A Global Model For Circumgalactic and Cluster-Core Precipitation

TL;DR

This paper develops an analytic model to interpret multiphase circumgalactic gas and cluster-core precipitation, linking local thermal conditions to observed gas properties and feedback mechanisms.

Contribution

It introduces a unified analytic framework for understanding precipitation and thermal balance in galaxy clusters and circumgalactic environments, informed by recent simulations.

Findings

Long-lasting gas configurations with 5 < t_cool / t_ff < 20 are common in cluster cores.

Precipitation-regulated feedback explains observed entropy profiles.

Models predict specific observational signatures of multiphase gas around galaxies.

Abstract

We provide an analytic framework for interpreting observations of multiphase circumgalactic gas that is heavily informed by recent numerical simulations of thermal instability and precipitation in cool-core galaxy clusters. We start by considering the local conditions required for the formation of multiphase gas via two different modes: (1) uplift of ambient gas by galactic outflows, and (2) condensation in a stratified stationary medium in which thermal balance is explicitly maintained. Analytic exploration of these two modes provides insights into the relationships between the local ratio of the cooling and freefall time scales (i.e., t_cool / t_ff), the large-scale gradient of specific entropy, and development of precipitation and multiphase media in circumgalactic gas. We then use these analytic findings to interpret recent simulations of circumgalactic gas in which global thermal balance is maintained. We show that long-lasting configurations of gas with 5 < t_cool / t_ff < 20 and radial entropy profiles similar to observations of local cool-core galaxy cluster cores are a natural outcome of precipitation-regulated feedback. We conclude with some observational predictions that follow from these models. This work focuses primarily on precipitation and AGN feedback in galaxy cluster cores, because that is where the observations of multiphase gas around galaxies are most complete. However, many of the physical principles that govern condensation in those environments apply to circumgalactic gas around galaxies of all masses.