A Lower Bound on the Cosmic Baryon Density
Abstract
We derive analytic lower bounds on the cosmic baryon density by requiring that the high-redshift IGM contain enough neutral hydrogen to produce the observed absorption in quasar spectra. The key theoretical assumption is that absorbing structures are no more extended in redshift space than in real space. This assumption might not hold if clouds are highly overdense and thermally broadened, but it is likely to hold in the gravitational instability picture for the forest suggested by cosmological simulations, independently of the details of the cosmological model. The other ingredients in these bounds are an estimate of the UV background from quasars, a temperature T~104K for the "warm" photoionized IGM that produces most of the absorption, a value of the Hubble constant, and observational estimates of the mean flux decrement or, for a more restrictive bound, the distribution function P(τ) of optical depths. With plausible parameter values, the mean decrement bound implies a baryon density parameter 0.0125/h2. With conservative values, the bound weakens to 0.005/h2, but the required clustering of the IGM is then incompatible with other properties of quasar spectra. A recent observational determination of P(τ) implies 0.0125/h2 even for a conservative estimate of the UV background, and 0.018/h2 for a more reasonable estimate. These bounds are consistent with recent low estimates of the primordial deuterium-to-hydrogen ratio , which imply ≈ 0.025/h2, but the P(τ) bound can only be reconciled with high estimates by abandoning standard big bang nucleosynthesis or the gravitational instability picture for the origin of the forest. (Shortened abstract.)
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