From Qubits to Couplings: A Hybrid Quantum Machine Learning Framework for LHC Physics
Abstract
In this paper, we propose a new Hybrid Quantum Machine Learning (HyQML) framework to improve the sensitivity of double Higgs boson searches in the HH bbγγ final state at s = 13.6 TeV. The proposed model combines parameterized quantum circuits with a classical neural network meta-model, enabling event-level features to be embedded in a quantum feature space while maintaining the optimization stability of classical learning. The hybrid model outperforms both a state-of-the-art XGBoost model and a purely quantum implementation by a factor of two, achieving an expected 95% CL upper limit on the non-resonant double Higgs boson production cross-section of 1.9×σSM and 2.1×σSM under background normalization uncertainties of 10% and 50%, respectively. In addition, expected constraints on the Higgs boson self-coupling κλ and quartic vector-boson-Higgs coupling κ2V are found to be improved compared to the classical and purely quantum models.
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