Particle-level transformers for 95 GeV Higgs boson searches at future e+e- Higgs factories
Abstract
Motivated by several mild excesses around 95~GeV, we investigate the prospects for a light scalar S produced via Higgsstrahlung, e+e- Z(μ+μ-)S, at future e+e- Higgs factories. We take the CEPC as a benchmark, with a center-of-mass energy of s=240 GeV and an integrated luminosity of L=20~ab-1. We focus on the decay modes Sτ+τ- and S b b. To maximize sensitivity, we employ the particle-level transformer networks Particle Transformer (ParT) and its more-interactive variant MIParT, which exploit the features of all reconstructed objects and their correlations. For a representative signal benchmark, this approach improves the expected statistical precision on the signal strength by factors of 2.3 in the τ+τ- channel and 1.4 in the b b channel compared to a cut-based analysis. Within the flipped Next-to-Two-Higgs-Doublet Model (N2HDM-F), the CEPC can measure the signal strength with a statistical precision down to 1.0% in the τ+τ- channel and 0.69% in the b b channel using MIParT. It can achieve a 5σ discovery for μττZS>1.6×10-2 or μbbZS>5.0×10-3, and reach 1% precision for μττZS>0.93 or μbbZS>0.14. These gains are expected to qualitatively carry over to other future lepton colliders such as FCC-ee and the ILC. Our results demonstrate the potential of particle-level machine-learning techniques to strengthen light Higgs searches at future e+e- Higgs factories.
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