X-ray Spectroscopy of Galaxy Clusters

TL;DR

This review highlights how X-ray spectroscopy of galaxy clusters reveals their structure, evolution, and composition, providing insights into cosmic history, cluster dynamics, and astrophysical processes.

Contribution

It comprehensively summarizes the principles, scientific applications, and future prospects of X-ray spectroscopy in studying galaxy clusters, emphasizing its role in understanding cosmic evolution.

Findings

Precise ICM temperature measurements are crucial for galaxy cluster mass estimates.

X-ray spectra reveal the thermal structure and merger history of clusters.

Element abundances trace supernova contributions and transport processes in the ICM.

Abstract

Galaxy clusters, the largest clearly defined objects in our Universe, are ideal laboratories to study in detail the cosmic evolution of the intergalactic intracluster medium (ICM) and the cluster galaxy population. For the ICM, which is heated to X-ray radiating temperatures, X-ray spectroscopy is the most important tool to obtain insight into the structure and astrophysics of galaxy clusters. In this review we recall the basic principles of the interpretation of X-ray spectra from a hot, tenuous plasma and we illustrate the wide range of scientific applications of X-ray spectroscopy. The determination of galaxy cluster masses, important for cosmology, rest crucially on a precise spectroscopic ICM temperature determination. The study of the thermal structure of the ICM provides a very interesting fossil record of the energy release during galaxy formation and evolution. The temperature and pressure distribution of the ICM gives us important insight into the process of galaxy cluster merging and the dissipation of the merger energy in form of turbulent motion. Cooling cores in the centers are interesting laboratories to investigate the interplay between gas cooling, star- and black hole formation and energy feedback, which is diagnosed by means of X-ray spectroscopy. The element abundances deduced from X-ray spectra of the ICM provide a cosmic history record of the contribution of different supernovae to the nucleosynthesis of heavy elements and their spatial distribution partly reflects important transport processes in the ICM. Some discussion of plasma diagnostics for conditions out of thermal equilibrium and an outlook on the future prospects of X-ray spectroscopic cluster studies complete our review.