Low scale type i seesaw model for lepton masses and mixings

A. E.Cárcamo Hernández; Marcela González; Nicolás A. Neill

doi:10.1103/PhysRevD.101.035005

Low scale type i seesaw model for lepton masses and mixings

A. E.Cárcamo Hernández
, Marcela González
, Nicolás A. Neill

UTFSM

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

9 Citas (Scopus)

Resumen

In contrast to the original type I seesaw mechanism that requires right-handed Majorana neutrinos at energies much higher than the electroweak scale, the so-called low scale seesaw models allow lighter masses for the additional neutrinos. Here we propose an alternative low scale type I seesaw model, where neither linear nor inverse seesaw mechanisms take place, but the spontaneous breaking of a discrete symmetry at an energy scale much lower than the model cutoff is responsible for the smallness of the light active neutrino masses. In this scenario, the model is defined with minimal particle content, where the right-handed Majorana neutrinos can have masses at the ∼50 GeV scale. The model is predictive in the neutrino sector having only four effective parameters that allow to successfully reproduce the experimental values of the six low energy neutrino observables.

Idioma original	Inglés
Número de artículo	035005
Publicación	Physical Review D
Volumen	101
N.º	3
DOI	https://doi.org/10.1103/PhysRevD.101.035005
Estado	Publicada - 6 feb. 2020
Publicado de forma externa	Sí

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title = "Low scale type i seesaw model for lepton masses and mixings",

abstract = "In contrast to the original type I seesaw mechanism that requires right-handed Majorana neutrinos at energies much higher than the electroweak scale, the so-called low scale seesaw models allow lighter masses for the additional neutrinos. Here we propose an alternative low scale type I seesaw model, where neither linear nor inverse seesaw mechanisms take place, but the spontaneous breaking of a discrete symmetry at an energy scale much lower than the model cutoff is responsible for the smallness of the light active neutrino masses. In this scenario, the model is defined with minimal particle content, where the right-handed Majorana neutrinos can have masses at the ∼50 GeV scale. The model is predictive in the neutrino sector having only four effective parameters that allow to successfully reproduce the experimental values of the six low energy neutrino observables.",

author = "Hern{\'a}ndez, \{A. E.C{\'a}rcamo\} and Marcela Gonz{\'a}lez and Neill, \{Nicol{\'a}s A.\}",

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doi = "10.1103/PhysRevD.101.035005",

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AU - Hernández, A. E.Cárcamo

AU - González, Marcela

AU - Neill, Nicolás A.

PY - 2020/2/6

Y1 - 2020/2/6

N2 - In contrast to the original type I seesaw mechanism that requires right-handed Majorana neutrinos at energies much higher than the electroweak scale, the so-called low scale seesaw models allow lighter masses for the additional neutrinos. Here we propose an alternative low scale type I seesaw model, where neither linear nor inverse seesaw mechanisms take place, but the spontaneous breaking of a discrete symmetry at an energy scale much lower than the model cutoff is responsible for the smallness of the light active neutrino masses. In this scenario, the model is defined with minimal particle content, where the right-handed Majorana neutrinos can have masses at the ∼50 GeV scale. The model is predictive in the neutrino sector having only four effective parameters that allow to successfully reproduce the experimental values of the six low energy neutrino observables.

AB - In contrast to the original type I seesaw mechanism that requires right-handed Majorana neutrinos at energies much higher than the electroweak scale, the so-called low scale seesaw models allow lighter masses for the additional neutrinos. Here we propose an alternative low scale type I seesaw model, where neither linear nor inverse seesaw mechanisms take place, but the spontaneous breaking of a discrete symmetry at an energy scale much lower than the model cutoff is responsible for the smallness of the light active neutrino masses. In this scenario, the model is defined with minimal particle content, where the right-handed Majorana neutrinos can have masses at the ∼50 GeV scale. The model is predictive in the neutrino sector having only four effective parameters that allow to successfully reproduce the experimental values of the six low energy neutrino observables.

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Low scale type i seesaw model for lepton masses and mixings

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