Exploring the Null Results in the Direct Detection Experiments, (g-2) and Neutrino Mass in an Extended U(1)Lμ-Lτ Model Constrained through the Z+- Decays

Abstract

The Direct Detection~(DD) experiments are vital for probing the particle nature of Dark Matter~(DM). However, in the absence of a scattering event, DD searches result in stringent bounds on the corresponding parameter space. The paper has considered a U(1)Lμ-Lτ-extension of the Standard Model~(SM) and augmented the particle spectrum with SU(2)L-singlet vector-like leptons and scalars. A discrete Z2 symmetry stabilizes the lightest SM-singlet vector-like lepton as the viable DM candidate. In the proposed model, amplitude-level cancellation can be achieved for both DM-electron and DM-quark scatterings, leading to a trivial explanation for the continuous null results in the DD experiments. The framework can also induce one-loop corrections to the lepton anomalous magnetic moments and Z+- couplings. The experimental bounds on the Z+- decays are instrumental in constraining the model parameters. Particularly, using the Zτ+τ- decay, a stronger exclusion limit can be imposed on the U(1)Lμ-Lτ parameter space. Further, in the presence of three heavy right-handed neutrinos, transforming as Z2-even states, the model can explain all the neutrino mass and mixing constraints using the Type-I seesaw mechanism. Future experimental updates on the (g-2), Z+- decays and improved bounds on the U(1)Lμ-Lτ theory can be crucial to test the proposed model. Moreover, future DD experiments searching for a DM-muon scattering might be significant to probe the considered DM-SM interaction.