Radio Continuum Emission from Evolving Star-Forming Galaxies -- I. Correlations Involving the Total Synchrotron Luminosity

Abstract

Synchrotron radiation dominates the continuum emission of star-forming galaxies in the frequency range from a few MHz to about 30\,GHz. We model the total synchrotron emission of a large population of evolving star-forming galaxies using the semi-analytic galaxy formation model GALFORM combined with the dynamo simulation code MAGNETIZER. Assuming local energy equipartition between cosmic rays and magnetic fields, we calculate the specific synchrotron luminosity Lν for each simulated galaxy at various frequencies and find strong positive correlations between Lν and both the star formation rate ( SFR) and characteristic galaxy rotation speed V rot for redshifts up to z 3. At low redshifts, the turbulent magnetic field is found to dominate in the synchrotron luminosity, but the contribution of the large-scale magnetic field increases with redshift and becomes important for z 1. The correlation between Lν and SFR arises from the tight correlation between the disc gas mass M gas and SFR, and the correlation between Lν and V rot is additionally a consequence of the stellar mass Tully--Fisher relation for main-sequence galaxies. At low redshifts, the model predictions and observational data compiled for this work show remarkable agreement, but a discrepancy arises at higher redshifts, where modelled SFR values are systematically smaller than those previously inferred from observations. These theoretical models will aid the interpretation of next-generation radio surveys with the Square Kilometre Array and other telescopes.