Higgs-curvature coupling and post-inflationary vacuum instability

Abstract

We study the post-inflationary dynamics of the Standard Model (SM) Higgs field in the presence of a non-minimal coupling ||2R to gravity, both with and without the electroweak gauge fields coupled to the Higgs. We assume a minimal scenario in which inflation and reheating are caused by chaotic inflation with a quadratic potential, and no additional new physics is relevant below the Planck scale. By using classical real-time lattice simulations with a renormalisation group improved effective Higgs potential and by demanding the stability of the Higgs vacuum after inflation, we obtain upper bounds for , taking into account the experimental uncertainty of the top-Yukawa coupling. We compare the bounds in the absence and presence of the electroweak gauge bosons, and conclude that the addition of gauge interactions has a rather minimal impact. In the unstable cases, we parametrize the time when such instability develops. For a top-quark mass mt ≈173.3 GeV, the Higgs vacuum instability is triggered for 4 -5, although a slightly lower mass of mt ≈ 172.1 GeV pushes up this limit to 11 - 12. This, together with the estimation 0.06 for stability during inflation, provides tight constraints to the Higgs-curvature coupling within the SM.