Towards a precision calculation of the effective number of neutrinos N eff in the Standard Model I: The QED equation of state

Abstract

We revisit several aspects of Standard Model physics at finite temperature that drive the theoretical value of the cosmological parameter N eff, the effective number of neutrinos in the early universe, away from 3. Our chief focus is finite-temperature corrections to the equation of state of the QED plasma in the vicinity of neutrino decoupling at T 1 MeV, where T is the photon temperature. Working in the instantaneous decoupling approximation, we recover at O(e2), where e is the elementary electric charge, the well-established correction of δ N eff(2) 0.010 across a range of plausible neutrino decoupling temperatures, in contrast to an erroneous claim in the recent literature which found twice as large an effect. At O(e3) we find a new and significant correction of δ N eff(3) -0.001 that has so far not been accounted for in any precision calculation of N eff, significant because this correction is potentially larger than the change in N eff induced between including and excluding neutrino oscillations in the transport modelling. In addition to the QED equation of state, we make a first pass at quantifying finite-temperature QED corrections to the weak interaction rates that directly affect the neutrino decoupling process, and find that the O(e2) thermal electron mass correction induces a change of δ N effm th 10-4. A complete assessment of the various effects considered in this work on the final value of N eff will necessitate an account of neutrino energy transport beyond the instantaneous decoupling approximation. However, relative to N eff = 3.044 obtained in the most recent such calculation, we expect the new effects found in this work to lower the number to N eff = 3.043.