Cosmic Distance Duality Relation and the Shape of Galaxy Clusters

TL;DR

This study tests the cosmic distance-duality relation using galaxy cluster data and WMAP results, finding that elliptical models align well with the relation while spherical models show marginal consistency.

Contribution

It introduces a method to evaluate the validity of the DD relation with different galaxy cluster geometries using WMAP data and parametrized deviations.

Findings

Elliptical galaxy cluster models agree with the DD relation at 1-sigma.

Spherical models are only marginally compatible at 3-sigma.

The DD relation holds better under elliptical assumptions.

Abstract

Observations in the cosmological domain are heavily dependent on the validity of the cosmic distance-duality (DD) relation, D_L(z) (1 + z)^{2}/D_{A}(z) = 1, an exact result required by the Etherington reciprocity theorem where D_L(z) and D_A(z) are, respectively, the luminosity and angular diameter distances. In the limit of very small redshifts D_A(z) = D_L(z) and this ratio is trivially satisfied. Measurements of Sunyaev-Zeldovich effect (SZE) and X-rays combined with the DD relation have been used to determine D_A(z)from galaxy clusters. This combination offers the possibility of testing the validity of the DD relation, as well as determining which physical processes occur in galaxy clusters via their shapes. We use WMAP (7 years) results by fixing the conventional LCDM model to verify the consistence between the validity of DD relation and different assumptions about galaxy cluster geometries usually adopted in the literature. We assume that $\eta$ is a function of the redshift parametrized by two different relations: \eta(z) = 1 + \eta_{0}z, and \eta(z)=1 + \eta_{0}z/(1+z), where \eta_0 is a constant parameter quantifying the possible departure from the strict validity of the DD relation. In order to determine the probability density function (PDF) of \eta_{0}, we consider the angular diameter distances from galaxy clusters recently studied by two different groups by assuming elliptical (isothermal) and spherical (non-isothermal) $\beta$ models. The strict validity of the DD relation will occur only if the maximum value of \eta_{0} PDF is centered on \eta_{0}=0. It was found that the elliptical $\beta$ model is in good agreement with the data, showing no violation of the DD relation (PDF peaked close to \eta_0=0 at 1-sigma), while the spherical (non-isothermal) one is only marginally compatible at 3-sigma.