A closer view of the radio-FIR correlation: disentangling the contributions of star formation and AGN activity

TL;DR

This study investigates the radio-FIR correlation across various galaxy types, revealing that many AGN-hosting galaxies exhibit flux ratios similar to star-forming galaxies, complicating the separation of these populations based solely on flux ratios.

Contribution

The paper provides a detailed analysis of the radio-FIR correlation in different galaxy types, incorporating spectral energy distribution fitting and optical diagnostics to distinguish star formation from AGN activity.

Findings

Most AGN-containing galaxies have FIR/radio ratios similar to star-forming galaxies.

Seyfert galaxies show lower FIR/radio ratios due to AGN contribution.

IR-detected LINER and absorption line galaxies are AGN-dominated but have ratios consistent with star formation.

Abstract

We extend the Unified Radio Catalog, a catalog of sources detected by various (NVSS, FIRST, WENSS, GB6) radio surveys, and SDSS, to IR wavelengths by matching it to the IRAS Point and Faint Source catalogs. By fitting each NVSS-selected galaxy's NUV-NIR spectral energy distribution (SED) with stellar population synthesis models we add to the catalog star formation rates, stellar masses, and attenuations.We further add information about optical emission line properties for NVSS-selected galaxies with available SDSS spectroscopy. Using an NVSS 20cm (F_{1.4GHz} ge 2.5mJy) selected sample, matched to the SDSS spectroscopic ("main" galaxy and quasar) catalogs and IRAS data (0.04<z le 0.2) we perform an in depth analysis of the radio-FIR correlation for various types of galaxies, separated into i) quasars, ii) star forming, iii) composite, iv) Seyfert, v) LINER and vi) absorption line galaxies using the standard optical spectroscopic diagnostic tools. We utilize SED-based star formation rates to independently quantify the source of radio and FIR emission in our galaxies. Our results show that Seyfert galaxies have FIR/radio ratios lower than, but still within the scatter of, the canonical value due to an additional (likely AGN) contribution to their radio continuum emission. Furthermore, IR-detected absorption and LINER galaxies are on average strongly dominated by AGN activity in both their FIR and radio emission; however their average FIR/radio ratio is consistent with that expected for star forming galaxies. In summary, we find that most AGN-containing galaxies in our NVSS-IRAS-SDSS sample have FIR/radio flux ratios indistinguishable from those of the star-forming galaxies that define the radio-FIR correlation. Thus, attempts to separate AGNs from star-forming galaxies by their FIR/radio flux ratios alone can separate only a small fraction of the AGNs, such as the radio-loud quasars.