The Planck Scale from Top Condensation

TL;DR

This paper presents a model linking the Planck scale to electroweak scale via top condensation in a 5D warped background, predicting new particles accessible at the LHC.

Contribution

It introduces a 5D warped model with top condensation that naturally explains the hierarchy and predicts a heavy Higgs, a vector-like quark, and a light radion.

Findings

Predicts a 500 GeV heavy Higgs with SM-like properties.

Forecasts a vector-like quark with 1.6-2.9 TeV mass.

Suggests a light radion with a few GeV mass.

Abstract

We propose a scenario in which the Planck scale is dynamically linked to the electroweak scale induced by top condensation. The standard model field content, without the Higgs, is promoted to a 5D warped background. There is also an additional 5D fermion with the quantum numbers of the right-handed top. Localization of the zero-modes leads, at low energies, to a Nambu-Jona-Lasinio model that also stabilizes the radion field dynamically thus explaining the hierarchy between the Planck scale and v_EW = 174 GeV. The top mass arises dynamically from the electroweak breaking condensate. The other standard model fermion masses arise naturally from higher-dimension operators, and the fermion mass hierarchies and flavor structure can be explained from the localization of the zero-modes in the extra dimension. If any other contributions to the radion potential except those directly related with electroweak symmetry breaking are engineered to be suppressed, the KK scale is predicted to be about two orders of magnitude above the electroweak scale rendering the model easily consistent with electroweak precision data. The model predicts a heavy (composite) Higgs with a mass of about 500 GeV and standard-model-like properties, and a vector-like quark with non-negligible mixing with the top quark and mass in the 1.6 - 2.9 TeV range. Both can be within the reach of the LHC. It also predicts a radion with a mass of a few GeV that is very weakly coupled to standard model matter.