Informative Priors on Primordial Non-Gaussianity Bias bφ From Galaxy Formation

Abstract

Constraining primordial non-Gaussianity via its scale-dependent imprint on galaxy clustering requires knowledge of the bias parameter bφ, which is exactly degenerate with flocNL at leading order. To break this degeneracy, current analyses adopt the relation (bφ = 2δc(b1 - 1)) based on the assumption of a universal mass function. This relation is known to break down for physically motivated galaxy selections, introducing systematic errors in the inferred flocNL that scale directly with the assumed bφ prior. We present a framework to construct physically motivated, observation-conditioned priors on bφ by marginalizing over galaxy formation uncertainties. We use the CAMELS-SAM simulation suite, augmented by separate Universe simulations, to measure galaxy formation observables, like the stellar mass function (SMF) and the stellar-to-halo mass relationship (SHMR), and bφ across a range of galaxy formation parameters. From these measurements, we construct a distribution of bφ conditioned on observations, and we select our galaxy sample to resemble the DESI Emission Line Galaxy (ELG) sample. Conditioning on the SMF or SHMR decreases σbφ from 0.69 to 0.08 and 0.02 respectively -- reductions of 88\% and 97\% -- with consistent results when conditioning on the observed data directly. Despite substantial shifts in the galaxy formation posteriors driven by known SC-SAM discrepancies at high halo masses, the resulting bφ distributions remain mutually consistent across all observables. The SMF and SHMR are found to carry sufficient constraining power to reduce the galaxy formation uncertainty in bφ relevant for flocNL inference with next-generation spectroscopic surveys