Mixing of Active and Sterile Neutrinos

Abstract

We investigate mixing of neutrinos in the (neutrino Minimal Standard Model), which is the MSM extended by three right-handed neutrinos. Especially, we study elements of the mixing matrix α I between three left-handed neutrinos α (α = e,μ,τ) and two sterile neutrinos NI (I=2,3) which are responsible to the seesaw mechanism generating the suppressed masses of active neutrinos as well as the generation of the baryon asymmetry of the universe (BAU). It is shown that eI can be suppressed by many orders of magnitude compared with μ I and τ I, when the Chooz angle θ13 is large in the normal hierarchy of active neutrino masses. We then discuss the neutrinoless double beta decay in this framework by taking into account the contributions not only from active neutrinos but also from all the three sterile neutrinos. It is shown that N2 and N3 give substantial, destructive contributions when their masses are smaller than a few 100 MeV, and as a results e I receive no stringent constraint from the current bounds on such decay. Finally, we discuss the impacts of the obtained results on the direct searches of N2,3 in meson decays for the case when N2,3 are lighter than pion mass. We show that there exists the allowed region for N2,3 with such small masses in the normal hierarchy case even if the current bound on the lifetimes of N2,3 from the big bang nucleosynthesis is imposed. It is also pointed out that the direct search by using π+ e+ + N2,3 and K+ e+ + N2,3 might miss such N2,3 since the branching ratios can be extremely small due to the cancellation in eI, but the search by K+ μ+ + N2,3 can cover the whole allowed region by improving the measurement of the branching ratio by a factor of 5.