A controlled study of cold dust content in galaxies from z=0-2

Abstract

At z=1-3, the formation of new stars is dominated by dusty galaxies whose far-IR emission indicates they contain colder dust than local galaxies of a similar luminosity. We explore the reasons for the evolving IR emission of similar galaxies over cosmic time using: 1) Local galaxies from GOALS (L IR=1011-1012\,L); 2) Galaxies at z0.1-0.5 from the 5MUSES (L IR=1010-1012\,L); 3) IR luminous galaxies spanning z=0.5-3 from GOODS and Spitzer xFLS (L IR>1011\,L). All samples have Spitzer mid-IR spectra, and Herschel and ground-based submillimeter imaging covering the full IR spectral energy distribution, allowing us to robustly measure L IR SF, T dust, and M dust for every galaxy. Despite similar infrared luminosities, z>0.5 dusty star forming galaxies have a factor of 5 higher dust masses and 5K colder temperatures. The increase in dust mass is linked with an increase in the gas fractions with redshift, and we do not observe a similar increase in stellar mass or star formation efficiency. L160 SF/L70 SF, a proxy for T dust, is strongly correlated with L IR SF/M dust independently of redshift. We measure merger classification and galaxy size for a subsample, and there is no obvious correlation between these parameters and L IR SF/M dust or L160 SF/L70 SF. In dusty star forming galaxies, the change in L IR SF/M dust can fully account for the observed colder dust temperatures, suggesting that any change in the spatial extent of the interstellar medium is a second order effect.