Constraints on Inflaton Higgs Field Couplings

Abstract

According to the best-fit parameters of the Standard Model, the Higgs field's potential reaches a maximum at a field value h 1010-11 GeV and then turns over to negative values. During reheating after inflation, resonance between the inflaton and the Higgs can cause the Higgs to fluctuate past this maximum and run down the dangerous side of the potential if these fields couple too strongly. In this paper, we place constraints on the inflaton-Higgs couplings such that the probability of the Higgs entering the unstable regime during reheating is small. To do so, the equations of motion are approximately solved semi-analytically, then solved fully numerically. Next the growth in variance is used to determine the parameter space for and α, the coupling coefficients for inflaton-Higgs cubic and quartic interactions, respectively. We find the upper bounds of < 1.6 × 10-5 mφ 2.2 × 108 GeV and α < 10-8 to allow the Higgs to remain stable in most Hubble patches during reheating, and we also find the full two parameter joint constraints. We find a corresponding bound on the reheat temperature of Treh 9.2 × 109 GeV. Additionally, de Sitter temperature fluctuations during inflation put a lower bound on inflaton-Higgs coupling by providing an effective mass for the Higgs, pushing back its hilltop during inflation. These additional constraints provide a lower bound on α, while must also be non-zero for the inflaton to decay efficiently.