The Cosmic Baryon Fraction and the Extragalactic Ionizing Background

Abstract

We reassess constraints on the cosmological baryon density from observations of the mean decrement and power spectrum of the Lyman-alpha forest, taking into account uncertainties in all free parameters in the simplest gravitational instability model. The uncertainty is dominated by that of the photoionizing background, but incomplete knowledge of the thermal state of the intergalactic medium also contributes significantly to the error-budget. While current estimates of the baryon fraction from the forest do prefer values that are somewhat higher than the big bang nucleosynthesis value of \Omega_b h^2 = 0.02 \pm 0.001, the discrepancy is at best about 3 \sigma. For instance, assuming the highest estimate of the ionizing background, as indicated by recent measurements of a large escape fraction from Lyman-break galaxies by Steidel, Pettini & Adelberger, we find \Omega_b h^2 = 0.045 \pm 0.008. A recent measurement of the ionizing background from the proximity effect by Scott et al., on the other hand, implies \Omega_b h^2 = 0.03 \pm 0.01. We provide an expression from which future likelihoods for \Omega_b h^2 can be derived as measurements of the ionizing background improve -- consistency among constraints from the forest, nucleosynthesis and the microwave background will provide a powerful test of the gravitational instability model. We also develop a formalism which treats lower bounds on the baryon density in a statistical manner, which is appropriate if only a lower bound on the ionizing background is known. Finally, we discuss the implications of the escape fraction measurement for the age, structure and stellar content of Lyman-break galaxies.