Branching Ratios of H1,2,3 → μ+μ- in the Broken-Phase N2HDM

Abstract

Recent evidence from the ATLAS Collaboration for the rare decay H → μ+μ- provides a unique window into the Higgs boson's coupling to second-generation fermions. In this work, we investigate how this signal can probe physics beyond the Standard Model by computing the branching ratios B(Hi → μ+μ-) for the three CP-even Higgs bosons H1,2,3 in the broken-phase Next-to-Two-Higgs-Doublet Model (N2HDM). We incorporate one-loop radiative corrections and analyze deviations from the Standard Model prediction due to modified Yukawa couplings, scalar mixing, and singlet--doublet interactions. By confronting our results with the ATLAS signal strength μ = 1.4 0.4, we identify viable regions of the N2HDM parameter space, characterized by tanβ, the singlet vacuum expectation value, and scalar masses, and assess the model's capacity to explain potential enhancements in the dimuon channel. Our study demonstrates that precision measurements of H → μ+μ- serve as a powerful tool to test extended Higgs sectors and uncover new physics at current and future colliders.