Thermal leptogenesis in a model with mass varying neutrinos

A. Acker; A. Broncano; A. Ganguly; A. Pilaftsis; A. Pilaftsis; A.G. Cohen; A.G. Riess; A.S. Joshipura; A.S. Joshipura; C. Kolda; C.L. Bennett; D. Comelli; D. Comelli; D. Falcone; D.N. Spergel; E. Ma; F. Buccella; F.R. Klinkhamer; G. D’Ambrosio; G.C. Branco; G.C. Branco; G.F. Giudice; G.F. Giudice; G.R. Farrar; H.B. Nielsen; H.B. Nielsen; H.V. Klapdor-Kleingrothaus; J. Ellis; J. Faridani; J.A. Harvey; J.K. Webb; J.M. Cline; J.R. Ellis; J.R. Ellis; J.R. Ellis; J.R. Ellis; J.R. Ellis; K. Eguchi; K. Enqvist; L. Amendola; L. Amendola; L. Boubekeur; M. Bolz; M. Flanz; M. Flanz; M. Flanz; M. Fukugita; M. Gasperini; M. Hirsch; M. Kawasaki; M. Li; M. Li; M. Pietroni; M. Plümacher; M. Tegmark; M. Trodden; M.A. Luty; M.N. Rebelo; M.S. Berger; M.S. Berger; N.S. Manton; P. Adhya; P. Adhya; P. Gu; P. Langacker; Peihong Gu; Q.R. Ahmad; R. Allahverdi; R. Barbieri; R. Barbieri; R. Cyburt; R. Horvat; R. Horvat; R. Rangarajan; R.N. Mohapatra; R.N. Mohapatra; R.N. Mohapatra; S. Davidson; S. Pascoli; S. Pelmutter; S.F. King; S.M. Carroll; S.W. Allen; S.Y. Khlebnikov; T. Asaka; T. Barreiro; T. Endoh; T. Hambye; T. Hambye; T. Hambye; V.A. Kuzmin; V.A. Rubakov; V.A. Rubakov; W. Buchmüller; W. Buchmüller; W. Buchmüller; W. Buchmüller; W. Rodejohann; W. Rodejohann; Xiao-Jun Bi; Xinmin Zhang; Xiulian Wang; Y. Fukuda; Y. Fukuda; Y. Grossman

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Thermal leptogenesis in a model with mass varying neutrinos

Authors: A. Acker
A. Broncano
A. Ganguly
A. Pilaftsis
A. Pilaftsis
A.G. Cohen
A.G. Riess
A.S. Joshipura
A.S. Joshipura
C. Kolda
C.L. Bennett
D. Comelli
D. Comelli
D. Falcone
D.N. Spergel
E. Ma
F. Buccella
F.R. Klinkhamer
G. D’Ambrosio
G.C. Branco
G.C. Branco
G.F. Giudice
G.F. Giudice
G.R. Farrar
H.B. Nielsen
H.B. Nielsen
H.V. Klapdor-Kleingrothaus
J. Ellis
J. Faridani
J.A. Harvey
J.K. Webb
J.M. Cline
J.R. Ellis
J.R. Ellis
J.R. Ellis
J.R. Ellis
J.R. Ellis
K. Eguchi
K. Enqvist
L. Amendola
L. Amendola
L. Boubekeur
M. Bolz
M. Flanz
M. Flanz
M. Flanz
M. Fukugita
M. Gasperini
M. Hirsch
M. Kawasaki
M. Li
M. Li
M. Pietroni
M. Plümacher
M. Tegmark
M. Trodden
M.A. Luty
M.N. Rebelo
M.S. Berger
M.S. Berger
N.S. Manton
P. Adhya
P. Adhya
P. Gu
P. Langacker
Peihong Gu
Q.R. Ahmad
R. Allahverdi
R. Barbieri
R. Barbieri
R. Cyburt
R. Horvat
R. Horvat
R. Rangarajan
R.N. Mohapatra
R.N. Mohapatra
R.N. Mohapatra
S. Davidson
S. Pascoli
S. Pelmutter
S.F. King
S.M. Carroll
S.W. Allen
S.Y. Khlebnikov
T. Asaka
T. Barreiro
T. Endoh
T. Hambye
T. Hambye
T. Hambye
V.A. Kuzmin
V.A. Rubakov
V.A. Rubakov
W. Buchmüller
W. Buchmüller
W. Buchmüller
W. Buchmüller
W. Rodejohann
W. Rodejohann
Xiao-Jun Bi
Xinmin Zhang
Xiulian Wang
Y. Fukuda
Y. Fukuda
Y. Grossman
Publication date: 22 April 2004
Publisher: 'American Physical Society (APS)'
Doi

Abstract

In this paper we consider the possibility of neutrino mass varying during the evolution of the Universe and study its implications on leptogenesis. Specifically, we take the minimal seesaw model of neutrino masses and introduce a coupling between the right-handed neutrinos and the dark energy scalar field, the Quintessence. In our model, the right-handed neutrino masses change as the Quintessence scalar evolves. We then examine in detail the parameter space of this model allowed by the observed baryon number asymmetry. Our results show that it is possible to lower the reheating temperature in this scenario in comparison with the case that the neutrino masses are unchanged, which helps solve the gravitino problem. Furthermore, a degenerate neutrino mass patten with

m_i

larger than the upper limit given in the minimal leptogenesis scenario is permitted.Comment: 18 pages, 7 figures, version to appear in PR

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