Phenomenology of the Neutrino-Mass-Giving Higgs Triplet and the Low-Energy Seesaw Violation of Lepton Number

Abstract

Small realistic Majorana neutrino masses can be generated via a Higgs triplet (++, +, 0) without having energy scales larger than M*= O(1) TeV in the theory. The large effective mass scale in the well-known seesaw neutrino-mass operator -1 (LL) is naturally obtained with M*2/μ, where μ is a small scale of lepton-number violation. In theories with large extra dimensions, the smallness of μ is naturally obtained by the mechanism of ``shining'' if the number of extra dimensions n 3. We study here the Higgs phenomenology of this model, where the spontaneous violation of lepton number is treated as an external source from extra dimensions. The observable decays ++ li+lj+ will determine directly the magnitudes of the \ij\ elements of the neutrino mass matrix. The decays + W+ J0 and 0 Z J0, where J0 is the massless Goldstone boson (Majoron), are also possible, but of special importance is the decay 0 J0 J0 which provides stringent constraints on the allowed parameter space of this model. Based on the current neutrino data, we also predict observable rates of μ-e conversion in nuclei.

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