Predictions for fermion masses and mixing from a low energy SU(3) flavor symmetry model with a Light Sterile Neutrino

Abstract

I report low energy results on the study of fermion masses and mixing for quarks and leptons, including neutrinos within a SU(3) flavor symmetry model, where ordinary heavy fermions, top and bottom quarks and tau lepton become massive at tree level from Dirac See-saw mechanisms implemented by the introduction a new set of SU(2)L weak singlet vector-like fermions U,D,E,N, with N a sterile neutrino. Light fermions obtain masses from one loop radiative corrections mediated by the massive SU(3) gauge bosons. Recent results shows the existence of a low energy space parameter where this model is able to accommodate the known spectrum of quark masses and mixing in a 4× 4 non-unitary VCKM as well as the charged lepton masses. Motivated by the recent LSND and MiniBooNe short-baseline neutrino oscillation experiments we fit for the 3+1 scenario the neutrino squared mass differences m22 - m12≈ 7.6× 10-5\;eV2, m32 - m22≈ 2.43× 10-3 eV2 and m42 - m12≈ 0.29 eV2. The model predicts the D vector like quark mass in the range MD=(350 - 900)GeV and horizontal gauge boson masses of few TeV. These low energy predictions are within LHC possibilities. Furthermore, the above scenario enable us to suppress simultaneously the tree level F=2 processes for Ko-Ko and Do-Do meson mixing mediated by these extra horizontal gauge bosons within current experimental bounds.