Unveiling the Dark Side of UV/Optical Bright Galaxies: Optically Thick Dust Absorption

TL;DR

This study uses JWST imaging to spatially resolve massive galaxies at z~3, revealing that optically thick dust structures are common and significantly impact the galaxies' observed properties, challenging previous assumptions.

Contribution

It provides the first spatially resolved analysis of optically thick dust substructures in high-redshift galaxies, demonstrating their ubiquity and physical characteristics.

Findings

Optically thick dust is common in massive galaxies at z~3.

Dark substructures are dustier and irregularly distributed.

A correlation exists between obscured luminosity and recent starburst activity.

Abstract

Over the past decades, a population of galaxies invisible in optical/near-infrared, but bright at longer wavelengths, have been identified through color selections. These so-called optically faint/dark galaxies are considered to be massive quiescent galaxies or highly dust-attenuated galaxies. Having the entire galaxy obscured by dust, however, is likely an extreme case of the much more common occurrence of optically thin and thick absorption coexisting in the same system. With the power of JWST imaging, we are able to spatially resolve massive galaxies at z~3, accurately model their spectral energy distributions, and identify candidate optically thick substructures. We target galaxies with log(M*/Msun)>10.3 and 2.5<z<3.5, and get 486 galaxies in CEERS and PRIMER fields. Based on excess NIR luminosity, we identify 162 galaxies (~33\% of the parent sample) as candidate hosts of optically thick substructures. We then carry out spatially resolved SED modeling to explore the physical properties of those dark substructures and estimate the amount of optically thick obscuration. We find that optically thick dust is ubiquitous in normal massive galaxies with a wide variety of SFR and morphology. 10-20\% of the stellar mass/SFR are unaccounted for in our selected galaxies, and the fraction is insensitive to stellar mass or SFR. The dark substructures are generally dustier than the rest of the galaxies and are irregularly distributed, arguing against an obscured AGN as the source of the NIR excess. A correlation between the obscured luminosity and the presence of a recent starburst in the past <100 Myr is also observed.