The quark–lepton complementarity is a possible fundamental symmetry between quarks and leptons. First proposed in 1990 by Foot and Lew, it assumes that leptons as well as quarks come in three "colors". Such theory may reproduce the Standard Model at low energies, and hence quark–lepton symmetry may be realized in nature.
Recent neutrino experiments confirm that the Pontecorvo–Maki–Nakagawa–Sakata matrixUPMNScontains large mixing angles. For example, atmospheric measurements of particle decay yield ≈ 45°, while solar experiments yield ≈ 34°. These results should be compared with which is small, and with the quark mixing angles in the Cabibbo–Kobayashi–Maskawa matrixUCKM. The disparity that nature indicates between quark and lepton mixing angles has been viewed in terms of a "quark–lepton complementarity" which can be expressed in the relations Possible consequences of QLC have been investigated in the literature and in particular a simplecorrespondence between the PMNS and CKM matrices have been proposed and analyzed in terms of a correlation matrix. The correlation matrix VM is simply defined as the product of the CKM and PMNS matrices: Unitarity implies:
Open questions
One may ask where do the large lepton mixings come from? Is this information implicit in the form of the matrix? This question has been widely investigated in the literature, but its answer is still open. Furthermore, in some Grand Unification Theories the direct QLC correlation between the CKM and the PMNS mixing matrix can be obtained. In this class of models, the matrix is determined by the heavy Majorananeutrino mass matrix. Despite the naive relations between the PMNS and CKM angles, a detailed analysis shows that the correlation matrix is phenomenologically compatible with a tribimaximal pattern, and only marginally with a bimaximal pattern. It is possible to include bimaximal forms of the correlation matrix in models with renormalization effects that are relevant, however, only in particular cases with and with quasi-degenerate neutrino masses.