Search for Vector-Like Singlet Top (T) Quark in a Future Muon-Proton (μ p) Collider at s = 5.29, 6.48, and 9.16 TeV using Advanced Machine Learning Architectures

Abstract

In this work, we explore the discovery potential of Vector-Like Singlet Top quarks (T) at a future μ p collider with center-of-mass energies of 5.29, 6.48, and 9.16 TeV, providing a unique environment to probe beyond Standard Model limits. We analyze the T Wb decay mode in both fully hadronic (bjj) and leptonic (bl) final states, offering a multi-channel assessment of T-quark sensitivity across a mass range of 2 to 5 TeV. Our methodology employs multivariate classifiers such as Boosted Decision Trees (BDTs) and Multi-Layer Perceptrons (MLP) to optimize signal-to-background discrimination in complex final states. The results demonstrate that the 9.16 TeV benchmark acts as a definitive discovery machine; even with 100 fb-1 of data, the statistical significance exceeds 5σ up to 4 TeV masses. We identify a crossover effect where hadronic channels provide superior reach at intermediate masses due to higher branching ratios, while leptonic channels offer robustness at 5 TeV where purity limits detection. Incorporating a 20\% systematic uncertainty via Asimov significance (ZA), we quantify the transition from fluctuation-dominated to systematic-dominated regimes at high luminosities. At 3000 fb-1, regions with g* ∈ [0.20, 0.50] and mT up to 4 TeV are discoverable via the hadronic channel with MLP, and regions with g* ∈ [0.10, 0.50] and mT up to 5 TeV are accessible through the leptonic channel with BDT, highlighting the collider's potential to probe new physics beyond the Standard Model.