Improved Search for Muon-Neutrino to Electron-Neutrino Oscillations in MINOS

Flavour symmetries of Froggatt-Nielsen type can naturally reconcile the large quark and charged lepton mass hierarchies and the small quark mixing angles with the observed small neutrino mass hierarchies and their large mixing angles. We point out that such a flavour structure, together with the measured neutrino mass squared differences and mixing angles, strongly constrains yet undetermined parameters of the neutrino sector. Treating unknown O(1) parameters as random variables, we obtain surprisingly accurate predictions for the smallest mixing angle, sin 2 2θ 13 = 0.07 +0.11 −0.05 , the smallest neutrino mass, m 1 = 2.2 +1.7 −1.4 × 10 −3 eV, and one Majorana phase, α 21 /π = 1.0 +0.2 −0.2 .

Section: Introductionsupporting

confidence: 70%

Section: Mass Hierarchymentioning

confidence: 99%

Predicting θ 13 and the neutrino mass scale from quark lepton mass hierarchies

Buchmüller

Domcke

Schmitz

2012

“…As long as tan β is rather small, the deviation would be tiny but the large tan β scenario may be also fascinating because of the discrepancy of (g − 2) µ . Furthermore, nonzero θ 13 is confirmed at the experiments [17][18][19][20][21][22], so it is important to discuss the contribution of the T -breaking terms to the PMNS matrix. In the next section, we investigate the mass mixing from the one-loop correction, and discuss the contribution to θ 13 and the flavor changing processes.…”

Section: Setting (δMmentioning

confidence: 99%

“…Especially, we could find so many models motivated by the large mixing in neutrino sector, because the experimental result may imply so-called Tri-Bi maximal mixing [5][6][7], which can be easily accommodated by the BSMs with non-Abelian discrete flavor symmetry such as A 4 [8][9][10][11][12], S 4 [13][14][15], and ∆ (27) [16] etc.. Recent result on the nonzero θ 13 [17][18][19][20][21][22] may require some small modifications in those models, but we could expect that so many kinds of flavor symmetric models can be still consistent with the experimental results [4,. Then, the next question in this approach to the flavor structure would be how to test the flavor symmetry in experiments.…”

Section: Jhep10(2015)042mentioning

confidence: 99%

Study of lepton flavor violation in flavor symmetric models for lepton sector

Kobayashi

Omura

Takayama

et al. 2015

Flavor symmetric model is one of the attractive Beyond Standard Models (BSMs) to reveal the flavor structure of the Standard Model (SM). A lot of efforts have been put into the model building and we find many kinds of flavor symmetries and setups are able to explain the observed fermion mass matrices. In this paper, we look for common predictions of physical observables among the ones in flavor symmetric models, and try to understand how to test flavor symmetry in experiments. Especially, we focus on the BSMs for leptons with extra Higgs SU(2) L doublets charged under flavor symmetry. In many flavor models for leptons, remnant symmetry is partially respected after the flavor symmetry breaking, and it controls well the Flavor Changing Neutral Currents (FCNCs) and suggests some crucial predictions against the flavor changing process, although the remnant symmetry is not respected in the full lagrangian. In fact, we see that τ − → e + µ − µ − (µ + e − e − ) and e + e − → τ + τ − (µ − µ + ) processes are the most important in the flavor models that the extra Higgs doublets belong to triplet representation of flavor symmetry. For instance, the stringent constraint from the µ → eγ process could be evaded according to the partial remnant symmetry. We also investigate the breaking effect of the remnant symmetry mediated by the Higgs scalars, and investigate the constraints from the flavor physics: the flavor violating τ and µ decays, the electric dipole moments, and the muon anomalous magnetic moment. We also discuss the correlation between FCNCs and nonzero θ 13 , and point out the physical observables in the charged lepton sector to test the BSMs for the neutrino mixing.

“…Even before the Daya Bay result, however, there have emerged direct evidence of large θ 13 from T2K [54], MINOS [55] and Double Chooz [56]. The accurate nonzero reactor angle θ 13 implies Tri-Bimaximal mixing pattern and else would be ruled out.…”

Section: Jhep06(2016)032mentioning

confidence: 99%

SUSY SU(5)×S 4 GUT flavor model for fermion masses and mixings with adjoint, large θ 13 PMNS

Zhao¹,

Zhang²

2016

Abstract:We propose an S 4 flavor model based on supersymmetric (SUSY) SU(5) GUT. The first and third generations of 10 dimensional representations in SU(5) are all assigned to be 1 1 of S 4 . The second generation of 10 is to be 1 2 of S 4 . Right-handed neutrinos of singlet 1 and three generations of5 are all assigned to be 3 1 of S 4 . The VEVs of two sets of flavon fields are allowed a moderate hierarchy, that is Φ ν ∼ λ c Φ e . Tri-Bimaximal (TBM) mixing can be produced at both leading order (LO) and next to next to leading order (NNLO) in neutrino sector. All the masses of up-type quarks are obtained at LO. We also get the bottom-tau unification m τ = m b and the popular Georgi-Jarlskog relation m µ = 3m s as well as a new mass relation m e = 8 27 m d in which the novel Clebsch-Gordan (CG) factor arises from the adjoint field H 24 . The GUT relation leads to a sizable mixing angle θ e 12 ∼ θ c and the correct quark mixing matrix V CKM can also be realised in the model. The resulting CKM-like mixing matrix of charged leptons modifies the vanishing θ ν 13 in TBM mixing to a large θ PMNS 13 θ c / √ 2, in excellent agreement with experimental results. A Dirac CP violation phase φ 12 ±π/2 is required to make the deviation from θ ν 12 small. We also present some phenomenological numerical results predicted by the model.