pop-cosmos: Insights from generative modeling of a deep, infrared-selected galaxy population

Abstract

We present an extension of the pop-cosmos model for the evolving galaxy population up to redshift z6. The model is trained on distributions of observed colors and magnitudes, from 26-band photometry of 420,000 galaxies in the COSMOS2020 catalog with Spitzer IRAC Ch. 1<26. The generative model includes a flexible distribution over 16 stellar population synthesis (SPS) parameters, and a depth-dependent photometric uncertainty model, both represented using score-based diffusion models. We use the trained model to predict scaling relationships for the galaxy population, such as the stellar mass function, star-forming main sequence, and gas-phase and stellar metallicity vs. mass relations, demonstrating reasonable-to-excellent agreement with previously published results. We explore the connection between mid-infrared emission from active galactic nuclei (AGN) and star-formation rate, finding high AGN activity for galaxies above the star-forming main sequence at 1 z 2. Using the trained population model as a prior distribution, we perform inference of the redshifts and SPS parameters for 429,669 COSMOS2020 galaxies, including 39,588 with publicly available spectroscopic redshifts. The resulting redshift estimates exhibit minimal bias (median[z]=-8×10-4), scatter (σMAD=0.0132), and outlier fraction (6.19\%) for the full 0<z<6 spectroscopic compilation. These results establish that pop-cosmos can achieve the accuracy and realism needed to forward-model modern wide--deep surveys for Stage IV cosmology. We publicly release pop-cosmos software, mock galaxy catalogs, and COSMOS2020 redshift and SPS parameter posteriors.