K-Band Imaging of the Nearby, Clumpy Turbulent Disk Galaxy DYNAMO G04-1

TL;DR

This study uses high-resolution K-band imaging and HST data to analyze stellar clumps in the nearby galaxy G04-1, revealing properties similar to high-redshift galaxies and challenging some simulation predictions about feedback effects.

Contribution

It provides detailed measurements of stellar clumps in a nearby turbulent galaxy, linking local observations to high-redshift galaxy characteristics and feedback models.

Findings

Clumps have masses from 3.6e6 to 2.7e8 solar masses.

Clumps closer to the galaxy center are more massive and redder.

Observed clump masses are inconsistent with strong radiative feedback in simulations.

Abstract

We present a case study of stellar clumps in G04-1, a clumpy, turbulent disk galaxy located at $z$ = 0.13 from the DYNAMO sample, using adaptive optics enabled K-band imaging ($\sim2.25$ kpc/arcsec) with Keck/NIRC2. We identify 15 stellar clumps in G04-1 with a range of masses from $3.6 \times 10^{6}$ to $2.7 \times 10^{8}\ \rm M_{\odot}$, and with a median mass of $\sim2.9 \times 10^{7}\ \rm M_{\odot}$. Note that these masses decrease by about one-half when we apply a light correction for the underlying stellar disk. A majority (12 of 15) of clumps observed in the $K_{P}$-band imaging have associated components in H$\alpha$ maps ($\sim2.75$ kpc/arcsec; $<$R$_{clump}> \sim$500 pc) and appear co-located ($\overline{\Delta x} \sim 0.1$ arcsec). Using Hubble Space Telescope WFC/ACS observations with the F336W and F467M filters, we also find evidence of radial trends in clump stellar properties: clumps closer to the centre of G04-1 are more massive (consistent with observations at high-$z$) and appear more red, suggesting they may be more evolved. Using our high-resolution data, we construct a star forming main sequence for G04-1 in terms of spatially-resolved quantities and find that all regions (both clump and intra-clump) within the galaxy are experiencing an enhanced mode of star formation routinely observed in galaxies at high-$z$. In comparison to recent simulations, our observation of a number of clumps with masses $10^{7}-10^{8}\ \rm M_{\odot}$ is not consistent with strong radiative feedback in this galaxy.