The Astrophysical Journal (Jan 2024)

A Break in the Size–Stellar Mass Relation: Evidence for Quenching and Feedback in Dwarf Galaxies

  • Nushkia Chamba,
  • Pamela M. Marcum,
  • Amélie Saintonge,
  • Alejandro S. Borlaff,
  • Matthew J. Hayes,
  • Valentin J. M. Le Gouellec,
  • S. Drew Chojnowski,
  • Michael N. Fanelli

DOI
https://doi.org/10.3847/1538-4357/ad7377
Journal volume & issue
Vol. 974, no. 2
p. 247

Abstract

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Mapping stars and gas in nearby galaxies is fundamental for understanding their growth and the impact of their environment. This issue is addressed by comparing the stellar “edges” of galaxies D _stellar , defined as the outermost diameter where in situ star formation significantly drops, with the gaseous distribution parameterized by the neutral atomic hydrogen diameter measured at 1 M _⊙ pc ^−2 , D _HI . By sampling a broad H i mass range 10 ^5 M _⊙ < M _HI < 10 ^11 M _⊙ , we find several dwarf galaxies with M _HI < 10 ^9 M _⊙ from the field and Fornax Cluster that are distinguished by D _stellar ≫ D _HI . For the cluster dwarfs, the average H i surface density near D _stellar is ∼0.3 M _⊙ pc ^−2 , reflecting the impact of quenching and outside-in gas removal from ram pressure and tidal interactions. In comparison, D _stellar / D _HI ranges between 0.5 and 2 in dwarf field galaxies, consistent with the expectations from stellar feedback. Only more massive disk galaxies in the field can thus be characterized by the common assumption that D _stellar ≲ D _HI . We discover a break in the D _stellar – M _⋆ relation at m _break ∼ 4 × 10 ^8 M _⊙ that potentially differentiates the low-mass regime, where the influence of stellar feedback and environmental processes more prominently regulates the sizes of nearby galaxies. Our results highlight the importance of combining deep optical and H i imaging for understanding galaxy evolution.

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