# ALMA 200-parsec Resolution Imaging of Smooth Cold Dusty Disks in Typical   $z \sim 3$ Star-Forming Galaxies

**Authors:** W. Rujopakarn, E. Daddi, G. H. Rieke, A. Puglisi, M. Schramm, P. G., P\'erez-Gonz\'alez, G. E. Magdis, S. Alberts, F. Bournaud, D. Elbaz, M., Franco, L. Kawinwanichakij, K. Kohno, D. Narayanan, J. D. Silverman, T. Wang,, and C. C. Williams

arXiv: 1904.04507 · 2019-09-25

## TL;DR

This study uses high-resolution ALMA imaging to reveal that typical $z \,\sim\, 3$ star-forming galaxies have smooth, disk-like cold dust distributions without significant substructures, contrasting with more clumpy submillimeter galaxies.

## Contribution

First high-resolution ALMA observations of typical $z\sim 3$ star-forming galaxies showing smooth dust disks without substructures, unlike more disturbed submillimeter galaxies.

## Key findings

- Cold dust is smoothly distributed in galaxy centers.
- No dust substructures or clumps detected down to 1-3 $M_\odot$/yr.
- Clumpy substructures contribute at most 1-7% of star formation.

## Abstract

We present high-fidelity, 30 milliarcsecond (200-pc) resolution ALMA rest-frame 240 $\mu$m observations of cold dust emission in three typical main-sequence star-forming galaxies (SFGs) at $z \sim 3$ in the Hubble Ultra-Deep Field (HUDF). The cold dust is distributed within the smooth disk-like central regions of star formation $1 - 3$ kpc in diameter, despite their complex and disturbed rest-frame UV and optical morphologies. No dust substructures or clumps are seen down to $\simeq 1- 3$ $M_\odot$yr$^{-1}$ (1$\sigma$) per 200-pc beam. No dust emission is observed at the locations of UV-emitting clumps, which lie $\simeq 2-10$ kpc from the bulk of star formation. Clumpy substructures can contribute no more than $1-7$% of the total star formation in these galaxies (3$\sigma$ upper limits). The lack of star-forming substructures in our HUDF galaxies is to be contrasted with the multiple substructures characteristic of submillimeter-selected galaxies (SMGs) at the same cosmic epoch, particularly the far-IR-bright SMGs with similarly high-fidelity ALMA observations of Hodge et al. (2019). Individual star-forming substructures in these SMGs contain $\sim10-30$% of their total star formation. A substructure in these SMGs is often comparably bright in the far-infrared as (or in some cases brighter than) our typical SFGs, suggesting that these SMGs originate from a class of disruptive event involving multiple objects at the scale of our HUDF galaxies. The scale of the disruptive event found in our main-sequence SFGs, characterized by the lack of star-forming substructures at our resolution and sensitivity, could be less violent, e.g., gas-rich disk instability or minor mergers.

## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1904.04507/full.md

---
Source: https://tomesphere.com/paper/1904.04507