Improving heavy Dirac neutrino prospects at future hadron colliders using machine learning
Abstract
In this work, by using the machine learning methods, we study the sensitivities of heavy pseudo-Dirac neutrino N in the inverse seesaw at the high-energy hadron colliders. The production process for the signal is pp N 3 + ET miss, while the dominant background is p p W Z 3 + ET miss. We use either the Multi-Layer Perceptron or the Boosted Decision Tree with Gradient Boosting to analyse the kinematic observables and optimize the discrimination of background and signal events. It is found that the reconstructed Z boson mass and heavy neutrino mass from the charged leptons and missing transverse energy play crucial roles in separating the signal from backgrounds. The prospects of heavy-light neutrino mixing |V N|2 (with = e,\,μ) are estimated by using machine learning at the hadron colliders with s=14 TeV, 27 TeV, and 100 TeV, and it is found that |V N|2 can be improved up to O (10-6) for heavy neutrino mass mN = 100 GeV and O (10-4) for mN = 1 TeV.
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