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

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.

[1]  R. Davé,et al.  ALMA Measures Rapidly Depleted Molecular Gas Reservoirs in Massive Quiescent Galaxies at z ∼ 1.5 , 2020, 2012.01433.

[2]  N. Caplar,et al.  Stochastic modelling of star-formation histories II: star-formation variability from molecular clouds and gas inflow , 2020, Monthly Notices of the Royal Astronomical Society.

[3]  V. Wild,et al.  The star formation histories of z ∼ 1 post-starburst galaxies , 2020, Monthly Notices of the Royal Astronomical Society.

[4]  J. Speagle dynesty: a dynamic nested sampling package for estimating Bayesian posteriors and evidences , 2019, Monthly Notices of the Royal Astronomical Society.

[5]  P. Dokkum,et al.  Anomalously Narrow Line Widths of Compact Massive Star-forming Galaxies at z ∼ 2.3: A Possible Inclination Bias in the Size–Mass Plane , 2019, The Astrophysical Journal.

[6]  B. Weiner,et al.  Extremely Low Molecular Gas Content in a Compact, Quiescent Galaxy at z = 1.522 , 2019, The Astrophysical Journal.

[7]  B. Weiner,et al.  PHIBSS2: survey design and z = 0.5 – 0.8 results , 2018, Astronomy & Astrophysics.

[8]  O. I. Wong,et al.  Quenching time-scales of galaxies in the eagle simulations , 2018, Monthly Notices of the Royal Astronomical Society.

[9]  S. Belli,et al.  MOSFIRE Spectroscopy of Quiescent Galaxies at 1.5 < z < 2.5. II. Star Formation Histories and Galaxy Quenching , 2018, The Astrophysical Journal.

[10]  C. Tremonti,et al.  Clocking the Evolution of Post-starburst Galaxies: Methods and First Results , 2018, The Astrophysical Journal.

[11]  B. Weiner,et al.  Molecular Gas Contents and Scaling Relations for Massive, Passive Galaxies at Intermediate Redshifts from the LEGA-C Survey , 2018, The Astrophysical Journal.

[12]  P. Pattarakijwanich,et al.  Stellar and Molecular Gas Rotation in a Recently Quenched Massive Galaxy at z ∼ 0.7 , 2018, The Astrophysical Journal.

[13]  D. Elbaz,et al.  Jekyll & Hyde: quiescence and extreme obscuration in a pair of massive galaxies 1.5 Gyr after the Big Bang , 2017, 1709.03505.

[14]  D. Narayanan,et al.  Massive Quenched Galaxies at z ∼ 0.7 Retain Large Molecular Gas Reservoirs , 2017, 1708.03337.

[15]  C. Harrison,et al.  Impact of supermassive black hole growth on star formation , 2017, Nature Astronomy.

[16]  A. Finoguenov,et al.  The unexpectedly large dust and gas content of quiescent galaxies at z > 1.4 , 2017, Nature Astronomy.

[17]  B. Weiner,et al.  PHIBSS: Unified Scaling Relations of Gas Depletion Time and Molecular Gas Fractions , 2017, 1702.01140.

[18]  Benjamin D. Johnson,et al.  Deriving Physical Properties from Broadband Photometry with Prospector: Description of the Model and a Demonstration of its Accuracy Using 129 Galaxies in the Local Universe , 2016, 1609.09073.

[19]  Edinburgh,et al.  The evolution of post-starburst galaxies from z=2 to 0.5 , 2016, 1608.00588.

[20]  Timothy A. Davis,et al.  The MASSIVE survey - III. Molecular gas and a broken Tully-Fisher relation in the most massive early-type galaxies , 2015, 1510.00729.

[21]  Mattia Fumagalli,et al.  THE 3D-HST SURVEY: HUBBLE SPACE TELESCOPE WFC3/G141 GRISM SPECTRA, REDSHIFTS, AND EMISSION LINE MEASUREMENTS FOR ∼100,000 GALAXIES , 2015, 1510.02106.

[22]  M. Martig,et al.  A DIRECT CONSTRAINT ON THE GAS CONTENT OF A MASSIVE, PASSIVELY EVOLVING ELLIPTICAL GALAXY AT z = 1.43 , 2015, 1502.00003.

[23]  Shannon G. Patel,et al.  3D-HST WFC3-SELECTED PHOTOMETRIC CATALOGS IN THE FIVE CANDELS/3D-HST FIELDS: PHOTOMETRY, PHOTOMETRIC REDSHIFTS, AND STELLAR MASSES , 2014, 1403.3689.

[24]  O. I. Wong,et al.  The green valley is a red herring: Galaxy Zoo reveals two evolutionary pathways towards quenching of star formation in early-and late-type galaxies , 2014, 1402.4814.

[25]  S. Wuyts,et al.  The total infrared luminosity may significantly overestimate the star formation rate of quenching and recently quenched galaxies , 2014, 1402.0006.

