Abstract
We propose a next-to-minimal supersymmetric Standard Model (NMSSM) extended by an $\mathbb{A}_{4}\times \boldsymbol{Z}_{3}$ flavor symmetry and three right-handed neutrinos providing a detailed study of the neutrino sector and a solution to the domain wall problem. In this proposal, neutrino masses are generated through Type I seesaw mechanism while the mixing angles are described by the trimaximal mixing realized using the NMSSM singlet S and only two flavon fields. The phenomenology of neutrino parameters is studied for normal and inverted mass hierarchies. In particular, we numerically evaluated the observables related to neutrino masses and mixing, namely, $\sum m_{i}$, $m_{ee}$, $m_{\nu_{e}}$, and $\delta_{CP}$ where we find that the ranges of $m_{ee}$ and $m_{\nu_{e}}$ are accessible by current and future experiments while the obtained ranges of $\sum m_{i}$ and $\delta_{CP}$ lie within the current experimental data. Another attractive feature we discussed in this paper is the circumvention of the domain wall problem induced by the spontaneous breaking of the $\mathbb{A}_{4}\times \boldsymbol{Z}_{3}$ discrete symmetry. We first showed that the domain walls in the charged lepton sector occur at high energy scale leading to unproblematic domain walls, while in the neutrino sector they are inevitable. Then, to solve this problem, we reconsidered the well-known approach that relies on the explicit breaking of the discrete symmetry through the insertion of Planck-suppressed operators induced by supergravity. \keywords{Neutrino physics, Discrete flavor symmetry,Trimaximal mixing, Domain walls}
Highlights
Physics beyond the standard model (SM) of elementary particles has been widely explored after the experimental discovery of neutrino oscillations [1,2,3], and of the Higgs boson with a mass of about 125 GeV [4,5]
We find that these DWs are remarkably described by the Klein-four V4 ≅ Z2 × Z2 flavor subsymmetry group, and are formed around the inflationary scale; and present no danger from the cosmological view. (ii) the second breaking is given by Gf to a subgroup Z2 in the neutrino sector, it is generated by the vacuum expectation value (VEV) of Ω and S and creates domain walls that expand between the boundaries of degenerate vacua which are characterized by the Z2 ⋊ Z3 × Z3 subgroup of Gf
Motivated by the recent progress in describing neutrino masses and mixing consistent with current data by using non-Abelian discrete flavor symmetries as well as their possible implications in cosmology, we have explored in this paper the neutrino phenomenology in a flavored next-to-minimal supersymmetric Standard Model (NMSSM) based on the flavor symmetry Gf 1⁄4 A4 × Z3 and studied the domain wall problem related to the spontaneous breaking of Gf
Summary
Physics beyond the standard model (SM) of elementary particles has been widely explored after the experimental discovery of neutrino oscillations [1,2,3], and of the Higgs boson with a mass of about 125 GeV [4,5]. We use results on the perturbation of the scalar potential of the theory by higher dimensional operators suppressed by powers of the Planck scale MPl; and on the effective field action approach in the flavon sector of FNMSSM to propose a scenario preventing the domain wall problem created by the spontaneous breaking of the full flavor group Gf in FNMSSM. Two A4 breaking patterns are analysed: (i) the first one driven by an A4 triplet leads to the spontaneous breaking of Gf down to its subgroup Z3 × Z3 in the charged lepton sector, where the domain walls appear as the boundaries separating the degenerate vacua generated by this breaking We find that these DWs are remarkably described by the Klein-four V4 ≅ Z2 × Z2 flavor subsymmetry group, and are formed around the inflationary scale; and present no danger from the cosmological view. Appendix D, we describe the case where the breaking pattern in the neutrino sector is driven by the VEV of the NMSSM singlet S
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