Luminous Infrared Galaxies with the Submillimeter Array: II. Comparing the CO(3-2) Sizes and Luminosities of Local and High-Redshift Luminous Infrared Galaxies

TL;DR

This study compares molecular gas properties in local and high-redshift luminous infrared galaxies, revealing consistent star formation efficiency and differing gas disk sizes, supporting the merger-driven evolution of high-redshift galaxies.

Contribution

It provides a direct comparison of CO(3-2) sizes and luminosities between local U/LIRGs and high-redshift galaxies, highlighting differences in gas disk sizes and merger stages.

Findings

Molecular gas traced by CO(3-2) correlates with infrared luminosity across five orders of magnitude.

Star formation efficiency remains nearly constant across galaxy types and epochs.

High-redshift SMGs have larger, more extended gas disks compared to local U/LIRGs.

Abstract

We present a detailed comparison of the CO(3-2) emitting molecular gas between a local sample of luminous infrared galaxies (U/LIRGs) and a high redshift sample that comprises submm selected galaxies (SMGs), quasars, and Lyman Break Galaxies (LBGs). The U/LIRG sample consists of our recent CO(3-2) survey using the Submillimeter Array while the CO(3-2) data for the high redshift population are obtained from the literature. We find that the L(CO(3-2)) and L(FIR) relation is correlated over five orders of magnitude, which suggests that the molecular gas traced in CO(3-2) emission is a robust tracer of dusty star formation activity. The near unity slope of 0.93 +/- 0.03 obtained from a fit to this relation suggests that the star formation efficiency is constant to within a factor of two across different types of galaxies residing in vastly different epochs. The CO(3-2) size measurements suggest that the molecular gas disks in local U/LIRGs (0.3 - 3.1 kpc) are much more compact than the SMGs (3 - 16 kpc), and that the size scales of SMGs are comparable to the nuclear separation (5 - 40 kpc) of the widely separated nuclei of U/LIRGs in our sample. We argue from these results that the SMGs studied here are predominantly intermediate stage mergers, and that the wider line-widths arise from the violent merger of two massive gas-rich galaxies taking place deep in a massive halo potential.