Reproducing sub-millimetre galaxy number counts with cosmological hydrodynamic simulations

TL;DR

This study uses cosmological hydrodynamic simulations with detailed dust modeling to accurately reproduce observed sub-millimetre galaxy counts, showing that standard galaxy evolution processes suffice without exotic assumptions.

Contribution

It demonstrates that SIMBA simulations can match observed SMG counts and redshift distributions using on-the-fly dust modeling, avoiding the need for exotic hypotheses.

Findings

Good agreement with 850μm luminosity function shape

Normalisation within 0.25 dex for >3 mJy sources

52% of sources are blends of multiple components

Abstract

Matching the number counts of high-$z$ sub-millimetre-selected galaxies (SMGs) has been a long standing problem for galaxy formation models. In this paper, we use 3D dust radiative transfer to model the sub-mm emission from galaxies in the SIMBA cosmological hydrodynamic simulations, and compare predictions to the latest single-dish observational constraints on the abundance of 850$\mathrm{\mu m}$-selected sources. We find good agreement with the shape of the integrated 850$\mathrm{\mu m}$ luminosity function, and the normalisation is within 0.25 dex at $> 3 \; \mathrm{mJy}$, unprecedented for a fully cosmological hydrodynamic simulation, along with good agreement in the redshift distribution of bright SMGs. The agreement is driven primarily by SIMBA's good match to infrared measures of the star formation rate (SFR) function between $z = 2-4$ at high SFRs. Also important is the self-consistent on-the-fly dust model in SIMBA, which predicts, on average, higher dust masses (by up to a factor of 2.5) compared to using a fixed dust-to-metals ratio of 0.3. We construct a lightcone to investigate the effect of far-field blending, and find that 52% of sources are blends of multiple components, which makes a small contribution to the normalisation of the bright-end of the number counts. We provide new fits to the 850$\mathrm{\mu m}$ luminosity as a function of SFR and dust mass. Our results demonstrate that exotic solutions to the discrepancy between sub-mm counts in simulations and observations, such as a top-heavy IMF, are unnecessary, and that sub-millimetre-bright phases are a natural consequence of massive galaxy evolution.