Neutrino masses from an approximate mixing matrix with θ13≠ 0

Abstract

An approximate neutrino mixing matrix is formutated by using the standard neutrino mixing matrix as a basis and experimental data of neutrino oscillations as inputs. By using the resulted approximate neutrino mixing matrix to proceed the neutrino mass matrix and constraining the resulted neutrino mass matrix with zero texture: M(1,1)=M(1,3)=M(3,1)=0, we can have neutrino masses as function of mixing angle θ13 with normal hierarchy: m1<m2<m3. By taking the central value of mixing angle θ13=9o that gives ε=0.16 and using the squared mass difference: m322 for normal hierarchy, we then obtained neutrino masses: m1=0.00847 eV, m2=0.01215 eV, and m3=0.05062 eV which can predict the squared mass difference for solar neutrino precisely with the experimental result: m212=7.59× 10-5~ eV2