Probing the Electroweak Phase Transition in the Flipped Two-Higgs-Doublet Model at the LHC

Abstract

We study the CP-conserving flipped (Type-Y) Two-Higgs-Doublet Model (2HDM) in the large-β regime (β>30), focusing on its implications for electroweak phase transitions (EWPTs) and LHC phenomenology. Viable parameter regions supporting a strong first-order EWPT fall into two heavy-Higgs hierarchies: (A) mH mH<mA and (B) mH<mH mA, both featuring a heaviest CP-odd Higgs A. Scenario~A typically proceeds via one-step transitions with lower nucleation temperatures, while Scenario~B allows one-step or two-step transitions, opening the decay A H W and yielding richer collider signatures. In all cases, nucleation conditions are satisfied, avoiding false-vacuum trapping. We assess LHC prospects through bottom-associated production with multi-b final states: pp bbH 4b and pp bbA bb W H 4bνν. The 4b channel offers high-statistics discovery potential, reaching signal significances z 25 at the 13 TeV LHC with 300 fb-1 and up to z 100 at the 14 TeV HL-LHC with 3 ab-1. The cascade channel, while experimentally more challenging, directly probes the heavy Higgs spectrum and can discriminate between EWPT scenarios. Using optimized selections with a BDT-based multivariate analysis, significances of z 6.8 can be achieved in favorable regions of Scenario~B at the HL-LHC. These results indicate that the HL-LHC can realistically probe the BSM Higgs sector responsible for a strong first-order EWPT and provide insight into the underlying phase transition dynamics in the flipped 2HDM.