The ALMA REBELS Survey: the dust content of $z \sim 7$ Lyman Break Galaxies

TL;DR

This study models dust content in $z \,\sim\,7$ Lyman Break Galaxies, finding that supernovae and outflows regulate dust, with grain growth playing a minor role, and explains observed dust-to-stellar mass ratios.

Contribution

It introduces a coupled metal and dust enrichment model that explains dust content and star formation obscuration in high-redshift galaxies, highlighting the limited role of grain growth.

Findings

Dust mass is mainly regulated by supernovae and outflows.

The model predicts a dust-to-stellar mass ratio of 0.07-0.1%.

Two galaxies show unexpectedly high dust-to-stellar mass ratios.

Abstract

We include a fully coupled treatment of metal and dust enrichment into the Delphi semi-analytic model of galaxy formation to explain the dust content of 13 Lyman Break Galaxies (LBGs) detected by the Atacama Large millimetre Array (ALMA) REBELS Large Program at $z\simeq 7$. We find that the galaxy dust mass, $M_d$, is regulated by the combination of SNII dust production, astration, shock destruction, and ejection in outflows; grain growth (with a standard timescale $\tau_0= 30$ Myr) plays a negligible role. The model predicts a dust-to-stellar mass ratio of $\sim 0.07-0.1\%$ and a UV-to-total star formation rate relation such that $log (\psi_{\rm UV}) = -0.05 ~[log (\psi)]^{2} + 0.86 ~log(\psi) -0.05$ (implying that 55-80\% of the star formation is obscured) for REBELS galaxies with stellar mass $M_* = 10^{9-10} M_\odot$. This relation reconciles the intrinsic UV luminosity of LBGs with their observed luminosity function at $z=7$. However, 2 out of the 13 systems show dust-to-stellar mass ratios ($\sim 0.94-1.1\%$) that are up to $18\times$ larger than expected from the fiducial relation. Due to the physical coupling between dust and metal enrichment, even decreasing $\tau_0$ to very low values (0.3 Myr) only increases the dust-to-stellar mass ratio by a factor $ \sim 2$. Given that grain growth is not a viable explanation for such high observed ratios of the dust-to-stellar mass, we propose alternative solutions.