Second resonance of the Higgs field: motivations, experimental signals, unitarity constraints
M. Consoli, G. Rupp
Perturbative calculations predict that the Standard Model (SM) effective potential should have a new minimum, well beyond the Planck scale, much deeper than the electroweak vacuum. As it is not obvious that gravitational effects can get so strong to stabilize the potential, most authors have accepted the metastability scenario in a cosmological perspective. This perspective is needed to explain why the theory remains trapped into our electroweak vacuum, but requires to control the properties of matter in the extreme conditions of the early universe. Alternatively, one can consider the completely different idea of a non-perturbative effective potential which, as at the beginning of the SM, is restricted to the pure Φ4 sector yet consistent with the now existing analytical and numerical studies. In this approach, where the electroweak vacuum is the lowest-energy state, besides the resonance of mass mh=125 GeV defined by the quadratic shape of the potential at its minimum, the Higgs field should exhibit a second resonance with mass 690±10(stat)±20(sys) GeV associated with the zero-point energy determining the potential depth. Despite its large mass, this would couple to longitudinal Ws with the same typical strength as the low-mass state at 125 GeV and represent a relatively narrow resonance of width ΓH=30÷38 GeV, mainly produced at LHC by gluon-gluon fusion. So it is interesting that, in the LHC data, one can find various indications for a new resonance in the expected mass range with a non-negligible statistical significance. As this could become an important new discovery by just adding two missing samples of RUN2 data, we outline further refinements of the theoretical predictions that could be obtained by implementing unitarity constraints, in the presence of fermion and gauge fields, with coupled-channel calculations used for meson spectroscopy.