The Scatter in the Hot Gas Content of Early-Type Galaxies

TL;DR

This study investigates the large variability in hot gas content among early-type galaxies by analyzing Chandra X-ray data and relating it to internal and external galaxy properties, revealing key factors influencing hot gas presence.

Contribution

It provides a comprehensive analysis of hot gas properties in 42 early-type galaxies, identifying correlations with star formation, environment, and galaxy dynamics, and clarifies the origins of hot gas diversity.

Findings

Deviations in hot gas luminosity are positively correlated with star formation rates.

Galaxies in dense environments tend to be massive slow-rotators.

Cold gas origins differ between cluster and field galaxies.

Abstract

Optically-similar early-type galaxies are observed to have a large and poorly understood range in the amount of hot, X-ray-emitting gas they contain.To investigate the origin of this diversity, we studied the hot gas properties of all 42 early-type galaxies in the multiwavelength ATLAS$^{\rm 3D}$ survey that have sufficiently deep {\sl Chandra} X-ray observations. We related their hot gas properties to a number of internal and external physical quantities. To characterize the amount of hot gas relative to the stellar light, we use the ratio of the gaseous X-ray luminosity to the stellar $K$-band luminosity, $L_{X_{\rm gas}}/L_K$; we also use the deviations of $L_{X_{\rm gas}}$ from the best-fit $L_{X_{\rm gas}}$--$L_K$ relation (denoted $\Delta L_{X_{\rm gas}}$). We quantitatively confirm previous suggestions that various effects conspire to produce the large scatter in the observed $L_X/L_K$ relation. In particular, we find that the deviations $\Delta L_{X_{\rm gas}}$ are most strongly positively correlated with the (low rates of) star formation and the hot gas temperatures in the sample galaxies. This suggests that mild stellar feedback may energize the gas without pushing it out of the host galaxies. We also find that galaxies in high galaxy density environments tend to be massive slow-rotators, while galaxies in low galaxy density environments tend to be low mass, fast-rotators. Moreover, cold gas in clusters and fields may have different origins. The star formation rate increases with cold gas mass for field galaxies but it appears to be uncorrelated with cold gas for cluster galaxies.