Signatures of Type-I Seesaw in Neutrino Oscillation Phenomenology

Abstract

We investigate the low-energy phenomenology of the Type-I seesaw mechanism within a 3+3 framework containing three active and three sterile neutrinos. Using the exact seesaw relation as a bridge between the high-scale sterile-sector parameters and the standard oscillation observables, we perform a comprehensive Monte Carlo scan of the 21-dimensional sterile parameter space, retaining only those configurations consistent with current neutrino oscillation data within 3σ. For the viable parameter points, we simulate the modified neutrino oscillation probabilities and event rates at the long-baseline experiments DUNE and NO, and the medium-baseline reactor experiment JUNO, quantifying their sensitivity to sterile neutrino effects across the eV--GeV mass range. We find that eV-scale sterile neutrinos produce pronounced spectral distortions, while heavier states decouple progressively from oscillation experiments. In parallel, we confront the seesaw predictions with complementary probes: cosmological bounds on Σ mi, the kinematic mass mβ from beta decay, the effective Majorana mass |mββ| from neutrinoless double beta decay (0ββ), and the charged-lepton-flavor-violating branching ratio BR(μ eγ). The combination of all constraints significantly narrows the allowed parameter space: the predicted sum of neutrino masses clusters at Σ mi 0.05--0.07~eV, within reach of next-generation cosmological surveys, and eV-scale sterile neutrinos are found to be under significant tension from the current MEG bound on μ eγ.

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