are generally important for the indirect searches of dark matters. The recent development of $\gamma$-ray astronomy puts stringent constraints on the properties of dark matter, especially by observations with the Fermi $\gamma$-ray satellite in the last several years. Motivated by the lack of $\gamma$-ray as well as the shape of the neutrino spectrum observed by IceCube, we discuss a scenario in which the DM is a PeV scale particle which couples strongly to other invisible particles and its decay products do not contain a charged particle. As an example to realize such possibilities, we consider a model of fermionic dark matter that decays into a neutrino and many invisible fermions. The dark matter decay is secluded in the sense that the emitted products are mostly neutrinos and dark fermions. One remarkable feature of this model is the resulting broadband neutrino spectra around the energy scale of the dark matter. We apply this model to multi-PeV dark matter, and discuss possible observable consequences in light of the IceCube data. In particular, this model could account for the large flux at medium energies of $\sim10-100$ TeV, possibly as well as the second peak at PeV, without violating the stringent $\gamma$-ray constraints from Fermi and air-shower experiments such as CASA-MIA.
Highlights
High-energy neutrinos are powerful probes of the Universe in astrophysics and cosmology
Motivated by the lack of γ-ray as well as the shape of the neutrino spectrum observed by IceCube, we discuss a scenario in which the dark matter (DM) is a PeV scale particle which couples strongly to other invisible particles and its decay products do not contain a charged particle
We propose a new decaying DM scenario where the DM is very weakly coupled to the standard model particles so that it is almost stable, but is very strongly coupled to other nonstandard-model particles so that it has a finite size to make the annihilation cross section larger than the naive unitarity limit and to make the broad spectrum of neutrinos possible in addition to the line at PeV
Summary
High-energy neutrinos are powerful probes of the Universe in astrophysics and cosmology. The flavor ratio is consistent with νe∶νμ∶ντ ≈ 1∶1∶1 [5,13], as expected in the long baseline limit of neutrino oscillation In astrophysical models, those high-energy neutrinos can be produced by proton-proton (pp) and/or proton-gamma (pγ) interactions [14,15,16] induced by accelerated primary cosmic rays. Those high-energy neutrinos can be produced by proton-proton (pp) and/or proton-gamma (pγ) interactions [14,15,16] induced by accelerated primary cosmic rays In this kind of scenarios, extragalactic sources may be favored because the observed neutrinos are isotropically distributed. The energy spectrum measured at IceCube has a board component around Oð10–100Þ TeV as well as a peak at PeV This structure does not seem to be explained solely by the decay of the DM.
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