Cool Gas in High Redshift Galaxies

TL;DR

Recent advancements in observing cool interstellar gas in high-redshift galaxies have transformed it into a vital tool for understanding galaxy formation, star formation, and cosmic evolution through multi-line studies and dynamical imaging.

Contribution

This review highlights the progress in high-redshift molecular and atomic gas observations, emphasizing new insights into physical conditions, gas mass estimates, and galaxy dynamics during early cosmic epochs.

Findings

Increased detection of molecular gas in galaxies at z>1.

Progress in understanding the CO-to-H2 conversion factor at high redshift.

Atomic [CII] line as a tracer for galaxy dynamics and redshift measurement.

Abstract

Over the last decade, observations of the cool interstellar medium in distant galaxies via molecular and atomic fine structure line emission has gone from a curious look into a few extreme, rare objects, to a mainstream tool to study galaxy formation, out to the highest redshifts. Molecular gas has now been observed in close to 200 galaxies at z>1, including numerous AGN host-galaxies out to z~7, highly starforming sub-millimeter galaxies (median redshift z~2.5), and increasing samples of 'main-sequence' star forming galaxies at z~1.5-2.5. Studies have moved well beyond simple detections, to dynamical imaging at kpc-scale resolution, and multi-line, multi-species studies that determine the physical conditions in the interstellar medium. Observations of the cool gas are the required complement to studies of the stellar density and star formation history of the Universe, as they reveal the phase of the interstellar medium that immediately precedes star formation. Current observations suggest that the order of magnitude increase in the cosmic star formation rate density from z~0 to 2 is commensurate with a similar increase in the gas to stellar mass ratio in star forming disk galaxies. Progress has been made on determining the CO luminosity to H_2 mass conversion factor at high-z, and the dichotomy between high versus low depletion time values for main sequence versus starburst galaxies, respectively, with a likely dependence on metallicity and other local physical conditions. Studies of atomic fine structure line emission are rapidly progressing, with some tens of galaxies detected in the exceptionally bright [CII] 158 micron line to date. This line is proving to be a unique tracer of galaxy dynamics in the early Universe and has the potential to be the most direct means of obtaining spectroscopic redshifts for the first galaxies during cosmic reionization.