Deep Neural Networks for Heavy Lepton-Flavor-Violating Higgs Searches at the LHC

Abstract

We study lepton-flavor-violating (LFV) decays of a heavy Higgs boson, H μτ, in the Type-III two-Higgs-doublet model by recasting the CMS search at s = 13 TeV with 35.9 fb-1 using fast detector simulation in the mass range 200-450 GeV. We develop a deep neural network (DNN) classifier trained on final-state kinematic variables that, with mass-dependent threshold optimization, reduces the expected 95% CL upper limits on the signal cross section by 42-46% in the 0-jet channel and 36-40% in the 1-jet channel relative to the standard collinear mass (Mcol) baseline. We apply SHAP interpretability analysis to identify the visible mass mvis as one of the dominant discriminating feature, reflecting the characteristic neutrino momentum fraction of the τ decay. We show that supplementing the Mcol analysis with a simplified mass-dependent pre-selection, mvis < f · mH with f = 0.7 (0-jet) and f = 0.8 (1-jet), consistently improves the sensitivity over the Mcol-only baseline without requiring multivariate infrastructure. In addition, a DNN regression model trained to predict the ratio mH/Mcol corrects the systematic prediction bias inherent in the collinear approximation, maintaining an absolute mass prediction error below 1 GeV for signals up to 400 GeV and improving the mass resolution by 12% (0-jet) and 21% (1-jet) at mH = 450 GeV. These results demonstrate a clear path toward significantly enhanced sensitivity in LFV Higgs searches at the LHC.