Radio continuum size evolution of star-forming galaxies over 0.35 < z < 2.25

Abstract

We present the first systematic study of the radio continuum size evolution of star-forming galaxies (SFGs) over the redshift range 0.35<z<2.25. We use the VLA COSMOS 3GHz map (noise rms=2.3\,μ Jy \,beam-1, θ beam=0.75\, arcsec) to construct a mass-complete sample of 3184 radio-selected SFGs that reside on and above the main-sequence (MS) of SFGs. We find no clear dependence between the radio size and stellar mass, M, of SFGs with 10.5(M/ M)11.5. Our analysis suggests that MS galaxies are preferentially extended, while SFGs above the MS are always compact. The median effective radius of SFGs on (above) the MS of R eff=1.50.2 (1.00.2) kpc remains nearly constant with cosmic time; a parametrization of the form R eff(1+z)α yields a shallow slope of only α=-0.260.08\,(0.120.14) for SFGs on (above) the MS. The size of the stellar component of galaxies is larger than the extent of the radio continuum emission by a factor 2 (1.3) at z=0.5\,(2), indicating star formation is enhanced at small radii. The galactic-averaged star formation rate surface density ( SFR) scales with the distance to the MS, except for a fraction of MS galaxies (10\%) that harbor starburst-like SFR. These "hidden" starbursts might have experienced a compaction phase due to disk instability and/or merger-driven burst of star formation, which may or may not significantly offset a galaxy from the MS. We thus propose to jointly use SFR and distance to the MS to better identify the galaxy population undergoing a starbursting phase.