Dynamical Determination of the Cut-off Scale in Loop-Induced Neutrino Mass Models with Non-Invertible Symmetry
Abstract
We propose our framework as an effective field theory valid below the cut-off scale , in which we explain the tiny scale of neutrino masses by integrating a non-invertible symmetry with the dynamical determination of the cut-off scale. In our model, we introduce three families of SU(2)L quintet fermions (R) and a quartet scalar (φ4), both of which are charged under the Fibonacci fusion rule (FFR). A central feature of this construction is that the vacuum expectation value (VEV) v4 of φ4 is induced at the one-loop level via dynamical symmetry breaking. To resolve the inherent arbitrariness of the cut-off scale in loop-induced VEV models, we identify with the scale at which the SU(2)L gauge coupling g2 encounters the renormalization group evolution (RGE) of g2, naturally fixing the physical cut-off within the range of approximately 105 to 107 GeV. Quantitatively, this framework yields v4 0.07-0.1 GeV, which in turn leads to neutrino Yukawa couplings on the order of 10-3. This result provides a significantly more natural explanation for the neutrino mass hierarchy compared to standard seesaw models, which typically require couplings as small as 10-6 or less. Notably, our approach maintains a relatively simple particle content and does not necessitate additional (gauge) bosons for symmetry breaking.
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