Two Higgs doublet dynamics at the electroweak phase transition: a non-perturbative study

TL;DR

This study employs non-perturbative lattice simulations within a 3d effective field theory to analyze the MSSM electroweak phase transition with two Higgs doublets, revealing a stronger transition than perturbative predictions and implications for baryogenesis.

Contribution

It provides the first non-perturbative analysis of the MSSM electroweak phase transition with two Higgs doublets, including CP violation effects and phase boundary properties.

Findings

The phase transition is stronger than 2-loop perturbation theory predicts.

Electroweak baryogenesis remains viable for Higgs mass around 115 GeV.

Small mA values do not significantly weaken the transition with a light stop.

Abstract

Using a three-dimensional (3d) effective field theory and non-perturbative lattice simulations, we study the MSSM electroweak phase transition with two dynamical Higgs doublets. We first carry out a general analysis of spontaneous CP violation in 3d two Higgs doublet models, finding that this part of the parameter space is well separated from that corresponding to the physical MSSM. We then choose physical parameter values with explicit CP violation and a light right-handed stop, and determine the strength of the phase transition. We find a transition somewhat stronger than in 2-loop perturbation theory, leading to the conclusion that from the point of view of the non-equilibrium constraint, MSSM electroweak baryogenesis can be allowed even for a Higgs mass mH \approx 115 GeV. We also find that small values of the mass parameter mA (\lsim 120 GeV), which would relax the experimental constraint on mH, do not weaken the transition noticeably for a light enough stop. Finally we determine the properties of the phase boundary.