Cosmology and Astrophysics from Relaxed Galaxy Clusters II: Cosmological Constraints

Abstract

We present cosmological constraints from measurements of the gas mass fraction, fgas, for massive, dynamically relaxed galaxy clusters. Our data set consists of Chandra observations of 40 such clusters, identified in a comprehensive search of the Chandra archive, as well as high-quality weak gravitational lensing data for a subset of these clusters. Incorporating a robust gravitational lensing calibration of the X-ray mass estimates, and restricting our measurements to the most self-similar and accurately measured regions of clusters, significantly reduces systematic uncertainties compared to previous work. Our data for the first time constrain the intrinsic scatter in fgas, (7.42.3)% in a spherical shell at radii 0.8-1.2 r2500, consistent with the expected variation in gas depletion and non-thermal pressure for relaxed clusters. From the lowest-redshift data in our sample we obtain a constraint on a combination of the Hubble parameter and cosmic baryon fraction, h3/2b/m=0.0890.012, that is insensitive to the nature of dark energy. Combined with standard priors on h and b h2, this provides a tight constraint on the cosmic matter density, m=0.270.04, which is similarly insensitive to dark energy. Using the entire cluster sample, extending to z>1, we obtain consistent results for m and interesting constraints on dark energy: =0.65+0.17-0.22 for non-flat models, and w=-0.980.26 for flat constant-w models. Our results are both competitive and consistent with those from recent CMB, SNIa and BAO data. We present constraints on models of evolving dark energy from the combination of fgas data with these external data sets, and comment on the possibilities for improved fgas constraints using current and next-generation X-ray observatories and lensing data. (Abridged)