Detection of Accretion Shelves Out to the Virial Radius of a Low-Mass Galaxy with JWST

TL;DR

This study uses JWST imaging to discover extended stellar halos and accretion shelves around a low-mass galaxy, revealing evidence of multiple minor mergers and demonstrating JWST's capability to detect ultra-faint dwarfs at significant distances.

Contribution

First detection of accretion shelves in a low-mass galaxy at large radii using JWST, supporting hierarchical galaxy growth models.

Findings

Identification of accretion shelves at 10-20 kpc and tentative second shelf at 50-100 kpc.

Metallicity decline supports minor merger scenario.

Detection of ultra-faint dwarf galaxy at 30 Mpc distance.

Abstract

We report the serendipitous discovery of an extended stellar halo surrounding the low-mass galaxy Ark 227 ($M_\ast=5\times10^9 M_\odot$; d=35 Mpc) in deep JWST NIRCam imaging from the Blue Jay Survey. The F200W-F444W color provides robust star-galaxy separation, enabling the identification of stars at very low density. By combining resolved stars at large galactocentric distances with diffuse emission from NIRCam and Dragonfly imaging at smaller distances, we trace the surface brightness and color profiles of this galaxy over the entire extent of its predicted dark matter halo, from 0.1-100 kpc. Controlled N-body simulations have predicted that minor mergers create "accretion shelves" in the surface brightness profile at large radius. We observe such a feature in Ark 227 at 10-20 kpc, which, according to models, could be caused by a merger with total mass ratio 1:10. The metallicity declines over this radial range, further supporting the minor merger scenario. There is tentative evidence of a second shelf at $\mu_V\approx 35$ mag arcsec$^{-2}$ extending from 50-100 kpc, along with a corresponding drop in metallicity. The stellar mass in this outermost envelope is $\approx10^7M_\odot$. These results suggest that Ark 227 experienced multiple mergers with a spectrum of lower-mass galaxies -- a scenario that is broadly consistent with the hierarchical growth of structure in a cold dark matter-dominated universe. Finally, we identify an ultra-faint dwarf associated with Ark 227 with $M_\ast\approx10^5 M_\odot$ and $\mu_{V,e}=28.1$ mag arcsec$^{-2}$, demonstrating that JWST is capable of detecting very low-mass dwarfs to distances of at least ~30 Mpc.