Multi-step Strong First-Order Electroweak Phase Transitions in the Inverted Type-I 2HDM: Parameter Space, Gravitational Waves, and Collider Phenomenology

Abstract

We investigate the electroweak phase transition (EWPT) within the inverted Type-I two-Higgs-doublet model, where the observed 125\,GeV Higgs boson is identified as the heavier CP-even scalar H. Through a comprehensive parameter-space scan consistent with current theoretical and experimental constraints, we identify regions supporting strong first-order EWPTs (SFOEWPTs), including multi-step transitions. We find that two-step SFOEWPTs occur as frequently as one-step transitions, while three-step transitions can occur, albeit rarely. Crucially, the parameter spaces inducing one-step and two-step transitions are partially yet significantly separated: one-step transitions restrict the charged Higgs mass and β to mH∈[295,441]\,GeV and β∈[4.2,8.8], whereas two-step transitions allow mH∈[100,350]\,GeV and β∈[2.5,45.4]. Notably, negative values of (β-α) arise almost exclusively in one-step scenarios. We present the calculation of gravitational wave (GW) signal-to-noise ratios (SNRs) at LISA for multi-step EWPTs, finding that detectable GW signals (SNR>10) predominantly emerge from two-step transitions. Furthermore, we demonstrate that the correlation between the vacuum uplifting measure F0 and c persists in one-step transitions and breaks down in multi-step cases. Finally, we perform a dedicated collider analysis for representative SFOEWPT parameter points at the 1.5\,TeV CLIC, identifying e+ e- H+ H- W+ W- hh as a promising discovery channel. Enhanced hγγ branching ratios for negative (β-α) motivate two complementary golden final states, W+ W- bb τ+ τ- and W+ W- bbγγ, which demonstrate high discovery potential due to negligible Standard Model backgrounds.