Proton decay and μ e+γ Connection in a Renormalizable SO(10) GUT for Neutrinos

Abstract

Supersymmetric SO(10) grand unified models with renormalizable Yukawa couplings involving 10, 126 and 120 Higgs fields have been shown to give a very economical theory for understanding quark-lepton flavor in a unified framework. In previous papers, we showed how nucleon decay can be suppressed in these models without invoking cancellation, by choice of Yukawa flavor texture within a type II seesaw framework for neutrinos that explains all mixings and masses including the recently observed "large" θ13. In this follow-up paper, we extend our earlier work to the case of type I seesaw and show that the recently measured "large" θ13 can be accommodated in this case while suppressing proton decay. We then point out that the two cases (type I and II) lead to different testable predictions for B(μ e+γ) and B(τ μ (e) +γ) as well as different flavor final states in nucleon decay. In particular, we find that for the type I seesaw case, B(τ μ +γ) can be observable while at the same time suppressing B(μ e+γ), whereas in the type II seesaw case, B(τ μ +γ) is always suppressed whereas B(μ e+γ) is observable.