The SFR-M* Correlation Extends to Low Mass at High Redshift

Abstract

To achieve a fuller understanding of galaxy evolution, SED fitting can be used to recover quantities beyond stellar masses (M*) and star formation rates (SFRs). We use Star Formation Histories (SFHs) reconstructed via the Dense Basis method of Iyer \& Gawiser (2017) for a sample of 17,873 galaxies at 0.5<z<6 in the CANDELS GOODS-S field to study the nature and evolution of the SFR-M* correlation. The reconstructed SFHs represent trajectories in SFR-M* space, enabling us to study galaxies at epochs earlier than observed by propagating them backwards in time along these trajectories. We study the SFR-M* correlation at z=1,2,3,4,5,6 using both direct fits to galaxies observed at those epochs and SFR-M* trajectories of galaxies observed at lower redshifts. The SFR-M* correlations obtained using the two approaches are found to be consistent with each other through a KS test. Validation tests using SFHs from semi-analytic models and cosmological hydrodynamical simulations confirm the sensitivity of the method to changes in the slope, normalization and shape of the SFR-M* correlation. This technique allows us to further probe the low-mass regime of the correlation at high-z by 1 dex and over an effective volume of 10× larger than possible with just direct fits. We find that the SFR-M* correlation is consistent with being linear down to M* 107 M at z>4. The evolution of the correlation is well described by SFR= (0.80 0.029 - 0.017 0.010× tuniv) M* - (6.487 0.282-0.039 0.008× tuniv), where tuniv is the age of the universe in Gyr.