The Extended Distribution of Baryons Around Galaxies

TL;DR

This paper reviews and reanalyzes observations of galactic baryons, proposing a comprehensive picture of hot halo gas around L* galaxies, highlighting the distribution, mass, and differences between galaxy types.

Contribution

It offers a unified model for hot halo gas distribution around galaxies, integrating X-ray, SZ, and UV absorption data, and discusses differences between galaxy types.

Findings

Hot halos detected to 50-70 kpc with mass ~5E9 Msun.

Extrapolated gas mass comparable to stellar mass, but missing half the baryons.

SZ measurements suggest hot baryons extend beyond R200, differing between galaxy types.

Abstract

We summarize and reanalyze observations bearing upon missing galactic baryons, where we propose a consistent picture for halo gas in L >~ L* galaxies. The hot X-ray emitting halos are detected to 50-70 kpc, where typically, M_hot(<50 kpc) ~ 5E9 Msun, and with density n \propto r^-3/2. When extrapolated to R200, the gas mass is comparable to the stellar mass, but about half of the baryons are still missing from the hot phase. If extrapolated to 1.9-3 R200, the baryon to dark matter ratio approaches the cosmic value. Significantly flatter density profiles are unlikely for R < 50 kpc and they are disfavored but not ruled out for R > 50 kpc. For the Milky Way, the hot halo metallicity lies in the range 0.3-1 solar for R < 50 kpc. Planck measurements of the thermal Sunyaev-Zeldovich effect toward stacked luminous galaxies (primarily early-type) indicate that most of their baryons are hot, near the virial temperature, and extend beyond R200. This stacked SZ signal is nearly an order of magnitude larger than that inferred from the X-ray observations of individual (mostly spiral) galaxies with M_* > 10^11.3 Msun. This difference suggests that the hot halo properties are distinct for early and late type galaxies, possibly due to different evolutionary histories. For the cooler gas detected in UV absorption line studies, we argue that there are two absorption populations: extended halos; and disks extending to ~50 kpc, containing most of this gas, and with masses a few times lower than the stellar masses. Such extended disks are also seen in 21 cm HI observations and in simulations.