Majorana Neutrino Masses from Neutrinoless Double-Beta Decays and Lepton-Number-Violating Meson Decays

Abstract

The Schechter-Valle theorem states that a positive observation of neutrinoless double-beta (0 β β) decays implies a finite Majorana mass term for neutrinos when any unlikely fine-tuning or cancellation is absent. In this note, we reexamine the quantitative impact of the Schechter-Valle theorem, and find that current experimental lower limits on the half-lives of 0 β β-decaying nuclei have placed a restrictive upper bound on the Majorana neutrino mass |δ mee| < 7.43 × 10-29~ eV radiatively generated at the four-loop level. Furthermore, we generalize this quantitative analysis of 0 β β decays to that of the lepton-number-violating (LNV) meson decays M- M^+ + -α + -β (for α, β = e or μ). Given the present upper limits on these rare LNV decays, we have derived the loop-induced Majorana neutrino masses |δ mee| < 9.7 × 10-18~ eV, |δ meμ| < 1.6 × 10-15~ eV and |δ mμ μ| < 1.0 × 10-12~ eV from K- π+ + e- + e-, K- π+ + e- + μ- and K- π+ + μ- + μ-, respectively. A partial list of radiative neutrino masses from the LNV decays of D, Ds and B mesons is also given.