Omega0 and Substructure in Galaxy Clusters

Abstract

(Abridged) We examine the theoretical relationship between Omega0 and substructure in galaxy clusters which are formed by the collapse of high density peaks in a gaussian random field. The radial mass distributions of the clusters are computed from the spherical accretion model using the adiabatic approximation following Ryden & Gunn. For a cluster of mass, M(r,t), we compute the quantity dM/Mbar at a cosmic time t and within a radius r, where dM is the accreted mass and Mbar is the average mass of the cluster during the previous relaxation time, which is computed individually for each cluster. For a real cluster in three dimensions we argue that dM/Mbar should be strongly correlated with the low order multipole ratios, Phiintl/Phiint0, of the potential due to matter interior to r. It is shown that the expected correlation between dM/Mbar and Phiintl/Phiint0 extends to the two-dimensional multipole ratios, Psiintm/Psiint0, which are well defined observables of the cluster density distribution. The strongest dependence of dM/Mbar on Omega0 (lambda0=0) occurs at z=0 where dM/Mbar propto Omega01/2 for relaxation times ~1-2 crossing times and only very weakly depends on mass and radius. The fractional accreted mass in CDM models with Omega0+lambda0=1 depends very weakly on Omega0 and has a magnitude similar to the Omega0=1 value. dM/Mbar evolves more rapidly with redshift in low-density universes and decreases significantly with radius for Omega0=1 models for z > ~0.5. We discuss how to optimize constraints on Omega0 and lambda0 using cluster morphologies.

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