Exploring extended Higgs sectors by radiative corrections with future precision coupling measurements

TL;DR

This paper calculates one-loop radiative corrections to Higgs couplings in two Higgs doublet models to help distinguish different extended Higgs sectors using future high-precision measurements.

Contribution

It provides detailed one-loop corrected predictions for Higgs couplings in various two Higgs doublet models, aiding model discrimination with future collider data.

Findings

Patterns of coupling deviations differ among models.

Future colliders can extract model parameters from coupling measurements.

Radiative corrections are essential for accurate predictions.

Abstract

In non-minimal Higgs sectors, coupling constants of the discovered Higgs boson can deviate from the predictions in the Standard Model by effects of additional scalar bosons. The pattern of the deviations in various Higgs boson couplings largely depends on the structure of extended Higgs sectors. Therefore, we may be able to determine the true Higgs sector by fingerprinting the predictions on the Higgs boson couplings in each model with the future precision data. As the expected precision is extremely high, it is essentially important to evaluate the theory predictions as accurately as possible with radiative corrections in each model. We calculate a full set of one-loop corrections to the Higgs boson couplings in the two Higgs doublet models with a softly-broken $Z_2$ symmetry, where there are four types of Yukawa interactions. We discuss how to distinguish four types of the model by evaluating the pattern of the deviations in the Yukawa coupling constants and also the couplings with gauge bosons. In addition, we demonstrate how inner parameters in each type of the model can be extracted by the future precision measurements of these couplings at the high luminosity LHC and the International Linear Collider.