Abstract
We propose a model based on the $SU(3)_{C}\otimes SU(3)_{L}\otimes U(1)_{X}$ gauge symmetry with an extra $S_{3}\otimes Z_{2}\otimes Z_{4}\otimes Z_{12}$ discrete group, which successfully accounts for the SM quark mass and mixing pattern. The observed hierarchy of the SM quark masses and quark mixing matrix elements arises from the $Z_{4}$ and $Z_{12}$ symmetries, which are broken at very high scale by the $SU(3)_{L}$ scalar singlets ($\sigma$,$\zeta$) and $\tau $, charged under these symmetries, respectively. The Cabbibo mixing arises from the down type quark sector whereas the up quark sector generates the remaining quark mixing angles. The obtained magnitudes of the CKM matrix elements, the CP violating phase and the Jarlskog invariant are in agreement with the experimental data.
Highlights
The discovery of a scalar field with a mass of 125 GeV by LHC experiments [1,2,3,4] confirms that the standard model (SM) is the right theory of electroweak interactions and may provide an explanation for the origin of mass of fundamental particles and for the spontaneous symmetry breaking
Considering that the quark mass and mixing pattern arises from the Z4 and Z12 symmetries, and in order to relate the quark masses with the quark mixing parameters, we set the vacuum expectation value (VEV) of the SU (3)L singlet scalar fields excepting vζ as follows: vξ = vτ = vσ = int = λ, (2.10)
In this paper we proposed a model based on the symmetry group SU (3)C ⊗ SU (3)L ⊗ U (1)X ⊗ S3 ⊗ Z2 ⊗ Z4 ⊗ Z12, which is an extension of the 331 model with β = − √1 of
Summary
The discovery of a scalar field with a mass of 125 GeV by LHC experiments [1,2,3,4] confirms that the standard model (SM) is the right theory of electroweak interactions and may provide an explanation for the origin of mass of fundamental particles and for the spontaneous symmetry breaking. Despite the success of the LHC experiments, there are many aspects not yet explained, such as the fermion mass hierarchy This discovery of the Higgs scalar field opens the possibility to formulate theories beyond the SM that include additional scalar fields that can be useful to explain the existence of dark matter [5,6,7,8]. Models based on the gauge symmetry SU (3)C × SU (3)L × U (1)X are very interesting since they predict the existence of three families from the quiral anomaly cancelation [92–97]. In these models, two families of quarks have the same quantum numbers, which are associated to the two families of light quarks to correctly predict the Cabbibo mixing angle.
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