Fermion Masses and Mixings from Dihedral Flavor Symmetries with Preserved Subgroups

TL;DR

This paper systematically studies dihedral flavor symmetries with preserved subgroups, deriving mass matrix structures and linking group theory to fermion mixing angles, including the Cabibbo angle and lepton mixing patterns.

Contribution

It identifies five possible Dirac mass matrix structures under preserved subgroups and connects these to fermion mixing angles, providing a group-theoretic expression for |V_{us}| and models for lepton mixing.

Findings

Derived five mass matrix structures with preserved subgroups.

Expressed |V_{us}| in terms of group parameters, e.g., |cos(3π/7)|.

Models predict maximal atmospheric mixing and zero θ_{13} based on subgroup mismatches.

Abstract

We perform a systematic study of dihedral groups used as flavor symmetry. The key feature here is the fact that we do not allow the dihedral groups to be broken in an arbitrary way, but in all cases some (non-trivial) subgroup has to be preserved. In this way we arrive at only five possible (Dirac) mass matrix structures which can arise, if we require that the matrix has to have a non-vanishing determinant and that at least two of the three generations of left-handed (conjugate) fermions are placed into an irreducible two-dimensional representation of the flavor group. We show that there is no difference between the mass matrix structures for single- and double-valued dihedral groups. Furthermore, we comment on possible forms of Majorana mass matrices. As a first application we find a way to express the Cabibbo angle, i.e. the CKM matrix element |V_{us}|, in terms of group theory quantities only, the group index n, the representation index j and the index m_{u,d} of the different preserved subgroups in the up and down quark sector: |V_{us}|=|cos(pi(m_{u}-m_{d})j/n)| which is |cos(3 pi/7)| = 0.2225 for n=7, j=1, m_{u}=3 and m_{d}=0. We prove that two successful models which lead to maximal atmospheric mixing and vanishing theta_{13} in the lepton sector are based on the fact that the flavor symmetry is broken in the charged lepton, Dirac neutrino and Majorana neutrino sector down to different preserved subgroups whose mismatch results in the prediction of these mixing angles. This also demonstrates the power of preserved subgroups in connection with the prediction of mixing angles in the quark as well as in the lepton sector.