The Astrophysical Journal Letters (Jan 2024)

The H i Reservoir in Central Spiral Galaxies and the Implied Star Formation Process

  • Jing Dou,
  • Yingjie Peng,
  • Qiusheng Gu,
  • Alvio Renzini,
  • Luis C. Ho,
  • Filippo Mannucci,
  • Emanuele Daddi,
  • Chengpeng Zhang,
  • Jiaxuan Li,
  • Yong Shi,
  • Tao Wang,
  • Dingyi Zhao,
  • Cheqiu Lyu,
  • Di Li,
  • Feng Yuan,
  • Roberto Maiolino,
  • Yulong Gao

DOI
https://doi.org/10.3847/2041-8213/ad7574
Journal volume & issue
Vol. 973, no. 1
p. L23

Abstract

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The cold interstellar medium (ISM) as the raw material for star formation is critical to understanding galaxy evolution. It is generally understood that galaxies stop making stars when, in one way or another, they run out of gas. However, here we provide evidence that central spiral galaxies remain rich in atomic gas even if their star formation rate (SFR) and molecular gas fraction have dropped significantly compared to “normal” star-forming galaxies of the same mass. Since H i is sensitive to external processes, here we investigate central spiral galaxies using a combined sample from the Sloan Digital Sky Survey, Arecibo Legacy Fast ALFA survey, and the extended GALEX Arecibo SDSS Survey. After proper incompleteness corrections, we find that the key H i scaling relations for central spirals show significant but regular systematic dependence on stellar mass. At any given stellar mass, the H i gas mass fraction is about constant with changing specific star formation rate (sSFR), which suggests that H i reservoir is ubiquitous in central spirals with any star formation status down to M _* ∼ 10 ^9 M _⊙ . Together with the tight correlation between the molecular gas mass fraction and sSFR for galaxies across a wide range of different properties, it suggests that the decline of SFR of all central spirals in the local Universe is due to the halt of H _2 supply, though there is plenty of H i gas around. These hence provide critical observations of the dramatically different behavior of the cold multiphase ISM, and a key to understand the star formation process and quenching mechanism.

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