The far-infrared/radio correlation and radio spectral index of galaxies in the SFR-M* plane up to z 2

Benjamin Magnelli,Rob Ivison,Dieter Lutz,Ivan Valtchanov,Duncan Farrah,S. Berta,Frank Bertoldi,J. J. Bock,Asantha Cooray,Edo Ibar,Alexander Karim,E. Le Floch,Raanan Nordon,Sebastian Oliver,M. J. Page,Paola Popesso,Francesca Pozzi,D. Rigopoulou,L. Riguccini,Giulia Rodighiero,David J. Rosario,I. G. Roseboom,Lingyu Wang,Stijn Wuyts

The far-infrared/radio correlation and radio spectral index of galaxies in the SFR-M* plane up to z 2

2014

[Abridged] We study the evolution of the radio spectral index and far-infrared/radio correlation (FRC) across the star-formation rate-stellar masse (i.e. SFR-M*) plane up to z 2. We start from a M*-selected sample of galaxies with reliable SFR and redshift estimates. We then grid the SFR-M* plane in several redshift ranges and measure the infrared luminosity, radio luminosity, radio spectral index, and ultimately the FRC index (i.e. qFIR) of each SFR-M*-z bin. The infrared luminosities of our SFR-M*-z bins are estimated using their stacked far-infrared flux densities inferred from observations obtained with Herschel. Their radio luminosities and radio spectral indices (i.e. alpha, where Snu nu^-alpha) are estimated using their stacked 1.4GHz and 610MHz flux densities from the VLA and GMRT, respectively. Our far-infrared and radio observations include the most widely studied blank extragalactic fields -GOODS-N/S, ECDFS, and COSMOS- covering a sky area of 2deg^2. Using this methodology, we constrain the radio spectral index and FRC index of star-forming galaxies with M*>10^10Msun and 0

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