Determination of mass hierarchy with medium baseline reactor neutrino experiments

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.

Section: Jhep08(2014)130mentioning

confidence: 92%

A to Z of Flavour with Pati-Salam

King

2014

“…The "binary" predictions of a normal neutrino mass hierarchy and an atmospheric angle in the first octant will both be tested over the next few years by current and planned neutrino experiments such as SuperKamiokande, T2K, NOνA and PINGU [49][50][51][52]. The Daya Bay II reactor experiment, including the short baseline detectors [59,60], will also test the neutrino mass hierarchy and in addition measure the reactor and solar angle to high accuracy, enabling precision tests of the predictions θ l 13 = 9.0 • ±0.5 • and θ l 12 = 34 • ± 1 • . In the longer term, superbeam and neutrino factory proposals such as WBB and LENF [61] would measure the atmospheric mixing angle to high accuracy, confronting the prediction θ l 23 = 40 • ±1 • , and ultimately testing the prediction of the Dirac CP violating oscillation phase δ l = 260 • ± 5 • .…”

Section: Jhep01(2014)119mentioning

confidence: 99%

A model of quark and lepton mixing

King

2014

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 • .

“…Note that the result of this method, χ 2 min corresponds to the so-called "average experiment" [116] or "Asimov data set" [117]. The uncertainty from statistical fluctuation can be easily estimated to be ∆(χ 2 min ) ≈ 2 ∆(χ 2 min ) [118][119][120]. It not only applies to the case of discrete variables such as the neutrino mass hierarchy and the octant, but actually applies generally as long as the binned event number is large enough such that statistical fluctuation can be approximated by Gaussian distribution.…”

Section: χ 2 Functionmentioning

confidence: 99%

“…The first could be achieved with a medium baseline reactor experiment [8][9][10][11][12][13][14][15][16][17][18][19][20][21] and long baseline accelerator experiments [22][23][24][25][26][27][28][29][30][31][32][33][34][35][36][37]44] could measure all three of them. Atmospheric neutrino experiments could offer alternative ways to accomplish the same.…”

Section: Introductionmentioning

confidence: 99%

A novel approach to study atmospheric neutrino oscillation

Hagiwara

Rott

2014

Self Cite

We develop a general theoretical framework to analytically disentangle the contributions of the neutrino mass hierarchy, the atmospheric mixing angle, and the CP phase, in neutrino oscillations. To illustrate the usefulness of this framework, especially that it can serve as a complementary tool to neutrino oscillogram in the study of atmospheric neutrino oscillations, we take PINGU as an example and compute muon-and electron-like event rates with event cuts on neutrino energy and zenith angle. Under the assumption of exact measurement of neutrino momentum with a perfect e-µ identification and no background, we find that the PINGU experiment has the potential of resolving the neutrino mass hierarchy and the octant degeneracies within 1-year run, while the measurement of the CP phase is significantly more challenging. Our observation merits a serious study of the detector capability of estimating the neutrino momentum for both muon-and electron-like events.