Conditions of general Z2 symmetry and TM1,2 mixing for the minimal type-I seesaw mechanism in an arbitrary basis

Abstract

In this paper, using a formula for the minimal type-I seesaw mechanism by LDLT (or generalized Cholesky) decomposition, conditions of general Z2-invariance for the neutrino mass matrix m is obtained in an arbitrary basis. The conditions are found to be (M22 ai+ - M12 bi+) \, ( M22 aj- - M12 bj-) = - M \, bi+ \, bj- for the Z2-symmetric and -antisymmetric part of a Yukawa matrix Yij (Y T Y )ij /2 (aj, bj) and the right-handed neutrino mass matrix Mij. In other words, the symmetric and antisymmetric part of bi must be proportional to those of the quantity ai ai - M12 M22 bi. They are equivalent to the condition that m is block diagonalized by eigenvectors of the generator T. These results are applied to three Z2 symmetries, the μ-τ symmetry, the TM1 mixing, and the magic symmetry which predicts the TM2 mixing. For the case of TM1,2, the symmetry conditions become M222 \, a1 TBM a2 TBM = - M \, b1 TBM b2 TBM and M222 \, a1,2 TBM a3 TBM = - M \, b1,2 TBM b3 TBM with components ai TBM and bi TBM in the TBM basis v1,2,3. In particular, for the TM2 mixing, the magic (anti-)symmetric Yukawa matrix with S2 Y = Y is phenomenologically excluded because it predicts m2=0 or m1, m3 = 0. In the case where Yukawa is not (anti-)symmetric, the mass singular values are displayed without a root sign.