The Diverse Molecular Gas Content of Massive Galaxies Undergoing Quenching at z ∼ 1

Sirio Belli, Alessandra Contursi, Reinhard Genzel, Linda J. Tacconi, Natascha M. Förster-Schreiber, Dieter Lutz, Francoise Combes, Roberto Neri, Santiago García-Burillo, Karl F. Schuster, Rodrigo Herrera-Camus, Ken Ichi Tadaki, Rebecca L. Davies, Richard I. Davies, Benjamin D. Johnson, Minju M. Lee, Joel Leja, Erica J. Nelson, Sedona H. Price, Jinyi ShangguanT. Taro Shimizu, Sandro Tacchella, Hannah Ubler

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Abstract

We present a detailed study of the molecular gas content and stellar population properties of three massive galaxies at 1 < z < 1.3 that are in different stages of quenching. The galaxies were selected to have quiescent optical/near-infrared spectral energy distribution and relatively bright emission at 24 μm, and show remarkably diverse properties. CO emission from each of the three galaxies is detected in deep NOEMA observations, allowing us to derive molecular gas fractions M gas/M ∗ of 13%-23%. We also reconstruct the star formation histories by fitting models to the observed photometry and optical spectroscopy, finding evidence for recent rejuvenation in one object, slow quenching in another, and rapid quenching in the third system. To better constrain the quenching mechanism we explore the depletion times for our sample and other similar samples at z ∼ 0.7 from the literature. We find that the depletion times are highly dependent on the method adopted to measure the star formation rate: using the UV+IR luminosity we obtain depletion times about 6 times shorter than those derived using dust-corrected [O ii] emission. When adopting the star formation rates from spectral fitting, which are arguably more robust, we find that recently quenched galaxies and star-forming galaxies have similar depletion times, while older quiescent systems have longer depletion times. These results offer new, important constraints for physical models of galaxy quenching.

Original languageEnglish (US)
Article numberL11
JournalAstrophysical Journal Letters
Volume909
Issue number1
DOIs
StatePublished - Mar 1 2021

All Science Journal Classification (ASJC) codes

  • Astronomy and Astrophysics
  • Space and Planetary Science

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