Constraining Cosmological Parameters using the Cluster Mass-Richness Relation

Abstract

The cluster mass-richness relation (MRR) is an observationally efficient and potentially powerful cosmological tool for constraining the mean matter density of the universe and the amplitude of fluctuations using the cluster abundance technique. We derive the MRR relation using GalWCat19, a publicly available galaxy cluster catalog we created from the Sloan Digital Sky Survey-DR13 spectroscopic dataset. The MRR shows a tail at the low-richness end. Using the Illustris-TNG and mini-Uchuu cosmological numerical simulations, we demonstrate that this tail is caused by systematical uncertainties. We show that, by means of a judicious cut, identified by the use of the Hinge function, it is possible to determine a richness threshold above which the MRR is linear i.e., where cluster mass scales with richness as logM200 = alpha + beta logN200. We derive the MRR and show it is consistent with both sets of simulations with a slope of beta ~ 1. We use our MRR to estimate cluster masses from the GalWCat19 catalog which we then use to set constraints on omegam and sigma8. Utilizing the all-member MRR, we obtain constraints of omegam = 0.31 (+0.04-0.03) and sigma8 = 0.82 (+0.05-0.04), and utilizing the red-member MRR, we obtain omegam = 0.31 (+0.04-0.03) and sigma8 = 0.81 (+0.05-0.04). Our constraints on omegam and sigma8 are consistent and very competitive with the Planck 2018 results.