Fingerprinting non-minimal Higgs sectors

TL;DR

This paper explores how future collider experiments can distinguish non-minimal Higgs sectors by analyzing deviations in Higgs boson couplings, combining direct searches for additional Higgs bosons with precision measurements.

Contribution

It provides a comprehensive framework for fingerprinting extended Higgs sectors through coupling deviation patterns, even without direct detection of extra Higgs particles.

Findings

Expected exclusion regions for additional Higgs boson masses at the LHC.

Patterns of Yukawa coupling deviations can discriminate between different models.

Precision measurements can identify non-minimal Higgs sectors without direct discovery.

Abstract

After the discovery of the standard-model-like Higgs boson at the LHC, the structure of the Higgs sector remains unknown. We discuss how it can be determined by the combination of direct and indirect searches for additional Higgs bosons at future collider experiments. First of all, we evaluate expected excluded regions for the mass of additional neutral Higgs bosons from direct searches at the LHC with the 14 TeV collision energy in the two Higgs doublet models with a softly-broken $Z_2$ symmetry. Second, precision measurements of the Higgs boson couplings at future experiments can be used for the indirect search of extended Higgs sectors if measured coupling constant with the gauge boson slightly deviates from the standard model value. In particular, in the two Higgs doublet model with the softly-broken discrete symmetry, there are four types of Yukawa interactions, so that they can be discriminated by measuring the pattern of deviations in Yukawa coupling constants. Furthermore, we can fingerprint various extended Higgs sectors with future precision data by detecting the pattern of deviations in the coupling constants of the standard-model-like Higgs boson. We demonstrate how the pattern of deviations can be different among various Higgs sectors which predict the electroweak rho parameter to be unity; such as models with additional an isospin singlet, a doublet, triplets or a septet. We conclude that as long as the gauge coupling constant of the Higgs boson slightly differs from the standard model prediction but is enough to be detected at the LHC and its high-luminosity run or at the International Linear Collider, we can identify the non-minimal Higgs sector even without direct discovery of additional Higgs bosons at the LHC.