Muon (g-2) in U(1)Lμ-Lτ Scotogenic Model Extended with Vector like Fermion

Abstract

The latest results of anomalous muon magnetic moment at Fermilab show a discrepancy of 4.2 σ between the Standard Model (SM) prediction and experimental value. In this work, we revisit U(1)Lμ-Lτ symmetry with in the paradigm of scotogenic model which explains muon (g-2) and neutrino mass generation, simultaneously. The mass of new gauge boson MZμτ generated after the spontaneous symmetry breaking of U(1)Lμ-Lτ is constrained, solely, in light of the current neutrino oscillation data to explain muon (g-2). In particular, we have obtained two regions I and II, around 150 MeV and 500 MeV, respectively, in MZμτ-gμτ plane which explain the neutrino phenomenology. Region I is found to be consistent with muon neutrino trident (MNT) bound (gμτ ≤ 10-3) to explain muon (g-2), however, region II violates it for mass range MZμτ>300 MeV. We, then, extend the minimal gauged scotogenic model by a vector like lepton (VLL) triplet T. The mixing of T with inert scalar doublet η leads to chirally enhanced positive contribution to muon anomalous magnetic moment independent of Zμτ mass. Furthermore, we have, also, investigated the implication of the model for 0ββ decay and CP violation. The non-observation of 0ββ decay down to the sensitivity of 0.01 eV shall refute the model. The model, in general,is found to be consistent with both CP conserving and CP violating solutions.