The MOSDEF Survey: Implications of the Lack of Evolution in the Dust Attenuation-Mass Relation to z~2

Abstract

We investigate the relationship between dust attenuation and stellar mass (M*) in star-forming galaxies over cosmic time. For this analysis, we compare measurements from the MOSFIRE Deep Evolution Field (MOSDEF) survey at z2.3 and the Sloan Digital Sky Survey (SDSS) at z0, augmenting the latter optical dataset with both UV Galaxy Evolution Explorer (GALEX) and mid-infrared Wide-field Infrared Survey Explorer (WISE) photometry from the GALEX-SDSS-WISE Catalog. We quantify dust attenuation using both spectroscopic measurements of Hα and Hβ emission lines, and photometric measurements of the rest-UV stellar continuum. The Hα/Hβ ratio is used to determine the magnitude of attenuation at the wavelength of Hα, A Hα. Rest-UV colors and spectral-energy-distribution fitting are used to estimate A1600, the magnitude of attenuation at a rest wavelength of 1600. As in previous work, we find a lack of significant evolution in the relation between dust attenuation and M* over the redshift range z0 to z2.3. Folding in the latest estimates of the evolution of M dust, (M dust/M gas), and gas surface density at fixed M*, we find that the expected M dust and dust mass surface density are both significantly higher at z2.3 than at z0. These differences appear at odds with the lack of evolution in dust attenuation. To explain the striking constancy in attenuation vs. M*, it is essential to determine the relationship between metallicity and (M dust/M gas), the dust mass absorption coefficient, and dust geometry, and the evolution of these relations and quantities from z0 to z2.3.