The low-mass and structured stellar halo of M83 argues against a merger origin for its starburst and extended neutral hydrogen disk

Eric F. Bell; Benjamin Harmsen; Matthew Cosby; Paul A. Price; Sarah Pearson; Antonela Monachesi; Roelof S. de Jong; Richard D'Souza; Katya Gozman; Jacob Nibauer; Michael P. Busch; Jeremy Bailin; Benne W. Holwerda; In Sung Jang; Adam Smercina

Paper

The low-mass and structured stellar halo of M83 argues against a merger origin for its starburst and extended neutral hydrogen disk

Abstract

A merger origin has been suggested for M83's massive, metal-rich extended HI disk and nuclear starburst. We observe M83's stellar halo to test this idea. We train nearest-neighbor star-galaxy separation on wide-area Subaru imaging with Hubble Space Telescope data to map M83's halo in resolved stars. We find that M83 has an extended, very low density smooth stellar halo of old and metal-poor [M/H]

RGB stars with a mass between 15 and 40 kpc of

. In addition to M83's well-known Northern Stream, our ground-based Subaru imaging reveals a new stream to M83's south, which modeling suggests could be its trailing arm. The combined stream masses are

, with metallicity [M/H]

. The stream progenitor was only recently accreted, as its stellar populations suggest that it formed stars until

Gyr ago. M83 lies on the stellar halo mass-metallicity correlation seen for other Milky Way mass galaxies, albeit with low stellar halo mass. We infer a total accreted mass of

, with the most massive past merger having

. We identify plausible M83 analogs in TNG-50 with similar stellar halos, finding that while a recent accretion can create a prominent stellar stream, such accretions do not trigger starburst activity, nor do they deliver enough gas to form M83's extended Hi disk. We conclude that other non-merger mechanisms, such as secular evolution or accretion of gas from the IGM, are likely to be responsible for M83's remarkable properties.