A Type-I Seesaw Framework with Non-Holomorphic Modular Symmetry

Abstract

We study neutrino mass generation within the framework of non-holomorphic modular symmetry proposed by Qu and Ding. In this formalism, neutrino masses are generated via the Type-I seesaw mechanism, where the Yukawa couplings depend on non-holomorphic modular forms. The viability of the model is examined through a 2 analysis using current neutrino oscillation data. The 2min value is found to be 7.06 for normal hierarchy(NH). All neutrino oscillation parameters are consistent within their 1σ allowed ranges, except the atmospheric mixing angle 2θ23, which is predicted to lie in the second octant. The Dirac CP-violating phase(δCP) is constrained to the first and fourth quadrants, indicating relatively weak CP violation. These predictions can be tested in future long-baseline neutrino oscillation experiments. The sum of neutrino masses is compatible with the stringent bound proposed by the DESI experiment. However, the inverted hierarchy(IH) is not viable in this model, as the predicted value of 2min exceeds 100, and the mixing angles 2θ12 and 2θ23 lie outside the 3 σ allowed ranges.