The temperature dependence of the far-infrared-radio correlation in the Herschel-ATLAS

TL;DR

This study investigates how the far-infrared-radio correlation (FIRC) in star-forming galaxies varies with dust temperature, redshift, and wavelength, revealing temperature dependence that impacts star formation rate estimations.

Contribution

It provides the first detailed analysis of the temperature dependence of the FIRC across multiple wavelengths using a large Herschel-ATLAS galaxy sample.

Findings

Stacked FIRC values are higher than individual detections.

Warm dust galaxies have higher 1.4 GHz luminosity.

FIRC shows significant temperature dependence at longer wavelengths.

Abstract

We use 10,387 galaxies from the Herschel Astrophysical TeraHertz Large Area Survey (H-ATLAS) to probe the far-infrared radio correlation (FIRC) of star forming galaxies as a function of redshift, wavelength, and effective dust temperature. All of the sources in our 250 {\mu}m-selected sample have spectroscopic redshifts, as well as 1.4 GHz flux density estimates measured from the Faint Images of the Radio Sky at Twenty centimetres (FIRST) survey. This enables us to study not only individual sources, but also the average properties of the 250 {\mu}m selected population using median stacking techniques. We find that individual sources detected at $\geq 5\sigma$ in both the H-ATLAS and FIRST data have logarithmic flux ratios (i.e. FIRC $q_\lambda$ parameters) consistent with previous studies of the FIRC. In contrast, the stacked values show larger $q_\lambda$, suggesting excess far-IR flux density/luminosity in 250{\mu}m selected sources above what has been seen in previous analyses. In addition, we find evidence that 250 {\mu}m sources with warm dust SEDs have a larger 1.4 GHz luminosity than the cooler sources in our sample. Though we find no evidence for redshift evolution of the monochromatic FIRC, our analysis reveals significant temperature dependence. Whilst the FIRC is reasonably constant with temperature at 100 {\mu}m, we find increasing inverse correlation with temperature as we probe longer PACS and SPIRE wavelengths. These results may have important implications for the use of monochromatic dust luminosity as a star formation rate indicator in star-forming galaxies, and in the future, for using radio data to determine galaxy star formation rates.