Addressing μ-bμ and proton lifetime problems and active neutrino masses in a U(1)-extended supergravity model

Abstract

We present a locally supersymmetric extension of the minimal supersymmetric Standard Model (MSSM) based on the gauge group SU(3)C× SU(2)L× U(1)Y× U(1) where, except for the supersymmetry breaking scale which is fixed to be 1011 GeV, we require that all non-Standard-Model parameters allowed by the local spacetime and gauge symmetries assume their natural values. The U(1) symmetry, which is spontaneously broken at the intermediate scale, serves to ( i) explain the weak scale magnitudes of μ and bμ terms, ( ii) ensure that dimension-3 and dimension-4 baryon-number-violating superpotential operators are forbidden, solving the proton-lifetime problem, ( iii) predict bilinear lepton number violation in the superpotential at just the right level to accommodate the observed mass and mixing pattern of active neutrinos (leading to a novel connection between the SUSY breaking scale and neutrino masses), while corresponding trilinear operators are strongly supppressed. The phenomenology is like that of the MSSM with bilinear R-parity violation, were the would-be lightest supersymmetric particle decays leptonically with a lifetime of 10-12-10-8 s. Theoretical consistency of our model requires the existence of multi-TeV, stable, colour-triplet, weak-isosinglet scalars or fermions, with either conventional or exotic electric charge which should be readily detectable if they are within the kinematic reach of a hadron collider. Null results of searches for heavy exotic isotopes implies that the re-heating temperature of our Universe must have been below their mass scale which, in turn, suggests that sphalerons play a key role for baryogensis. Finally, the dark matter cannot be the weakly interacting neutralino.