A Grand Design for Galaxy Clusters: Connections and Predictions

TL;DR

This paper introduces a unified model for galaxy clusters' intra-cluster plasma, linking entropy profiles to cluster evolution and making predictions about temperature and turbulence based on entropy states.

Contribution

The study develops a simple entropy-based Supermodel that connects cluster properties with dark matter halo development, providing a unified framework for understanding cluster evolution.

Findings

Clusters split into low and high entropy classes.

Inverse correlation between entropy and halo concentration.

Predictions of temperature profiles and turbulence evolution.

Abstract

We take up from a library of 12 galaxy clusters featuring extended X-ray observations of their Intra Cluster Plasma (ICP), analyzed with our entropy-based Supermodel. Its few intrinsic parameters - basically, the central level and the outer slope of the entropy profile - enable us to uniformly derive not only robust snapshots of the ICP thermal state, but also the 'concentration' parameter marking the age of the host dark matter halo. We test these profiles for consistency with numerical simulations and observations. We find the central and the outer entropy to correlate, so that these clusters split into two main classes defined on the basis of low (LE) or high (HE) entropy conditions prevailing throughout the ICP. We also find inverse correlations between the central/outer entropy and the halo concentration. We interpret these in terms of mapping the ICP progress on timescales around 5 Gyr toward higher concentrations, under the drive of the dark matter halo development. The progress proceeds from HEs to LEs, toward states of deeper entropy erosion by radiative cooling in the inner regions, and of decreasing outer entropy production as the accretion peters out. We propose these radial and time features to constitute a cluster Grand Design, that we use here to derive a number of predictions. For HE clusters we predict sustained outer temperature profiles. For LEs we expect the outer entropy ramp to bend over, hence the temperature decline to steepen at low z; this feature goes together with an increasing turbulent support, a condition that can be directly probed with the SZ effect.