Identifying and Characterizing the Most Heavily Dust-Obscured Galaxies at $1 \le z \le 4$

TL;DR

This study identifies and characterizes the most heavily dust-obscured galaxies at redshifts 1 to 4 using UV-MIR SED modeling, revealing their properties and morphology compared to other dusty galaxy populations.

Contribution

It introduces a novel selection method based on dust attenuation from SED modeling to identify heavily obscured galaxies, expanding understanding of their characteristics.

Findings

Sample has lower SFRs and higher A_V than SMGs.

Most galaxies are disk-like with axis ratios ~0.4.

Sample overlaps with but is distinct from dust-selected galaxy populations.

Abstract

We present 65 extremely dust-obscured galaxies from the UltraVISTA DR3 survey of the COSMOS field at $1<z<4$. In contrast to other studies of dusty galaxies, we select our sample based on dust attenuation measured by UV-MIR spectral energy distribution (SED) modeling that allows for extreme attenuation levels. We construct our sample by making cuts at $1 \le z \le 4$, A$_V \ge 3$, and log(M$_*$/M$_\odot$)$ \ge 10.5$. This method reliably selects galaxies exhibiting independent indicators of significant dust content, including FIR detection rates. We perform panchromatic SED modeling with matched $Herschel$ photometry and find stellar and dust properties that differ from typical sub-millimeter galaxy (SMG) samples as well as $Herschel$ sources matched in redshift and stellar mass. Our sources have lower star formation rates and higher A$_V$ than SMGs, but comparable total IR luminosities. Most of our sample falls on or near the star-forming main sequence for this redshift range. Finally, we perform a morphological analysis with GALFIT using the $K_S$-band images and $Hubble$ $F814W$ and $F160W$ imaging when available. Typical axis ratios of $\sim 0.4$ suggest disk-like morphology for the majority of our sources, and we note only three apparent merging systems. Our sample generally agrees with the size-mass relation for star-forming galaxies, with a tail extending to smaller sizes. We conclude that the most heavily obscured galaxies in this redshift range share many characteristics with typical star-forming galaxies, forming a population of dusty galaxies that overlaps, but is not encompassed by, those selected through dust emission.