Type-I 2HDM under the Higgs and Electroweak Precision Measurements

TL;DR

This paper investigates how future precision measurements at Z- and Higgs factories can constrain the parameter space of the Type-I Two-Higgs-doublet model, including heavy Higgs masses and mixing angles, through comprehensive loop-level analysis.

Contribution

It provides a detailed global fit of the Type-I 2HDM incorporating loop effects and non-degenerate masses, highlighting the potential of future colliders to tightly constrain model parameters.

Findings

Future measurements can significantly restrict the allowed parameter space.

Indirect limits on heavy Higgs masses complement direct collider searches.

Precision at Z-pole and Higgs factories are highly complementary in constraining the model.

Abstract

We explore the extent to which future precision measurements of the Standard Model (SM) observables at the proposed $Z$-factories and Higgs factories may have impacts on new physics beyond the Standard Model, as illustrated by studying the Type-I Two-Higgs-doublet model (Type-I 2HDM). We include the contributions from the heavy Higgs bosons at the tree-level and at the one-loop level in a full model-parameter space. While only small $\tan\beta$ region is strongly constrained at tree level, the large $\tan\beta$ region gets constrained at loop level due to $\tan\beta$ enhanced tri-Higgs couplings. We perform a multiple variable global fit with non-alignment and non-degenerate masses. We find that the allowed parameter ranges could be tightly constrained by the future Higgs precision measurements, especially for small and large values of $\tan\beta$. Indirect limits on the masses of heavy Higgs bosons can be obtained, which can be complementary to the direct searches of the heavy Higgs bosons at hadron colliders. We also find that the expected accuracies at the $Z$-pole and at a Higgs factory are quite complementary in constraining mass splittings of heavy Higgs bosons. The typical results are $|\cos(\beta-\alpha)| < 0.05, |\Delta m_\Phi | < 200\ {\rm GeV}$, and $\tan\beta \gtrsim 0.3$. The reaches from CEPC, FCCee and ILC are also compared, for both Higgs and $Z$-pole precision measurements. Comparing to the Type-II 2HDM, the 95\% C.L. allowed range of $\cos(\beta-\alpha)$ is larger, especially for large values of $\tan\beta$.