A translational flavor symmetry in the mass terms of Dirac and Majorana fermions

Abstract

Requiring the effective mass term for a category of fundamental Dirac or Majorana fermions of the same electric charge to be invariant under the translational transformations α L (R) α L (R) + nα z L(R) in the flavor space, where nα and z L(R) stand respectively for the flavor-dependent complex numbers and a constant spinor field anticommuting with the fermion fields, we show that nα can be identified as the elements Uα i in the i-th column of the unitary matrix U used to diagonalize the corresponding Hermitian or symmetric fermion mass matrix M, and mi = 0 holds accordingly. We find that the reverse is also true. Now that the mass spectra of charged leptons, up- and down-type quarks are all strongly hierarchical and current experimental data allow the lightest neutrino to be massless, we argue that the zero mass limit for the first-family fermions and the translational flavor symmetry behind it should be a natural starting point for building viable fermion mass models.