Predicting neutrino parameters from SO(3) family symmetry and quark-lepton unification

King, Stephen F.

doi:10.1088/1126-6708/2005/08/105

Cited by 236 publications

(227 citation statements)

References 57 publications

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“…The unification of quarks and leptons in terms of A4SU421 is depicted in figure 1. The model involves U(1) R , rather than SU(2) R , used in previous models [20], in order to allow diagonal charged lepton and down quark Yukawa matrices together with off-diagonal neutrino and up quark Yukawa matrices. Quark mixing then arises completely from the up quark Yukawa matrix, which is equal to the neutrino Yukawa up to Clebsch-Gordan coefficients.…”

Section: Jhep01(2014)119mentioning

confidence: 99%

“…ous forms of constrained sequential dominance (CSD) have been considered based on the atmospheric neutrino alignment (0, 1, 1) but with different forms of solar neutrino alignment: original CSD [25] involved a solar alignment (1, 1, −1) yielding tri-bimaximal (TB) mixing; CSD2 [26,27] involved a solar alignment (1, 2, 0) and hence a small reactor angle; CSD3 [13] involved solar alignment (1, 3, 1) with an acceptable reactor angle but maximal atmospheric mixing; CSD4 [12] with the tetra-alignment (1, 4, 2) adopted here predicts best fit lepton angles with a normal hierarchy. By unifying leptons with quarks, we show here for the first time that CSD4 can also successfully predict the Cabibbo angle.…”

Section: Jhep01(2014)119mentioning

confidence: 99%

“…In the Majorana sector the Z 5 allowed leading operators are diagonal and given by, 20) where ξ j are three singlets under both A 4 and the Pati-Salam group. The operators relevant for the heavy Majorana mass matrix M R , emerging from eq.…”

Section: The Majorana Sectormentioning

confidence: 99%

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A model of quark and lepton mixing

King

2014

J. High Energ. Phys.

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We propose a model of quark and lepton mixing based on the tetrahedral A 4 family symmetry with quark-lepton unification via the tetra-colour Pati-Salam gauge group SU(4) P S , together with SU(2) L × U(1) R . The "tetra-model" solves many of the flavour puzzles and remarkably gives ten predictions at leading order, including all six PMNS parameters. The Cabibbo angle is approximately given by θ C ≈ 1/4, due to the tetravacuum alignment (1, 4, 2), providing the Cabibbo connection between quark and lepton mixing. Higher order corrections are responsible for the smaller quark mixing angles and CP violation and provide corrections to the Cabibbo and lepton mixing angles and phases. The tetra-model involves an SO(10)-like pattern of Dirac and heavy right-handed neutrino masses, with the strong up-type quark mass hierarchy cancelling in the see-saw mechanism, leading to a normal hierarchy of neutrino masses with an atmospheric angle in the first octant, θ l 23 = 40 • ± 1 • , a solar angle θ l 12 = 34 • ± 1 • , a reactor angle θ l 13 = 9.0 • ± 0.5 • , depending on the ratio of neutrino masses m 2 /m 3 , and a Dirac CP violating oscillation phase δ l = 260 • ± 5 • .

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Section: Jhep01(2014)119mentioning

confidence: 99%

Section: Jhep01(2014)119mentioning

confidence: 99%

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A model of quark and lepton mixing

King

2014

J. High Energ. Phys.

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“…However sharp predictions for the reactor (and solar) angles can only result from applying constraints to the Dirac mass matrix of various types, an approach known as constrained sequential dominance (CSD) [24]. For example, keeping the first column of the Dirac mass matrix fixed (0, a, a) T , a class of CSDn models has emerged [18,[24][25][26][27][28][29] corresponding to the second column taking the form (b, nb, (n − 2)b) T , with a reactor angle approximately given by [30] θ 13 ∼ (n − 1)…”

Section: Jhep09(2016)023mentioning

confidence: 99%

“…where CSD1 [24] implies tri-bimaximal (TB) mixing with a zero reactor angle, CSD2 [25] has a reactor angle θ 13 ∼ √ 2 3 m 2 m 3 , which is too small, CSD3 [18] in eq. (1.1) predicts θ 13 ∼ 2 √ 2 3 m 2 m 3 which is in good agreement with the experimental value θ 13 ∼ 0.15 [1], and CSD4 [26][27][28] predicts θ 13 ∼ √ 2 m 2 m 3 , while higher values of n > 4 involve increasingly large values of the reactor angle which are disfavoured [29].…”

Section: Jhep09(2016)023mentioning

confidence: 99%

Littlest Seesaw model from S 4 × U(1)

King

Luhn

2016

J. High Energ. Phys.

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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.

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References

2014

Beyond the Standard Model of Elementary Particle Physics

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Predicting neutrino parameters from SO(3) family symmetry and quark-lepton unification

Cited by 236 publications

References 57 publications

A model of quark and lepton mixing

A model of quark and lepton mixing

Littlest Seesaw model from S 4 × U(1)

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