Electroweak Phase Transition in Two Higgs Doublet Models
Abstract
We reexamine the strength of the first order phase transition in the electroweak theory supplemented by an extra Higgs doublet. The finite-temperature effective potential, , is computed to one-loop order, including the summation of ring diagrams, to study the ratio of the Higgs field VEV to the critical temperature. We make a number of improvements over previous treatments, including a consistent treatment of Goldstone bosons in , an accurate analytic approximation to valid for any mass-to-temperature ratios, and use of the experimentally measured top quark mass. For two-Higgs doublet models, we identify a significant region of parameter space where is large enough for electroweak baryogenesis, and we argue that this identification should persist even at higher orders in perturbation theory. In the case of the minimal supersymmetric standard model, our results indicate that the extra Higgs bosons have little effect on the strength of the phase transition.
Cite
@article{arxiv.hep-ph/9609240,
title = {Electroweak Phase Transition in Two Higgs Doublet Models},
author = {James M. Cline and Pierre-Anthony Lemieux},
journal= {arXiv preprint arXiv:hep-ph/9609240},
year = {2009}
}
Comments
18 pp., 5 figures, uses epsf.tex. Corrected matching conditions for analytic approximation to thermal effective potential, eq. (10), and typos in eq. (5)