On Holographic Vacuum Misalignment

TL;DR

This paper constructs a holographic model for a strongly coupled field theory with spontaneous symmetry breaking, capturing composite Higgs dynamics and vacuum misalignment, with implications for realistic model building.

Contribution

It develops a regular, bottom-up holographic model incorporating boundary terms to simulate external sector couplings and analyzes symmetry breaking and spectrum implications.

Findings

Holographic model exhibits SO(5)/SO(4) symmetry breaking with vacuum misalignment.

Spectrum calculations reveal the effects of symmetry breaking and Higgsing.

Model provides a framework for understanding composite Higgs mechanisms in holography.

Abstract

We develop a bottom-up holographic model that provides the dual description of a strongly coupled field theory, in which the spontaneous breaking of an approximate global symmetry yields the SO(5)/SO(4) coset relevant to minimal composite-Higgs models. The gravity background is completely regular and smooth, and has an end of space that mimics confinement on the field theory side. We add to the gravity description a set of localised boundary terms, that introduce additional symmetry-breaking effects, capturing those that would result from coupling the dual strongly coupled field theory to an external, weakly coupled sector. Such terms encapsulate the gauging of a subgroup of the global $SO(5)$ symmetry of the dual field theory, as well as additional explicit symmetry-breaking effects. We show how to combine spurions and gauge fixing and how to take the appropriate limits, so as to respect gauge principles and avoid violations of unitarity. The interplay of bulk and boundary-localised couplings leads to the breaking of the SO(5) symmetry to either its SO(4) or SO(3) subgroup, via vacuum misalignment. In field theory terms, the model describes the spontaneous breaking of a SO(4) gauge symmetry to its SO(3) subgroup. We expose the implications of the higgsing phenomenon by computing the spectrum of fluctuations of the model, which we interpret in four-dimensional field-theory terms, for a few interesting choices of parameters. We conclude by commenting on the additional steps needed to build a realistic composite Higgs model.