Measurement of Higgs-boson self-coupling with single-Higgs and double-Higgs production channels

Abstract

The trilinear self-coupling can be measured directly using the Higgs-boson-pair production cross section, or indirectly through the measurement of single-Higgs-boson production and decay modes. In fact, at next-to-leading order in electroweak interaction, the Higgs-decay partial widths and the cross sections of the main single-Higgs production processes depend on the Higgs-boson self-coupling via weak loops. Measurements of λ, i.e. the rescaling of the trilinear Higgs self-coupling, are presented in this dissertation. Results are obtained exploiting proton-proton collision data from the Large Hadron Collider at a centre-of-mass energy of 13 TeV recorded by the ATLAS detector in 2015, 2016 and 2017, corresponding to a luminosity of up to 79.8 fb-1. Constraints on the Higgs self-coupling are presented considering the most sensitive double-Higgs channels (HH), bbτ+τ-, bbγγ and bbbb, considering single-Higgs (H) production modes, ggF, VBF, ZH, WH and ttH, together with WW*, ZZ*, τ+τ-, γ γ and bb decay channels, and combining the aforementioned analyses (H+HH) to improve the sensitivity on λ. Under the assumption that new physics affects only the Higgs-boson self-coupling, the combined H+HH best-fit value of the coupling modifier is: λ = 4.6+3.2-3.8, excluding values outside the interval -2.3<λ<10.3 at 95% confidence level. Results with less stringent assumptions are also provided, decoupling the Higgs-boson self-coupling and the other Standard Model couplings. The final results of this thesis provide the most stringent constraint on λ from experimental measurements to date.