The Missing Metal Problem in Galaxy Clusters: Characterizing the Early Enrichment Population (2105.04638v3)

Abstract: Rich and poor galaxy clusters have the same measured halo metallicity, 0.35-0.4 $Z_\odot$, even though they are an order of magnitude apart in stellar fraction, $M_/M_{gas}$. The measured intracluster medium (ICM) metallicity in high-mass clusters cannot be explained by the visible stellar population as stars typically make up 3-20% of the total baryon mass. The independence of metallicity of $M_/M_{gas}$ suggests an external and universal source of metals such as an early enrichment population (EEP). Galaxy cluster RX J1416.4+2315, classified as a fosil system, has a stellar fraction of $M_/M_{gas}=0.054\pm0.018$, and here we improve the halo metallicity determination using archival Chandra and XMM Newton observations. We determine the ICM metallicity of RXJ1416 to be $0.303\pm0.053$ $Z_\odot$ within $0.3<R/R_{500}<1$, excluding the central galaxy. We combine this measurement with other clusters with a wider range of $M_/M_{gas}$ resulting in the fit of $Z_{tot}=(0.36\pm0.01)+(0.10\pm 0.17)(M_/M_{gas})$. This fit is largely independent of $M_/M_{gas}$, and shows that for a low $M_/M_{gas}$ system, the observed stellar population can make only 10-20% of the total metals. We quantify the Fe contribution of the EEP further by adopting a standard Fe yield for visible stellar populations, and find that $Z_{EEP}=(0.36\pm0.01)-(0.96\pm0.17)(M_/M_{gas})$. To account for the observed Fe mass, a supernova (SN) rate of $10\pm5$ SNe yr$^{-1}$ (Type Ia) and $40\pm19$ SNe yr$^{-1}$ (core collapse) is required over the redshift range $3<z<10$ for a single galaxy cluster with mass $\sim3\times10^{14}$ $M_\odot$ at z=0. These SNe might be visible in observations of high-redshift clusters and protoclusters with the James Webb Space Telescope.