Saving the fourth generation Higgs with radion mixing

TL;DR

This paper investigates Higgs-radion mixing in a warped extra dimensional model with a fourth fermion generation, analyzing how it can reconcile with LHC data and exploring the constrained parameter space.

Contribution

It introduces a detailed analysis of Higgs-radion mixing effects in the presence of a fourth generation, including decay modes and experimental constraints.

Findings

Current LHC data can be compatible with mixed Higgs-radion states.

The radion interaction scale must be around 1-1.3 TeV.

Mass configurations depend on the Higgs and radion masses.

Abstract

We study Higgs-radion mixing in a warped extra dimensional model with Standard Model fields in the bulk, and we include a fourth generation of chiral fermions. The main problem with the fourth generation is that, in the absence of Higgs-radion mixing, it produces a large enhancement in the Higgs production cross-section, now severely constrained by LHC data. We analyze the production and decay rates of the two physical states emerging from the mixing and confront them with present LHC data. We show that the current signals observed can be compatible with the presence of one, or both, of these Higgs-radion mixed states (the $\phi$ and the $h$), although with a severely restricted parameter space. In particular, the radion interaction scale must be quite low, Lambda_\phi ~ 1-1.3 TeV. If m_\phi ~ 125 GeV, the $h$ state must be heavier (m_h>320 GeV). If m_h ~ 125 GeV, the $\phi$ state must be quite light or close in mass (m_\phi ~ 120 GeV). We also present the modified decay branching ratios of the mixed Higgs-radion states, including flavor violating decays into fourth generation quarks and leptons. The windows of allowed parameter space obtained are very sensitive to the increased precision of upcoming LHC data. During the present year, a clear picture of this scenario will emerge, either confirming or further severely constraining this scenario.