Marvelous Metals: Surveying the Circumgalactic Medium of Simulated Dwarf Galaxies

TL;DR

This study uses hydrodynamic simulations to analyze the circumgalactic medium of dwarf galaxies, revealing its role as a major reservoir of mass and metals, and providing insights for future observations.

Contribution

It offers the first comprehensive analysis of the CGM in simulated dwarf galaxies, highlighting the warm phase as a key component in baryon and metal retention.

Findings

48 extpm11 ext{%} of baryons are in the CGM.

Warm CGM gas dominates beyond half the virial radius.

Metals are primarily retained in the warm and cool gas phases.

Abstract

Dwarf galaxies are uniquely sensitive to energetic feedback processes and are known to experience substantial mass and metal loss from their disk. Here, we investigate the circumgalactic medium (CGM) of 64 isolated dwarf galaxies ($6.0<$log(M$_*/M_{\odot}$)$<9.5$) at $z=0$ from the Marvel-ous Dwarfs and Marvelous Massive Dwarfs hydrodynamic simulations. Our galaxies produce column densities broadly consistent with current observations. We investigate these column densities in the context of mass and metal retention rates and the physical properties of the CGM. We find $48\pm11\%$ of all baryons within $R_{200c}$ reside in the CGM, with $\sim70\%$ of CGM mass existing in a warm gas phase, $10^{4.5}<T<10^{5.5}$ K that dominates beyond $r/R_{200c}\sim0.5$. Further, the warm and cool ($10^{4.0}<T<10^{4.5}$ K) gas phases each retain $5-10\%$ of metals formed by the dwarf galaxy. The significant fraction of mass and metals residing in the warm CGM phase provides an interpretation for the lack of observed low ion detections beyond $b/R_{200c}\sim0.5$ at $z\sim0$, as the majority of mass in this region exists in higher ions. We find a weak correlation between galaxy mass and total CGM metal retention despite the fraction of metals lost from the halo increasing from $\sim10\%$ to $>40\%$ towards lower masses. Our findings highlight the CGM (primarily its warm component) as a key reservoir of mass and metals for dwarf galaxies across stellar masses and underscore its importance in understanding the baryon cycle in the low-mass regime. Finally, we provide individual galaxy properties of our full sample and quantify the fraction of ultraviolet observable mass to support future observational programs, particularly those aimed at performing a metal budget around dwarf galaxies.