Dust Evolution in Galaxy Cluster Simulations

TL;DR

This paper presents a new simulation method for dust evolution in galaxy clusters, accounting for processes in the cold ISM, and compares predictions with observations across different redshifts.

Contribution

It introduces a state-of-the-art dust modeling approach in SPH simulations, including a two-size approximation and processes in the cold ISM, to better understand dust evolution in galaxy clusters.

Findings

Dust-rich proto-cluster regions at high redshift.

Including cold ISM processes increases dust content by 2-3 times.

Model reproduces local galaxy dust-metallicity trends but underestimates cluster dust at low redshift.

Abstract

We implement a state-of-the-art treatment of the processes affecting the production and Interstellar Medium (ISM) evolution of carbonaceous and silicate dust grains within SPH simulations. We trace the dust grain size distribution by means of a two-size approximation. We test our method on zoom-in simulations of four massive ($M_{200} \geq 3 \times 10^{14} M_{\odot}$) galaxy clusters. We predict that during the early stages of assembly of the cluster at $z \gtrsim 3$, where the star formation activity is at its maximum in our simulations, the proto-cluster regions are rich of dusty gas. Compared to the case in which only dust production in stellar ejecta is active, if we include processes occurring in the cold ISM,the dust content is enhanced by a factor $2-3$. However, the dust properties in this stage turn out to be significantly different than those observationally derived for the {\it average} Milky Way dust, and commonly adopted in calculations of dust reprocessing. We show that these differences may have a strong impact on the predicted spectral energy distributions. At low redshift in star forming regions our model reproduces reasonably well the trend of dust abundances over metallicity as observed in local galaxies. However we under-produce by a factor of 2 to 3 the total dust content of clusters estimated observationally at low redshift, $z \lesssim 0.5$ using IRAS, Planck and Herschel satellites data. This discrepancy can be solved by decreasing the efficiency of sputtering which erodes dust grains in the hot Intracluster Medium (ICM).