SAGAbg II: the Low-Mass Star-Forming Sequence Evolves Significantly Between 0.05<z<0.21

Abstract

The redshift-dependent relation between galaxy stellar mass and star formation rate (the Star-Forming Sequence, or SFS) is a key observational yardstick for galaxy assembly. We use the SAGAbg-A sample of background galaxies from the Satellites Around Galactic Analogs (SAGA) Survey to model the low-redshift evolution of the low-mass SFS. The sample is comprised of 23258 galaxies with Hα-based star formation rates (SFRs) spanning 6<10( M/[M])<10 and z<0.21 (t<2.5 Gyr). Although it is common to bin or stack galaxies at z 0.2 for galaxy population studies, the difference in lookback time between z=0 and z=0.21 is comparable to the time between z=1 to z=2. We develop a model to account for both the physical evolution of low-mass SFS and the selection function of the SAGA survey, allowing us to disentangle redshift evolution from redshift-dependent selection effects across the SAGAbg-A redshift range. Our findings indicate significant evolution in the SFS over the last 2.5 Gyr, with a rising normalization: SFR( M=108.5 M)(z)=1.24+0.25-0.23\ z -1.47+0.03-0.03. We also identify the redshift limit at which a static SFS is ruled out at the 95% confidence level, which is z=0.05 based on the precision of the SAGAbg-A sample. Comparison with cosmological hydrodynamic simulations reveals that some contemporary simulations under-predict the recent evolution of the low-mass SFS. This demonstrates that the recent evolution of the low-mass SFS can provide new constraints on the assembly of the low-mass Universe and highlights the need for improved models in this regime.