The linear-non-linear frontier for the Goldstone Higgs

TL;DR

This paper explores the transition from linear to non-linear effective theories in the Goldstone Higgs framework, analyzing operator coefficients and couplings, and proposing a universal parametrization for heavy fermion completions.

Contribution

It provides a detailed derivation of the low-energy effective Lagrangian for the minimal $SO(5)/SO(4)$ sigma model, including linear corrections and a universal parametrization for fermionic completions.

Findings

Higgs couplings to vectors and fermions are universal and proportional to symmetry breaking parameters.

Three independent effective bosonic operators emerge at first order in linear corrections.

A simple parametrization for heavy fermion ultraviolet completions is proposed.

Abstract

The minimal $SO(5)/SO(4)$ sigma model is used as a template for the ultraviolet completion of scenarios in which the Higgs particle is a low-energy remnant of some high-energy dynamics, enjoying a (pseudo) Nambu-Goldstone boson ancestry. Varying the $\sigma$ mass allows to sweep from the perturbative regime to the customary non-linear implementations. The low-energy benchmark effective non-linear Lagrangian for bosons and fermions is obtained, determining as well the operator coefficients including linear corrections. At first order in the latter, three effective bosonic operators emerge which are independent of the explicit soft breaking assumed. The Higgs couplings to vector bosons and fermions turn out to be quite universal: the linear corrections are proportional to the explicit symmetry breaking parameters. Furthermore, we define an effective Yukawa operator which allows a simple parametrization and comparison of different heavy fermion ultraviolet completions. In addition, one particular fermionic completion is explored in detail, obtaining the corresponding leading low-energy fermionic operators.