What Does mu-tau Symmetry Imply about Neutrino Mixings?

Abstract

The requirement of the mu-tau symmetry in the neutrino sector that yields the maximal atmospheric neutrino mixing is shown to yield either sin(θ13)=0 (referred to as C1)) or sin(θ12)=0 (referred to as C2)), where θ12(13) stands for the solar (reactor) neutrino mixing angle. We study general properties possessed by approximately mu-tau symmetric textures. It is argued that the tiny mu-tau symmetry breaking generally leads to cos(2θ23) (θ13) for C1) and cos(2θ23) m2/ m2atm( R) for C2), which indicates that the smallness of cos(2θ23) is a good measure of the mu-tau symmetry breaking, where m2atm ( m2) stands for the square mass differences of atmospheric (solar) neutrinos. We further find that the relation R sin2(θ13) arises from contributions of O(sin2(θ13)) in the estimation of the neutrino masses (m1,2,3) for C1), and that possible forms of textures are strongly restricted to realize sin2(2θ12)=O(1) for C2). To satisfy R sin2(θ13) for C1), neutrinos exhibit the inverted mass hierarchy, or the quasi degenerate mass pattern with | m1,2,3| O( m2atm), and, to realize sin2(2θ12)=O(1) for C2), there should be an additional small parameter η whose size is comparable to that of the mu-tau symmetry breaking parameter ε, giving tan(2θ12) ε/η with η ε to be compatible with the observed large mixing.

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