Anatomy of the Real Higgs Triplet Model
Abstract
In this article, we examine the Standard Model extended by a Y=0 real Higgs triplet, the . It contains a CP-even neutral Higgs (0) and two charged Higgs bosons (), which are quasi-degenerate in mass. We first study the theoretical constraints from vacuum stability and perturbative unitarity and then calculate the Higgs decays, including the loop-induced modes such as di-photons (γγ) and Zγ. In the limit of a small mixing between the SM Higgs and 0, the latter decays dominantly to WW and can have a sizable branching ratio to di-photon. The model predicts a positive definite shift in the W mass, which agrees with the current global electroweak fit. At the Large Hadron Collider, it leads to a (i) stau-like signature from pp +- τ+τ-, (ii) multi-lepton final states from pp γ* +- W+W-ZZ and pp W* ^0 W Z W+W- as well as (iii) associated di-photon production from pp W* (0γγ). Concerning (i), the reinterpretation of the recent supersymmetric tau partner search by ATLAS and CMS excludes m<110 GeV at 95% CL. From (ii), some of the signal regions of multi-lepton searches lead to bounds close to the predicted cross-section, but electroweak scale masses are still allowed. For (iii), the recast of the associated di-photon searches by ATLAS and a combined log-likelihood fit of signal and background to data find that out of the 25 signal regions, 10 provide relevant limits on Br(0γγ) at the per cent level. Interestingly, 6 signal regions show excesses at around 152 GeV, leading to a preference for a non-zero di-photon branching ratio of about 0.7% with the corresponding significance amounting to about 4σ.
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