The quenched fraction of satellites around simulated Milky Way-mass galaxies

TL;DR

This study compares satellite galaxy quenching in simulations and observations, finding consistent stellar-mass dependence but varying radial trends influenced by host environment and assembly history.

Contribution

It provides a uniform comparison of satellite quenched fractions across multiple simulations and observations, highlighting the robustness of mass dependence and the variability of radial trends.

Findings

Lower-mass satellites are more likely to be quenched across all datasets.

Radial trends differ among simulations, with environmental effects playing a significant role.

Simulations agree on mass dependence but show diverse environmental quenching signatures.

Abstract

We compare satellite quenched fractions across three cosmological simulation suites (FIREbox, the FIRE-2 zoom-ins, and IllustrisTNG50) and observational datasets from SAGA, ELVES, and the combined satellite population of the Milky Way and M31. To enable consistent comparisons, we select Milky Way-mass hosts with $M_{\rm halo} = 10^{11.9}$ - $10^{12.2} \, M_{\odot}$ and satellites with stellar masses of $10^{7}$ - $10^{10}\, M_{\odot}$, applying uniform projected apertures and a common quenching definition. All three simulations reproduce the strong observed trend that lower-mass satellites are more likely to be quenched, closely matching the stellar-mass dependence seen in SAGA, ELVES, and the MW+M31 system. This agreement indicates that the mass dependence of satellite quenching is a robust outcome of contemporary galaxy formation models. Radial trends, however, show meaningful differences. SAGA and ELVES exhibit gently declining quenched fractions with projected distance, reflecting strong environmental quenching at small radii. TNG50 most closely matches this behavior, FIREbox, remains consistent with with a nearly flat trend within uncertainties, and the FIRE-2 zoom-ins show suppressed inner quenched fractions driven almost entirely by their paired MW-M31 hosts, which lack high-mass satellites and show strong radial segregation between star-forming and quenched systems. This environmental imprint suggests that host environment and assembly history can influence satellite quenching outcomes and may contribute to diversity across simulations. Overall, while the simulations consistently recover the stellar-mass dependence of quenching their radial trends vary, highlighting the influence of host-halo conditions and motivating deeper exploration of how host environments shape satellite quenching.