Exploring enhanced non-resonant di-Higgs production at the HL-LHC with neural networks
Abstract
We investigate di-Higgs production in the bbγγ final state at the LHC, focusing on scenarios where the gluon fusion process is enhanced by new colored scalars, which could be identified as squarks or leptoquarks. We consider two benchmarks characterized by the mass of the lightest colored scalar, BML and BMH, corresponding to 464 GeV and 621 GeV, respectively. Using Monte Carlo simulations for both the signal and the dominant backgrounds, we perform a discovery analysis with deep neural networks, exploring various architectures and input variables. Our results show that the discrimination power is maximized by employing two dedicated classifiers, one trained against QCD backgrounds and another against backgrounds involving single-Higgs processes. Furthermore, we demonstrate that including high-level features -- such as the invariant masses mγγ, mbb, and mhh, as well as the transverse momenta and angular separations of the photon and b-jet pairs -- significantly improves the performance compared to using only low-level features as the invariant mass and momenta of the final particles. For the latter case, we find that architectures processing photon and b-jet variables separately can enhance the significance for BMH. Projecting for an integrated luminosity of 3 ab-1, we obtain a significance of 7.3 for BML, while it drops to 3.1 for BMH. In the particular case of BML, discovery level significance can be reached at 1.7 ab-1.
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