Stellar Morphology of Optically Dark or Faint Galaxies at $z>3$ with JWST

TL;DR

This study analyzes the stellar morphology of optically dark or faint galaxies at redshift >3 using JWST data, revealing they are massive, dust-obscured, and structurally similar to typical star-forming galaxies, with high dust attenuation driven by stellar mass.

Contribution

It provides the first detailed morphological analysis of OFGs at high redshift with JWST, highlighting their mass, dust content, and structural properties, and compares them to typical SFGs to understand their evolution.

Findings

OFGs are 8-9 times more massive than typical SFGs.

OFGs are approximately 4 times more dust attenuated.

OFGs structurally resemble typical SFGs with slight roundness.

Abstract

JWST offers an unprecedented view of optically dark or faint galaxies (OFGs), previously missed by HST. They are likely massive, heavily dust-obscured star-forming galaxies (SFGs) that substantially contribute to the cosmic SFR density at $z>$3. To identify drivers of their high dust attenuation and their role in early universe galaxy evolution, we analyse the stellar morphology of 65 OFGs (from 1892 SFGs at 3$<z<$4) using NIRCam/F444W imaging from the PRIMER and CEERS fields. We study correlations between dust attenuation ($A_v$) and galaxy properties, like stellar mass, size, and orientation, and compare scaling relations between OFGs and typical SFGs. We find that OFGs are ~8-9 times more massive and ~4 times more dust attenuated than the parent sample. Structurally, OFGs resemble parent SFGs in median $R_e$ and median $\Sigma_{R_e}$ but may be slightly rounder on average. While $A_v$ strongly correlates with stellar mass, it does not show significant dependence on stellar mass-normalised effective radius and stellar mass surface density, S\'ersic index, axis ratio, or SFR surface density. The mass-size and mass-surface density relations place OFGs as a higher-mass extension of SFGs, with no concrete proof of evolutionary differences between them. This suggests that OFGs are heavily dust-obscured primarily due to their high stellar masses, which facilitates dust production and retention, with older stellar populations likely contributing as well. Although some OFGs exhibit high $\Sigma_\mathrm{{R_e}}$ and occupy regions of the mass-size plane similar to quiescent galaxies, the overall sample is not representative of this. Their current structures resemble typical SFGs, with no concrete signs of rapid compaction. Diversity in their physical properties shows that OFGs span a range of evolutionary states with few showing reduced star formation, while most remain actively star-forming.