Uncovering new Higgses in the LHC analyses of differential t t ¯ $$ t\overline{t} $$ cross sections

Uncovering new Higgses in the LHC analyses of differential t t ¯ $$ t\overline{t} $$ cross sections

Abstract Statistically significant tensions between the Standard Model (SM) predictions and the measured lepton distributions in differential top cross-sections emerged in LHC Run 1 data and became even more pronounced in Run 2 analyses. Due to the level of sophistication of the SM predictions and t...

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Bibliographic Details
Main Authors: Sumit Banik, Guglielmo Coloretti, Andreas Crivellin, Bruce Mellado
Format: Article
Language:English
Published: SpringerOpen 2025-01-01
Series:Journal of High Energy Physics
Subjects:
Multi-Higgs Models
Specific BSM Phenomenology
Online Access:https://doi.org/10.1007/JHEP01(2025)155
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Summary:Abstract Statistically significant tensions between the Standard Model (SM) predictions and the measured lepton distributions in differential top cross-sections emerged in LHC Run 1 data and became even more pronounced in Run 2 analyses. Due to the level of sophistication of the SM predictions and the performance of the ATLAS and CMS detectors, this is very remarkable. Therefore, one should seriously consider the possibility that these measurements are contaminated by beyond-the-SM contributions. In this article, we use the differential lepton distributions from the latest ATLAS t t ¯ $$ t\overline{t} $$ analysis to study a new physics benchmark model motivated by existing indications for new Higgses: a new scalar H is produced via gluon fusion and decays to S ′ (95 GeV) and S (152 GeV), which subsequently decay to b b ¯ $$ b\overline{b} $$ and WW, respectively. In this setup, the total 𝜒2 is reduced, compared to the SM, resulting in ∆χ 2 = 34 to ∆χ 2 = 158, corresponding to a significance of 5.8σ to 13σ, depending on the SM simulation used. Notably, allowing m S to vary, the combination of the distributions points towards m S ≈ 150 GeV, which is consistent with the existing γγ and WW signals, rendering a mismodelling of the SM unlikely. Averaging the results of the different SM predictions, σ(pp → H → SS ′) × Br(S → WW) × Br(S ′ → bb) ≈ 9pb is preferred. Assuming that S ′ is SM-like, the 95 GeV γγ excess can be explained if S decays dominantly to W bosons. That latter suggests that S is the neutral component of the SU(2) L triplet with hypercharge 0.
ISSN:1029-8479

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