Probing the Scalar Sector: Discovery Reach for Heavy Higgs Pairs at a s = 6 TeV Muon Collider in the 2HDM Alignment Limit

Abstract

This study provides a comprehensive phenomenological investigation into the discovery potential of heavy Higgs boson pairs (HH, HA, AA, H+H-) at a s=6~TeV Muon Collider. Utilizing the Two-Higgs-Doublet Model (2HDM) Type-I within the alignment limit ((β-α) ≈ 1), we evaluate two primary benchmarks with degenerate scalar masses of 1000~GeV (BP1) and 2000~GeV (BP2). Theoretical calculations performed reveal that Type-I branching fractions to third-generation fermions remain uniquely independent of β, providing a stable signal across the investigated parameter space. We demonstrate that the Muon Collider environment allows for the precise identification of high-multiplicity hadronic final states. A key finding of this research is that the signal processes yield distinctive topological signatures: an 8-jet state (4j+4b) for charged pairs and a highly complex 12-jet state (8j+4b) for neutral pairs (HA/AA). These signatures, combined with hard transverse momentum distributions and central pseudorapidity (|η| 3), allow for nearly absolute suppression of Standard Model backgrounds like tt, W+W-Z, and ZZZ. At an integrated luminosity of 10~ab-1, we report a staggering statistical significance of 104,000 for the H+H- channel and 3343 for the HA channel in the BP1 scenario. Furthermore, total selection efficiencies were found to increase from approximately 20\% at BP1 to 47\% at BP2, suggesting that the decay products of heavier scalars are kinematically easier to resolve. We conclude that a 6~TeV Muon Collider offers an unparalleled discovery reach for the extended scalar sector, providing a definitive facility for probing physics beyond the Standard Model.