Higgs phenomenology in the Stealth Doublet Model

Abstract

We analyze a model for the Higgs sector with two scalar doublets and a Z2 symmetry that is manifest in the Yukawa sector but broken in the potential. Thus, one of the doublets breaks the electroweak symmetry and has tree-level Yukawa couplings to fermions, whereas the other doublet has no vacuum expectation value and no tree-level couplings to fermions. Since the Z2 parity is broken the two doublets can mix, which leads to a distinct and novel phenomenology. This Stealth Doublet Model can be seen as a generalization of the Inert Doublet Model with a broken Z2 symmetry. We outline the model and present constraints from theory, electroweak precision tests and collider searches, including the recent observation of a Higgs boson at the LHC. The charged scalar H and the CP-odd scalar A couple to fermions at one-loop level. We compute the decays of H and A and in particular the one-loop decays A f f, H f f , H W Z and H W γ. We also describe how to calculate and renormalize such processes in our model. We find that if one of H or A is the lightest scalar, H W γ or A b b are typically their respective dominating decay channels. Otherwise, the dominating decays of H and A are into a scalar and a vector. Due to the absence of tree-level fermion couplings for H and A, we consider pair production and associated production with vector bosons and scalars at the LHC. If the parameter space of the model that favors H W γ is realized in Nature, we estimate that there could be a considerable amount of such events in the present LHC data.