Precision Primordial 4He Measurement with CMB Experiments

Abstract

Big bang nucleosynthesis (BBN) and the cosmic microwave background (CMB) are two major pillars of cosmology. Standard BBN accurately predicts the primordial light element abundances (4He, D, 3He and 7Li), depending on one parameter, the baryon density. Light element observations are used as a baryometers. The CMB anisotropies also contain information about the content of the universe which allows an important consistency check on the Big Bang model. In addition CMB observations now have sufficient accuracy to not only determine the total baryon density, but also resolve its principal constituents, H and 4He. We present a global analysis of all recent CMB data, with special emphasis on the concordance with BBN theory and light element observations. We find Bh2=0.025+0.0019-0.0026 and Yp=0.250+0.010-0.014 (fraction of baryon mass as 4He) using CMB data alone, in agreement with 4He abundance observations. With this concordance established we show that the inclusion of BBN theory priors significantly reduces the volume of parameter space. In this case, we find Bh2=0.0244+0.00137-0.00284 and Yp = 0.2493+0.0006-0.001. We also find that the inclusion of deuterium abundance observations reduces the Yp and Bh2 ranges by a factor of 2. Further light element observations and CMB anisotropy experiments will refine this concordance and sharpen BBN and the CMB as tools for precision cosmology.

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