Optimization of event selection in search for doubly-charged Higgs bosons at ATLAS using machine learning techniques
Date
2025
Authors
Scott, Adrienne
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Abstract
The analysis of proton-proton collision data recorded by ATLAS during Run 2 of the LHC identified an excess of data over the Standard Model prediction in both the W±Z and W±W± vector boson scattering processes. These excesses could be attributed to resonances of the singly-charged (H±) and doubly-charged (H±±) Higgs bosons, which are hypothesized by the Georgi-Machacek (GM) model. To investigate this excess and assess its compatibility with the GM model, a dedicated search is being performed for the H± and H±± bosons where they are produced by vector boson fusion and decay to W±Z and W±W± respectively. In this thesis, the selection of the H±± signal region is optimized by training a neural network to discriminate signal events from background events. The characteristics of the H±± events vary significantly with mass, which leads to undesired behaviour when training a single network for a large mass range. A number of strategies are devised to address this problem; the best solution is to modify the weighting of different simulated masses during training. The neural network is used to define a new W±W± signal region which has a greater sensitivity to the GM model compared to a cuts-based approach.
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Keywords
Particle physics, ATLAS, LHC