Inverse Hierarchy Approach to Fermion Masses
Abstract
The first fermion family might play a special role in understanding the physics of flavour. This possibility is suggested by the observation that the up-down splitting within quark families increases with the family number: mu md, mc>ms, mt mb. We construct a model that realizes this feature of the spectrum in a natural way. The inter-family hierarchy is first generated by radiative phenomena in a sector of heavy isosinglet fermions and then transferred to quarks by means of a universal seesaw. A crucial role is played by left-right parity and up-down isotopic symmetry. No family symmetry is introduced. The model implies mu/md> 0.5 and the Cabibbo angle is forced to be md/ms. The top quark is naturally in the 100 GeV range, but not too heavy: mt< 150 GeV. Inspired by the mass matrices obtained in the model for quarks, we suggest an ansatz also including charged leptons. The differences between u-, d- and e-type fermions are simply parametrized by three complex coefficients u, d and e. Additional consistent predictions are obtained: ms=100-150 MeV and mu/md< 0.75.
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