Neutrino masses, δPMNS, and mββ in SO(10)
Abstract
We explore the leptonic sector of a recently proposed supersymmetric SO(10) model with supersymmetry breaking in the 3-10 TeV range. A new ingredient in this work is the requirement that the observed baryon asymmetry is explained via non-thermal leptogenesis, which can be realized in a large class of supersymmetric hybrid inflation models including SO(10). We provide estimates for the masses of the three Standard Model neutrinos (with the lightest mass m1≈ 5 meV) as well as the three right-handed neutrinos (M1≈ 109 GeV and M2,3≈ 1013 GeV). The best fit estimate for the leptonic CP violating parameter δPMNS≈ 235, and the value of the neutrinoless double beta decay mass parameter mββ≈ 0.18 meV. A numerical analysis broadens the predicted range for δPMNS (100-300), but leaves largely intact the predictions for the six (light and heavy) neutrino masses and mβ β. Our statistical analysis, which yields the likelihood-predicted ranges of the observables, is fully consistent with JUNO's newly released first measurement of reactor neutrino oscillations in the m212-2θ12 plane, with JUNO improving the precision by a factor of 1.6 relative to the combination of all previous measurements. The implementation of successful non-thermal leptogenesis allows us to provide estimates for the inflaton mass (m ≈ 7× 109 GeV) and the reheating temperature (TRH≈ 4× 106 GeV).
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