The Age-Redshift Relationship of Old Passive Galaxies

Abstract

We use 32 age measurements of passively evolving galaxies as a function of redshift to test and compare the standard model () with the R h=ct Universe. We show that the latter fits the data with a reduced 2 dof=0.435 for a Hubble constant H0= 67.2-4.0+4.5 km s-1 Mpc-1. By comparison, the optimal flat model, with two free parameters (including m=0.12-0.11+0.54 and H0=94.3-35.8+32.7 km s-1 Mpc-1), fits the age-z data with a reduced 2 dof=0.428. Based solely on their 2 dof values, both models appear to account for the data very well, though the optimized parameters are only marginally consistent with those of the concordance model ( m=0.27 and H0= 70 km s-1 Mpc-1). Fitting the age-z data with the latter results in a reduced 2 dof=0.523. However, because of the different number of free parameters in these models, selection tools, such as the Akaike, Kullback and Bayes Information Criteria, favour R h=ct over with a likelihood of 66.5\%-80.5\% versus 19.5\%-33.5\%. These results are suggestive, though not yet compelling, given the current limited galaxy age-z sample. We carry out Monte Carlo simulations based on these current age measurements to estimate how large the sample would have to be in order to rule out either model at a 99.7\% confidence level. We find that if the real cosmology is , a sample of 45 galaxy ages would be sufficient to rule out R h=ct at this level of accuracy, while 350 galaxy ages would be required to rule out if the real Universe were instead R h=ct.