Neutrino mass without lepton number violation, dark matter; and a strongly first-order phase transition

Neutrino mass without lepton number violation, dark matter; and a strongly first-order phase transition

We propose a model to explain the tiny masses of neutrinos with lepton number conservation, where neither too heavy particles beyond the TeV-scale nor tiny coupling constants are required. Assignments of conserving lepton numbers to new fields result in an unbroken Z2 symmetry that stabilizes the da...

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Veröffentlicht in:Physical review. D 2017-11, Vol.96 (9), Article 095024
Hauptverfasser: Kanemura, Shinya, Sakurai, Kodai, Sugiyama, Hiroaki
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Sprache:eng
Schlagworte:
Asymmetry
Baryons
Constraint modelling
Cosmology
Dark matter
Electroweak model
Leptons
Neutrinos
Numbers
Phase transitions
Phenomenology
Standard model (particle physics)
Universe
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container_title Physical review. D
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creator Kanemura, Shinya
Sakurai, Kodai
Sugiyama, Hiroaki
description We propose a model to explain the tiny masses of neutrinos with lepton number conservation, where neither too heavy particles beyond the TeV-scale nor tiny coupling constants are required. Assignments of conserving lepton numbers to new fields result in an unbroken Z2 symmetry that stabilizes the dark matter candidate (the lightest Z2-odd particle). In this model, Z2-odd particles play an important role in generating the masses of neutrinos. The scalar dark matter in our model can satisfy constraints on the dark matter abundance and those from direct searches. It is also shown that the strongly first-order phase transition, which is required for electroweak baryogenesis, can be realized in our model. In addition, the scalar potential can in principle contain CP-violating phases, which can also be utilized for baryogenesis. Therefore, three problems in the standard model-namely, the absence of neutrino masses, the dark matter candidate, and the mechanism to generate the baryon asymmetry of the Universe-may be simultaneously resolved at the TeV scale. The phenomenology of this model is also discussed briefly.
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subjects Asymmetry
Baryons
Constraint modelling
Cosmology
Dark matter
Electroweak model
Leptons
Neutrinos
Numbers
Phase transitions
Phenomenology
Standard model (particle physics)
Universe
title Neutrino mass without lepton number violation, dark matter; and a strongly first-order phase transition
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