Collider probe of heavy additional Higgs bosons solving the muon \(g-2\)

We study the Large Hadron Collider (LHC) search potential of a \(\mathbb{Z}_4\)-based two Higgs doublet model which can simultaneously explain the muon \(g-2\) anomaly and the observed dark matter. The neutral scalars in the second Higgs doublet couple to \(\mu\) and \(\tau\) and largely contribute to the muon anomalous magnetic moment through the one-loop diagram involving \(\tau\) and scalars. An additional singlet scalar which is charged under the discrete symmetry can be a dark matter candidate. An upper limit on the scalar mass originates from the unitarity constraint, and the \(\mu\tau\) flavor violating nature of the scalars predicts non-standard signatures at the LHC. However, the previously proposed \(\mu^\pm\mu^\pm\tau^\mp\tau^\mp\) signal via the electroweak heavy neutral scalar pair production at the LHC loses sensitivity for increasing scalar mass. We revisit this model and investigate the LHC prospects for the single production of the \(\mu\tau\) flavor violating neutral scalar. It is shown that the single scalar process helps to extend the LHC reach for the 1 TeV mass regime of the scenario. The search potential at the high energy LHC is also discussed.