A Universal Relation of Dust Obscuration Across Cosmic Time

Abstract

We investigate dust obscuration as parameterised by the infrared excess IRX IR/L UV in relation to global galaxy properties, using a sample of 32\,000 local star-forming galaxies (SFGs) selected from SDSS, GALEX and WISE. We show that IRX generally correlates with stellar mass (M), star formation rate (SFR), gas-phase metallicity (Z), infrared luminosity (L IR) and the half-light radius (R e). A weak correlation of IRX with axial ratio (b/a) is driven by the inclination and thus seen as a projection effect. By examining the tightness and the scatter of these correlations, we find that SFGs obey an empirical relation of the form IRX=10α\,(L IR)β\,R e-γ\,(b/a)-δ where the power-law indices all increase with metallicity. The best-fitting relation yields a scatter of 0.17\,dex and no dependence on stellar mass. Moreover, this empirical relation also holds for distant SFGs out to z=3 in a population-averaged sense, suggesting it to be universal over cosmic time. Our findings reveal that IRX approximately increases with L IR/R e[1.3 - 1.5] instead of L IR/R e2 (i.e., surface density). We speculate this may be due to differences in the spatial extent of stars versus star formation and/or complex star-dust geometries. We conclude that not stellar mass but IR luminosity, metallicity and galaxy size are the key parameters jointly determining dust obscuration in SFGs.