Abstract
Even though the Standard Model with a Higgs mass mH = 125GeV possesses no bulk phase transition, its thermodynamics still experiences a “soft point” at temperatures around T = 160GeV, with a deviation from ideal gas thermodynamics. Such a deviation may have an effect on precision computations of weakly interacting dark matter relic abundances if their mass is in the few TeV range, or on leptogenesis scenarios operating in this temperature range. By making use of results from lattice simulations based on a dimensionally reduced effective field theory, we estimate the relevant thermodynamic functions across the crossover. The results are tabulated in a numerical form permitting for their insertion as a background equation of state into cosmological particle production/decoupling codes. We find that Higgs dynamics induces a non-trivial “structure” visible e.g. in the heat capacity, but that in general the largest radiative corrections originate from QCD effects, reducing the energy density by a couple of percent from the free value even at T > 160GeV.
Highlights
▸ no electroweak phase transition within the SM ▸ ”soft point” at T ≈ 160 GeV ▸ imprint on non-equilibrium BSM physics
We want to estimate the equation of state around the electroweak crossover through perturbative 3-loop computations as well as using existing lattice data within a dimensionally reduced effective theory
Where subscript R refers to renormalized quantities, μis the renormalization scale parameter and ν is the Higgs mass parameter
Summary
▸ no electroweak phase transition within the SM ▸ ”soft point” at T ≈ 160 GeV ▸ imprint on non-equilibrium BSM physics. Manuel Meyer Standard Model thermodynamics across the electroweak crossover ▸ no electroweak phase transition within the SM
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