Neutrino Masses with "Zero Sum" Condition: m_1 + m_2 + m_3 = 0
Abstract
It is well known that the neutrino mass matrix contains more parameters than experimentalists can hope to measure in the foreseeable future even if we impose CP invariance. Thus, various authors have proposed ansatzes to restrict the form of the neutrino mass matrix further. Here we propose that m_1 + m_2 + m_3 = 0; this ``zero sum'' condition can occur in certain class of models, such as models whose neutrino mass matrix can be expressed as commutator of two matrices. With this condition, the absolute neutrino mass can be obtained in terms of the mass-squared differences. When combined with the accumulated experimental data this condition predicts two types of mass hierarchies, with one of them characterized by m_3 ≈ -2m_1 ≈ -2 m_2 ≈ 0.063 eV, and the other by m_1 ≈ -m_2 ≈ 0.054 eV and m_3 ≈ 0.0064 eV. The mass ranges predicted is just below the cosmological upper bound of 0.23 eV from recent WMAP data and can be probed in the near future. We also point out some implications for direct laboratory measurement of neutrino masses, and the neutrino mass matrix.
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