A model of quark and lepton mixing

Self Cite

We show how a minimal (littlest) seesaw model involving two right-handed neutrinos and a very constrained Dirac mass matrix, with one texture zero and two independent Dirac masses, may arise from S 4 ×U(1) symmetry in a semi-direct supersymmetric model. The resulting CSD3 form of neutrino mass matrix only depends on two real mass parameters plus one undetermined phase. We show how the phase may be fixed to be one of the cube roots of unity by extending the S 4 × U(1) symmetry to include a product of Z 3 factors together with a CP symmetry, which is spontaneously broken leaving a single residual Z 3 in the charged lepton sector and a residual Z 2 in the neutrino sector, with suppressed higher order corrections. With the phase chosen from the cube roots of unity to be −2π/3, the model predicts a normal neutrino mass hierarchy with m 1 = 0, reactor angle θ 13 = 8.7 • , solar angle θ 12 = 34 • , atmospheric angle θ 23 = 44 • , and CP violating oscillation phase δ CP = −93 • , depending on the fit of the model to the neutrino masses.

Section: Jhep09(2016)023supporting

confidence: 76%

Section: Jhep09(2016)023mentioning

confidence: 99%

Littlest Seesaw model from S 4 × U(1)

King

Luhn

2016

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“…Different choices of phase for η are theoretically possible, but the phenomenologically successful choice for the relative phase of the atmospheric and solar terms (the first and second terms in eq. (5.5)) is η = 2π/5, whereas for example η = −2π/5 leaves the mixing angles unchanged but reverses the sign of the CP phases [33][34][35]. The dependence on see-saw phases was fully discussed in [33].…”

Section: Jhep08(2014)130mentioning

confidence: 82%

“…With a diagonal right-handed Majorana mass matrix, Y ν leads to a successful prediction of the PMNS mixing parameters [34]. Also the Cabibbo angle is given by θ C ≈ 1/4 [35]. Thus eq.…”

Section: Yukawa Matricesmentioning

confidence: 97%

A to Z of Flavour with Pati-Salam

King

2014

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Abstract:We propose an elegant theory of flavour based on A 4 × Z 5 family symmetry with Pati-Salam unification which provides an excellent description of quark and lepton masses, mixing and CP violation. The A 4 symmetry unifies the left-handed families and its vacuum alignment determines the columns of Yukawa matrices. The Z 5 symmetry distinguishes the right-handed families and its breaking controls CP violation in both the quark and lepton sectors. The Pati-Salam symmetry relates the quark and lepton Yukawa matrices, with Y u = Y ν and Y d ∼ Y e . Using the see-saw mechanism with very hierarchical right-handed neutrinos and CSD4 vacuum alignment, the model predicts the entire PMNS mixing matrix and gives a Cabibbo angle θ C ≈ 1/4. In particular, for a discrete choice of Z 5 phases, it predicts maximal atmospheric mixing, θ l 23 = 45 • ± 0.5 • and leptonic CP violating phase δ l = 260 • ± 5 • . The reactor angle prediction is θ l 13 = 9 • ± 0.5 • , while the solar angle is 34 • θ l 12 31 • , for a lightest neutrino mass in the range 0 m 1 0.5 meV, corresponding to a normal neutrino mass hierarchy and a very small rate for neutrinoless double beta decay.

“…An approach to flavour (GUT) model building with diagonal Y e (and Y d ) has been discussed recently in [33,34]. We introduce flavon fields θ 1 , θ 2 , θ 3 and θ 4 that obtain a VEV and generate the hierarchical structure of the Yukawa matrices.…”

Section: A Model With Diagonalmentioning

confidence: 99%

Towards predictive flavour models in SUSY SU(5) GUTs with doublet-triplet splitting

Antusch

Varzielas

Maurer

et al. 2014

We discuss how the double missing partner mechanism solution to the doublettriplet splitting problem in four-dimensional supersymmetric SU(5) Grand Unified Theories (GUTs) can be combined with predictive models for the quark-lepton Yukawa coupling ratios at the GUT scale. It is argued that towards this goal a second SU(5) breaking Higgs field in the adjoint representation is very useful and we discuss all possible renormalizable superpotentials with two adjoint Higgs fields and calculate the constraints on the GUT scale and effective triplet mass from a two-loop gauge coupling unification analysis. Two explicit flavour models with different predictions for the GUT scale Yukawa sector are presented, including shaping symmetries and a renormalizable messenger sector. Towards calculating the rates for proton decay induced by the exchange of colour triplets, the required ClebschGordan coefficients for their couplings are calculated for the possible dimension five and six operators. They are provided in detailed tables in the appendix, together with additional helpful material for GUT flavour model building.