Towards unification of quark and lepton flavors in A4 modular invariance

Abstract

We study quark and lepton mass matrices in the A4 modular symmetry towards the unification of the quark and lepton flavors. We adopt modular forms of weights 2 and 6 for quarks and charged leptons, while we use modular forms of weight 4 for the neutrino mass matrix which is generated by the Weinberg operator. We obtain the successful quark mass matrices, in which the down-type quark mass matrix is constructed by modular forms of weight 2, but the up-type quark mass matrix is constructed by modular forms of weight 6. Two regions of τ are consistent with observed CKM matrix elements. The one is close to τ=i and the other is in the larger Im [τ]. On the other hand, lepton mass matrices work well only at nearby τ=i, which overlaps with the one of the quark sector, for the normal hierarchy of neutrino masses. In the common τ region for quarks and leptons, the predicted sum of neutrino masses is 87--120meV taking account of its cosmological bound. Since both the Dirac CP phase δCP and 2θ23 are correlated with the sum of neutrino masses, improving its cosmological bound provides crucial tests for our scheme as well as the precise measurement of 2θ23 and δCP. The effective neutrino mass of the 0ββ decay is mee=15--31\,meV. It is remarked that the modulus τ is fixed at nearby τ=i in the fundamental domain of SL(2,Z), which suggests the residual symmetry Z2 in the quark and lepton mass matrices. The inverted hierarchy of neutrino masses is excluded by the cosmological bound of the sum of neutrino masses.