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The effective neutrino mass of neutrinoless double-beta decays: how possible to fall into a well

Abstract

If massive neutrinos are the Majorana particles and have a normal mass ordering, the effective mass term mee\langle m\rangle^{}_{ee} of a neutrinoless double-beta (0ν2β0\nu 2\beta) decay may suffer significant cancellations among its three components and thus sink into a decline, resulting in a "well" in the three-dimensional graph of mee|\langle m\rangle^{}_{ee}| against the smallest neutrino mass m1m^{}_1 and the relevant Majorana phase ρ\rho. We present a new and complete analytical understanding of the fine issues inside such a well, and discover a novel threshold of mee|\langle m\rangle^{}_{ee}| in terms of the neutrino masses and flavor mixing angles: mee=m3sin2θ13|\langle m\rangle^{}_{ee}|^{}_* = m^{}_3 \sin^2\theta^{}_{13} in connection with tanθ12=m1/m2\tan\theta^{}_{12} = \sqrt{m^{}_1/m^{}_2} and ρ=π\rho =\pi. This threshold point, which links the {\it local} minimum and maximum of mee|\langle m\rangle^{}_{ee}|, can be used to signify observability or sensitivity of the future 0ν2β0\nu 2\beta-decay experiments. Given current neutrino oscillation data, the possibility of mee<mee|\langle m\rangle^{}_{ee}| < |\langle m\rangle^{}_{ee}|^{}_* is found to be very small.Comment: 9 pages, 3 figures, version to appear in Eur. Phys. J.

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