An extreme case of galaxy and cluster co-evolution at $z$=0.7

TL;DR

This paper reports the discovery and analysis of a massive, highly evolved galaxy cluster at redshift 0.7, exhibiting extreme properties such as high velocity dispersion, intense star formation in its brightest galaxy, and evidence of a cooling flow, providing insights into early cluster evolution.

Contribution

The study presents the first detailed characterization of eMACSJ0252, revealing its extreme dynamical and morphological properties, and offers new observational evidence of galaxy cluster co-evolution at intermediate redshift.

Findings

High velocity dispersion of 1020 km/s indicating a massive cluster

Brightest galaxy with star formation rates between 85 and 300 M_sun/yr

Evidence of a cooling flow through gas kinematics and diffuse emission

Abstract

We report the discovery of eMACSJ0252.4$-$2100 (eMACSJ0252), a massive and highly evolved galaxy cluster at $z=0.703$. Our analysis of Hubble Space Telescope imaging and VLT/MUSE and Keck/DEIMOS spectroscopy of the system finds a high velocity dispersion of 1020$^{+180}_{-190}$ km s$^{-1}$ and a high (if tentative) X-ray luminosity of $(1.2\pm 0.4)\times10^{45}$ erg s$^{-1}$ (0.1$-$2.4 keV). As extreme is the system's brightest cluster galaxy, a giant cD galaxy that forms stars at a rate of between 85 and 300 M$_\odot$ yr$^{-1}$ and features an extended halo of diffuse [OII] emission, as well as evidence of dust. Its most remarkable properties, however, are an exceptionally high ellipticity and a radially symmetric flow of gas in the surrounding intracluster medium, potential direct kinematic evidence of a cooling flow. A strong-lensing analysis, anchored by two multiple-image systems with spectroscopic redshifts, finds the best lens model to consist of a single cluster-scale halo with a total mass of $(1.9\pm0.1)\times 10^{14}$ M$_\odot$ within 250 kpc of the cluster core and, again, an extraordinarily high ellipticity of $e=0.8$. Although further, in-depth studies across the electromagnetic spectrum (especially in the X-ray regime) are needed to conclusively determine the dynamical state of the system, the properties established so far suggest that eMACSJ0252 must have already been highly evolved well before $z\sim 1$, making it a prime target to constrain the physical mechanisms and history of the co-evolution or dark-matter halos and baryons in the era of cluster formation.