The full iron budget in simulated galaxy clusters: The chemistry between gas and stars

TL;DR

This study uses high-resolution cosmological simulations to analyze the distribution of iron between gas and stars in galaxy clusters, revealing discrepancies with observations and emphasizing the role of stellar content in ICM enrichment.

Contribution

It provides a detailed comparison of simulated and observed iron distribution in galaxy clusters, highlighting the impact of stellar mass fractions on ICM enrichment and identifying areas for model improvement.

Findings

Simulated clusters have a near-unity iron share, lower than observed in massive systems.

Stellar component dominates the difference in iron budget between simulations and observations.

Simulations show higher stellar mass fractions, affecting the iron content in the ICM.

Abstract

Heavy chemical elements such as iron in the intra-cluster medium (ICM) of galaxy clusters are a signpost of the interaction between the gas and stellar components. Observations of the ICM metallicity in present-day massive systems, however, pose a challenge to the underlying assumption that the cluster galaxies have produced the amount of iron that enriches the ICM. We evaluate the iron share between ICM and stars within simulated galaxy clusters with the twofold aim of investigating the origin of possible differences with respect to observational findings and of shedding light on the observed excess of iron on the ICM with respect to expectations based on the observed stellar population. We evaluated the iron mass in gas and stars in a sample of 448 simulated systems with masses M500 > 1e14 Msun at z=0.07. These were extracted from the high-resolution (352 cMpc/h)^3 volume of the Magneticum cosmological hydrodynamical simulations. We compared our results with observational data of low-redshift galaxy clusters. The iron share in simulated clusters features a shallow dependence on the total mass, and its value is close to unity on average. In the most massive simulated systems, the iron share is thus smaller than observational values by almost an order of magnitude. The dominant contribution to this difference is related to the stellar component, whereas the chemical properties of the ICM agree well overall with the observations. We find larger stellar mass fractions in simulated massive clusters, which in turn yield higher stellar iron masses, than in observational data. Consistently with the modelling, we confirm that the stellar content within simulated present-day massive systems causes the metal enrichment in the ICM. It will be crucial to alleviate the stellar mass discrepancy between simulations and observations to definitely assess the iron budget in galaxy clusters.