Resonant Multi-Scalar Production in the Generic Complex Singlet Model in the Multi-TeV Region

Abstract

We develop benchmarks for resonant di-scalar production in the generic complex singlet scalar extension of the Standard Model (SM), which contains two new scalars. These benchmarks maximize di-scalar resonant production: pp→ h2 → h1 h1/h1h3/h3h3, where h1 is the observed SM-like Higgs boson and h2,3 are new scalars. The decays h2→ h1h3 and h2→ h3h3 may be the only way to discover h3, leading to a discovery of two new scalars at once. Current LHC and projected future collider (HL-LHC, FCC-ee, ILC500) constraints are used to produce benchmarks at the HL-LHC for h2 masses between 250 GeV and 1 TeV and a future pp collider for h2 masses between 250 GeV and 12 TeV. We update the current LHC bounds on the singlet-Higgs boson mixing angle. As the mass of h2 increases, certain limiting behaviors of the maximum rates are uncovered due to theoretical constraints on the parameters. These limits, which can be derived analytically, are BR(h2→ h1h1)→ 0.25, BR(h2→ h3h3)→ 0.5, and BR(h2→ h1h3) → 0. It can also be shown that the maximum rates of pp→ h2→ h1h1/h3h3 approach the same value. Hence, all three h2→ hihj decays are promising discovery modes for h2 masses below O(1\, TeV), while above O(1\, TeV) the decays h2→ h1h1/h3h3 are more encouraging. Masses for h3 are chosen to produce a large range of signatures including multi-b, multi-vector boson, and multi-h1 production. The behavior of the maximum rates imply that in the multi-TeV region this model may be discovered in the Higgs quartet production mode before Higgs triple production is observed. The maximum di- and four Higgs production rates are similar in the multi-TeV range.