Abstract

We study origin, consequences and testability of a hypothesis of `partial $\mu$-$\tau$' reflection symmetry. This symmetry predicts $ |U_{\mu i}|=|U_{\tau i}|~(i=1,2,3) $ for a single column of the leptonic mixing matrix $U$. Depending on whether this symmetry holds for the first or second column of $U$ different correlations between $\theta_{23}$ and $ \delta_{CP} $ can be obtained. This symmetry can be obtained using discrete flavour symmetries. In particular, all the subgroups of SU(3) with 3-dimensional irreducible representation which are classified as class C or D can lead to partial $\mu$-$\tau$ reflection symmetry. We show how the predictions of this symmetry compare with the allowed area in the $\sin^2\theta_{23} - \delta_{CP}$ plane as obtained from the global analysis of neutrino oscillation data. Furthermore, we study the possibility of testing these symmetries at the proposed DUNE and Hyper-Kamiokande (HK) experiments (T2HK, T2HKK), by incorporating the correlations between $\theta_{23}$ and $ \delta_{CP}$ predicted by the symmetries. We find that when simulated data of DUNE and HK is fitted with the symmetry predictions, the $\theta_{23}-\delta_{CP}$ parameter space gets largely restricted near the CP conserving values of $ \delta_{CP} $. Finally, we illustrate the capability of these experiments to distinguish between the two cases leading to partial $\mu-\tau$ symmetry namely $|U_{\mu1}| = |U_{\tau 1}|$ and $|U_{\mu 2}| = |U_{\tau 2}|$.

Highlights

  • Considerable theoretical and experimental efforts are being devoted towards predicting and determining the unknowns of the leptonic sectors, namely the charge parity (CP) violating phase, octant of the atmospheric mixing angle θ23 [i.e., θ23 < 45°, named as lower octant (LO) or θ23 > 45° named as upper octant (HO)], and the neutrino mass hierarchy [i.e., the sign of Δm231, Δm231 > 0 known as normal hierarchy (NH) and Δm231 < 0 known as inverted hierarchy (IH)]

  • We find that when the simulated data of Deep Under-ground Neutrino Experiment (DUNE) and HK are fitted with the symmetry predictions, the θ23 − δCP parameter space gets largely restricted near the charge parity conserving values of δCP

  • We study here partial μ-τ reflection symmetry of the leptonic mixing matrix, U, which can arise from discrete flavor symmetry

Read more

Summary

INTRODUCTION

Considerable theoretical and experimental efforts are being devoted towards predicting and determining the unknowns of the leptonic sectors, namely the charge parity (CP) violating phase, octant of the atmospheric mixing angle θ23 [i.e., θ23 < 45°, named as lower octant (LO) or θ23 > 45° named as upper octant (HO)], and the neutrino mass hierarchy [i.e., the sign of Δm231, Δm231 > 0 known as normal hierarchy (NH) and Δm231 < 0 known as inverted hierarchy (IH)]. We consider the testability of these relations at the forthcoming long baseline experiments of the Deep Under-ground Neutrino Experiment (DUNE) and HyperKamiokande (HK) These potential high-statistics experiments will overcome the parameter degeneracies faced by the current experiments and lead us in to an era of precision measurements of the oscillation parameters [41,42,43,44,45,46,47,48,49,50]. We use the extra correlations predicted by the symmetry in fitting the simulated data of these experiments, and we obtain the allowed areas in the δCP-sin2θ23 plane.

PARTIAL μ-τ REFLECTION SYMMETRY AND DISCRETE FLAVOR SYMMETRIES
EXPERIMENTAL SPECIFICATIONS
PHENOMENOLOGICAL ANALYSIS
Differentiating between the C1 and C2 symmetries
CONCLUSION

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.