[26]  S. Belli,et al.  VELOCITY DISPERSIONS AND DYNAMICAL MASSES FOR A LARGE SAMPLE OF QUIESCENT GALAXIES AT z > 1: IMPROVED MEASURES OF THE GROWTH IN MASS AND SIZE , 2013, 1311.3317.

[27]  G. Zamorani,et al.  THE SINS/zC-SINF SURVEY OF z ∼ 2 GALAXY KINEMATICS: EVIDENCE FOR GRAVITATIONAL QUENCHING , 2013, 1310.3838.

[28]  A. Dekel,et al.  Wet Disc Contraction to Galactic Blue Nuggets and Quenching to Red Nuggets , 2013, 1310.1074.

[29]  C. Conroy,et al.  THE DUST ATTENUATION LAW IN DISTANT GALAXIES: EVIDENCE FOR VARIATION WITH SPECTRAL TYPE , 2013, 1308.1099.

[30]  A. Bolatto,et al.  The CO-to-H2 Conversion Factor , 2013, 1301.3498.

[31]  F. Walter,et al.  Cool Gas in High-Redshift Galaxies , 2013, 1301.0371.

[32]  D.Lutz,et al.  PHIBSS: MOLECULAR GAS CONTENT AND SCALING RELATIONS IN z ∼ 1-3 MASSIVE, MAIN-SEQUENCE STAR-FORMING GALAXIES* , 2012 .

[33]  E. Wright,et al.  MID-INFRARED SELECTION OF ACTIVE GALACTIC NUCLEI WITH THE WIDE-FIELD INFRARED SURVEY EXPLORER. I. CHARACTERIZING WISE-SELECTED ACTIVE GALACTIC NUCLEI IN COSMOS , 2012, 1205.0811.

[34]  J. L. Donley,et al.  IDENTIFYING LUMINOUS ACTIVE GALACTIC NUCLEI IN DEEP SURVEYS: REVISED IRAC SELECTION CRITERIA , 2012, 1201.3899.

[35]  S. Ravindranath,et al.  CANDELS: THE COSMIC ASSEMBLY NEAR-INFRARED DEEP EXTRAGALACTIC LEGACY SURVEY—THE HUBBLE SPACE TELESCOPE OBSERVATIONS, IMAGING DATA PRODUCTS, AND MOSAICS , 2011, 1105.3753.

[36]  R. Giovanelli,et al.  COLD GASS, an IRAM legacy survey of molecular gas in massive galaxies – I. Relations between H2, H i, stellar content and structural properties , 2011, 1103.1642.

[37]  T. Treu,et al.  KECK SPECTROSCOPY OF z>1 FIELD SPHEROIDALS: DYNAMICAL CONSTRAINTS ON THE GROWTH RATE OF RED “NUGGETS” , 2010, 1004.1331.

[38]  J. Gunn,et al.  THE PROPAGATION OF UNCERTAINTIES IN STELLAR POPULATION SYNTHESIS MODELING. III. MODEL CALIBRATION, COMPARISON, AND EVALUATION , 2009, 0911.3151.

[39]  R. Teyssier,et al.  MORPHOLOGICAL QUENCHING OF STAR FORMATION: MAKING EARLY-TYPE GALAXIES RED , 2009, 0905.4669.

[40]  J. Gunn,et al.  THE ASTROPHYSICAL JOURNAL Preprint typeset using LATEX style emulateapj v. 10/09/06 THE PROPAGATION OF UNCERTAINTIES IN STELLAR POPULATION SYNTHESIS MODELING I: THE RELEVANCE OF UNCERTAIN ASPECTS OF STELLAR EVOLUTION AND THE IMF TO THE DERIVED PHYSICAL PR , 2022 .

[41]  S. Wuyts,et al.  FIREWORKS U38-to-24 μm Photometry of the GOODS Chandra Deep Field-South: Multiwavelength Catalog and Total Infrared Properties of Distant Ks-selected Galaxies , 2008 .

[42]  B. Draine,et al.  Infrared Emission from Interstellar Dust. IV. The Silicate-Graphite-PAH Model in the Post-Spitzer Era , 2006, astro-ph/0608003.

[43]  H. Rix,et al.  Toward an Understanding of the Rapid Decline of the Cosmic Star Formation Rate , 2005, astro-ph/0502246.

[44]  L. Kewley,et al.  [O II] as a Star Formation Rate Indicator , 2004, astro-ph/0401172.

[45]  G. Chabrier Galactic Stellar and Substellar Initial Mass Function , 2003, astro-ph/0304382.

[46]  G. Helou,et al.  The Infrared Spectral Energy Distribution of Normal Star-forming Galaxies: Calibration at Far-Infrared and Submillimeter Wavelengths , 2002, astro-ph/0205085.