Precision Prediction for the Big-Bang Abundance of Primordial Helium

Abstract

Within the standard models of particle physics and cosmology we have calculated the big-bang prediction for the primordial abundance of to a theoretical uncertainty of less than 0.1 (δ YP < 0.0002), improving the current theoretical precision by a factor of 10. At this accuracy the uncertainty in the abundance is dominated by the experimental uncertainty in the neutron mean lifetime, τn = 885.4 2.0 sec. The following physical effects were included in the calculation: the zero and finite-temperature radiative, Coulomb and finite-nucleon-mass corrections to the weak rates; order-α quantum-electrodynamic correction to the plasma density, electron mass, and neutrino temperature; and incomplete neutrino decoupling. New results for the finite-temperature radiative correction and the QED plasma correction were used. In addition, we wrote a new and independent nucleosynthesis code designed to control numerical errors to be less than 0.1. Our predictions for the [4]He abundance are presented in the form of an accurate fitting formula. Summarizing our work in one number, YP(η = 5× 10-10) = 0.2462 0.0004 (expt) < 0.0002 (theory). Further, the baryon density inferred from the Burles-Tytler determination of the primordial D abundance, B h2 = 0.019 0.001, leads to the prediction: YP = 0.2464 0.0005 (D/H) < 0.0002 (theory) 0.0005 (expt). This ``prediction'' and an accurate measurement of the primeval abundance will allow an important consistency test of primordial nucleosynthesis.