Constraints on Hubble's Constant, Omegabaryon and Lambda from Cosmic Microwave Background Observations
Abstract
In this paper we compare data to theory. We use a compilation of the most recent cosmic microwave background (CMB) measurements to constrain Hubble's constant h, the baryon fraction Omegab, and the cosmological constant lambda. We fit h-, Omegab- and lambda-dependent power spectra to the data. The models we consider are flat cold dark matter (CDM) dominated universes with flat (n=1) power spectra, thus the results obtained apply only to these models. CMB observations can exclude more than half of the h - Omegab parameter space explored. The CMB data favor low values of Hubble's constant; h ≈ 0.35. Low values of Omegab are preferred (Omegab ~ 0.03) but the chi-squared minimum is shallow and we obtain Omegab < 0.28. A model with h ≈ 0.40, Omegab ≈ 0.15 and OmegaCDM ≈ 0.85 is permitted by constraints from the CMB data, BBN, cluster baryon fractions and the shape parameter Gamma derived from the mass density power spectra of galaxies and clusters. For flat-lambda models, the CMB data, combined with BBN constraints exclude most of the h - lambda plane. Models with Omegao ≈ 0.3, lambda ≈ 0.7 with h ≈ 0.75 are fully consistent with the CMB data but are excluded by the strict new qo limits from supernovae (Perlmutter et al. 1996). A combination of CMB data goodness-of-fit statistics, BBN and supernovae constraints in the h-lambda plane, limits Hubble's constant to the interval 0.23 < h < 0.72.
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