Non-perturbative determination of the sphaleron rate for first-order phase transitions

Abstract

In many extensions of the Standard Model electroweak phase transitions at high temperatures can be described in a minimal dimensionally reduced effective theory with SU(2) gauge field and fundamental Higgs scalar. In this effective theory, all thermodynamic information is governed by two dimensionless ratios x λ3/g23 and y m23/g43, where λ3, m23 and g3 are the effective thermal scalar self-interaction coupling, the thermal mass and the effective gauge-coupling, respectively. By using non-perturbative lattice simulations to determine the rate of sphaleron transitions in the entire (x,y)-plane corresponding to the Higgs phase, and by applying previous lattice results for the bubble nucleation, we find a condition x(Tc) 0.025 to guarantee preservation of the baryon asymmetry, which translates to v/Tc 2 φ φ /Tc 1.33 for the (gauge-invariant) discontinuity in Higgs condensate. This indicates that viability of the electroweak baryogenesis requires the phase transition to be slightly stronger than previously anticipated. Finally, we present a general template for analysing such viability in a wide class of beyond the Standard Model theories, in which new fields are heavy enough to be integrated out at high temperature.