A Model of Neutrino Mass Matrix With δ = -π/2 and θ₂₃ = π/4

Experimental data have provided stringent constraints on neutrino mixing parameters. In the standard parameterization the mixing angle $\theta_{23}$ is close to $\pi/4$. There are also evidences show that the CP violating phase is close to $-\pi/2$. We study neutrino mass matrix reconstructed using this information and find several interesting properties. We show that a theoretical model based on the $A_4$ symmetry naturally predicts $\delta = -\pi/2$ and $\theta_{23} = \pi/4$ when the Yukawa couplings and scalar vacuum expectation values are real reaching a $\mu-\tau$ exchange and CP conjugate symmetry limit. In this case CP violation solely comes from the complex group theoretical Clebsh-Gordan coefficients. The model also predicts $|V_{e2}|=1/\sqrt{3}$ consistent with data. With complex Yukawa couplings the values for $\delta$ and $\theta_{23}$ can be significantly deviate away from the symmetry values $-\pi/2$ and $\pi/4$, respectively. But $|V_{e2}|= 1/\sqrt{3}$ is not altered. This matrix is an excellent lowest order approximation for theoretical model buildings of neutrino mass matrix.