The Red and Featureless Outer Disks of Nearby Spiral Galaxies

TL;DR

This study uses deep optical imaging to analyze the outer disks of three nearby spiral galaxies, revealing large, smooth, red stellar populations with little ongoing star formation, suggesting secular dynamical processes shape these regions.

Contribution

It provides detailed observational evidence that outer disks are dominated by old, well-mixed stars, challenging models relying solely on radial migration and inside-out growth.

Findings

Outer disks are red and smooth with little star formation.

Similar outer disk properties across different environmental contexts.

Outer stellar populations extend several disk scalelengths beyond spiral arms.

Abstract

We present results from deep, wide-field surface photometry of three nearby (D=4--7 Mpc) spiral galaxies: M94 (NGC 4736), M64 (NGC 4826), and M106 (NGC 4258). Our imaging reaches limiting surface brightnesses of $\mu_{B} \sim$ 28 -- 30 mag arcsec$^{-2}$ and probes colors down to $\mu_{B} \sim$ 27.5 mag arcsec$^{-2}$. We compare our broadband optical data to available ultraviolet and high column-density HI data to better constrain the star forming history and stellar populations of the outermost parts of each galaxy's disk. Each galaxy has a well-defined radius beyond which little star formation occurs and the disk light appears both azimuthally smooth and red in color, suggestive of old, well-mixed stellar populations. Given the lack of ongoing star formation or blue stellar populations in these galaxies' outer disks, the most likely mechanisms for their formation are dynamical processes such as disk heating or radial migration, rather than inside-out growth of the disks. This is also implied by the similarity in outer disk properties despite each galaxy showing distinct levels of environmental influence, from a purely isolated galaxy (M94) to one experiencing weak tidal perturbations from its satellite galaxies (M106) to a galaxy recovering from a recent merger (M64), suggesting that a variety of evolutionary histories can yield similar outer disk structure. While this suggests a common secular mechanism for outer disk formation, the large extent of these smooth, red stellar populations---which reach several disk scalelengths beyond the galaxies' spiral structure---may challenge models of radial migration given the lack of any non-axisymmetric forcing at such large radii.