Probing Heavy Charged Higgs Boson Using Multivariate Technique at Gamma-Gamma Collider

Abstract

The current study explores the production of charged Higgs particles through photon-photon collisions within the Two Higgs Doublet Model context, including one-loop-level scattering amplitude of Electroweak and QED radiation. The cross-section has been scanned for plane (mφ0, s) investigating the process of γγ → H+H-. Three particular numerical scenarios low-mH, non-alignment, and short-cascade are employed. Hence using h0 for low-mH0 and H0 for non-alignment and short-cascade scenario, the new experimental and theoretical constraints are applied.The decay channels for charged Higgs particles are examined in all the scenarios along with the analysis for cross-sections revealing that at low energy it is consistently higher for all scenarios. However as s increases, it reaches a peak value at 1~TeV for all benchmark scenarios. The branching ratio of the decay channels indicates that for non-alignment, the mode of decay W h0 takes control % when BR(H → W H0) decreases at larger values of mH0. and for short cascade the prominent decay mode remains tb, while in the low-mH the dominant decay channel is of W h0. In our research, we employ contemporary machine-learning methodologies to investigate the production of high-energy Higgs Bosons within a 3 TeV Gamma-Gamma collider. We have used multivariate approaches such as Boosted Decision Trees (BDT), LikelihoodD, and Multilayer Perceptron (MLP) to show the observability of heavy-charged Higgs Bosons versus the most significant Standard Model backgrounds. The purity of the signal efficiency and background rejection are measured for each cut value.