Constancy of the Cluster Gas Mass Fraction in the Rh=ct Universe

Abstract

The ratio of baryonic to dark matter densities is assumed to have remained constant throughout the formation of structure. With this, simulations show that the fraction fgas(z) of baryonic mass to total mass in galaxy clusters should be nearly constant with redshift z. However, the measurement of these quantities depends on the angular distance to the source, which evolves with z according to the assumed background cosmology. An accurate determination of fgas(z) for a large sample of hot (kTe > 5 keV), dynamically relaxed clusters could therefore be used as a probe of the cosmological expansion up to z < 2. The fraction fgas(z) would remain constant only when the "correct" cosmology is used to fit the data. In this paper, we compare the predicted gas mass fractions for both LCDM and the Rh=ct Universe and test them against the 3 largest cluster samples. We show that Rh=ct is consistent with a constant fgas in the redshift range z < 2, as was previously shown for the reference LCDM model (with parameter values H0=70 km/s/Mpc, Omegam=0.3 and wde=-1). Unlike LCDM, however, the Rh=ct Universe has no free parameters to optimize in fitting the data. Model selection tools, such as the Akaike Information Criterion (AIC) and the Bayes Information Criterion (BIC), therefore tend to favour Rh=ct over LCDM. For example, the BIC favours Rh=ct with a likelihood of ~95% versus ~5% for LCDM.