Inside-out growth or inside-out quenching? Clues from colour gradients of local galaxies

We constrain the spatial gradient of star formation history within galaxies using the colour gradients in NUV-u and u-i for a local spatially-resolved galaxy sample. By splitting each galaxy into an inner and an outer part, we find that most galaxies show negative gradients in these two colours. We first rule out dust extinction gradient and metallicity gradient as the dominant source for the colour gradient. Then using stellar population models, we explore variations in star formation history to explain the colour gradients. As shown by our earlier work, a two-phase SFH consisting of an early secular evolution (growth) phase and a subsequent rapid evolution (quenching) phase is necessary to explain the observed colour distributions among galaxies. We explore two different inside-out growth models and two different inside-out quenching models by varying parameters of the SFH between inner and outer regions of galaxies. Two of the models can explain the observed range of colour gradients in NUV-u and u-i colours. We further distinguish them using an additional constraint provided by the u-i colour gradient distribution, under the assumption of constant galaxy formation rate and a common SFH followed by most galaxies. We find the best model is an inside-out growth model in which the inner region has a shorter e-folding time scale in the growth phase than the outer region. More spatially resolved ultraviolet (UV) observations are needed to improve the significance of the result.

[1]  M. Bershady,et al.  SDSS-IV MaNGA: stellar population gradients as a function of galaxy environment , 2016, 1612.01545.

[2]  M. Bershady,et al.  SDSS-IV MaNGA : spatially resolved star formation histories in galaxies as a function of galaxy mass and type , 2016, 1612.01546.

[3]  R. Yan,et al.  THE QUENCHING TIMESCALE AND QUENCHING RATE OF GALAXIES , 2016, 1609.04805.

[4]  J. Haas,et al.  RICH KOZAI–LIDOV DYNAMICS IN AN INITIALLY THIN AND ECCENTRIC STELLAR DISK AROUND A SUPERMASSIVE BLACK HOLE , 2016, 1602.05582.

[5]  Weipeng Lin,et al.  THE SPATIALLY RESOLVED NUV–r COLOR OF LOCAL STAR-FORMING GALAXIES AND CLUES FOR QUENCHING , 2016, 1601.05503.

[6]  A. Quirrenbach,et al.  The CALIFA survey across the Hubble sequence: Spatially resolved stellar population properties in galaxies , 2015, 1506.04157.

[7]  G. Zamorani,et al.  Evidence for mature bulges and an inside-out quenching phase 3 billion years after the Big Bang , 2015, Science.

[8]  Weipeng Lin,et al.  QUENCHING DEPENDS ON MORPHOLOGIES: IMPLICATIONS FROM THE ULTRAVIOLET–OPTICAL RADIAL COLOR DISTRIBUTIONS IN GREEN VALLEY GALAXIES , 2014, 1407.6715.

[9]  D. Lang unWISE: UNBLURRED COADDS OF THE WISE IMAGING , 2014, 1405.0308.

[10]  X. Kong,et al.  Characterizing AGB stars in Wide-field Infrared Survey Explorer (WISE) bands , 2014, 1403.0343.

[11]  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.

[12]  M. Blanton,et al.  PRIMUS: CONSTRAINTS ON STAR FORMATION QUENCHING AND GALAXY MERGING, AND THE EVOLUTION OF THE STELLAR MASS FUNCTION FROM z = 0–1 , 2013, 1301.1688.

[13]  Benjamin D. Johnson,et al.  DUST-CORRECTED STAR FORMATION RATES OF GALAXIES. II. COMBINATIONS OF ULTRAVIOLET AND INFRARED TRACERS , 2011, 1108.2837.

[14]  Kevin Schawinski,et al.  IMPROVED AND QUALITY-ASSESSED EMISSION AND ABSORPTION LINE MEASUREMENTS IN SLOAN DIGITAL SKY SURVEY GALAXIES , 2011, 1106.1896.

[15]  M. Blanton,et al.  IMPROVED BACKGROUND SUBTRACTION FOR THE SLOAN DIGITAL SKY SURVEY IMAGES , 2011, 1105.1960.

[16]  A. Finoguenov,et al.  Direct observational evidence for a large transient galaxy population in groups at 0.85 < z < 1 , 2010, 1011.5509.

[17]  Jing Wang,et al.  The GALEX Arecibo SDSS survey – III. Evidence for the inside‐out formation of Galactic discs , 2010, 1011.0829.

[18]  V. Cardone,et al.  Colour and stellar population gradients in galaxies: correlation with mass , 2010, Monthly Notices of the Royal Astronomical Society.

[19]  B. Weiner,et al.  DETERMINING STAR FORMATION RATES FOR INFRARED GALAXIES , 2008, 0810.4150.

[20]  R. Azzollini,et al.  Cosmic Evolution of Stellar Disk Truncations: From z ~ 1 to the Local Universe , 2008, Proceedings of the International Astronomical Union.

[21]  A. Szalay,et al.  The UV-Optical Galaxy Color-Magnitude Diagram. III. Constraints on Evolution from the Blue to the Red Sequence , 2007, astro-ph/0703281.

[22]  Caltech,et al.  Star Formation in AEGIS Field Galaxies since z = 1.1: Staged Galaxy Formation and a Model of Mass-dependent Gas Exhaustion , 2007, astro-ph/0703056.

[23]  M. Blanton Galaxies in SDSS and DEEP2: A Quiet Life on the Blue Sequence? , 2005, astro-ph/0512127.

[24]  A. Szalay,et al.  Galaxy Luminosity Functions to z~1 from DEEP2 and COMBO-17: Implications for Red Galaxy Formation , 2005, astro-ph/0506044.

[25]  A. Szalay,et al.  Dust Attenuation in the Nearby Universe: A Comparison between Galaxies Selected in the Ultraviolet and in the Far-Infrared , 2004, astro-ph/0411343.

[26]  Z. Shao,et al.  Optical and Near-Infrared Color Profiles in Nearby Early-Type Galaxies and the Implied Age and Metallicity Gradients , 2004, astro-ph/0404226.

[27]  S. M. Fall,et al.  Star formation history and dust content of galaxies drawn from ultraviolet surveys , 2003, astro-ph/0312474.

[28]  G. Bruzual,et al.  Stellar population synthesis at the resolution of 2003 , 2003, astro-ph/0309134.

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

[30]  Heidelberg,et al.  Nearly 5000 Distant Early-Type Galaxies in COMBO-17: A Red Sequence and Its Evolution since z ~ 1 , 2003, astro-ph/0303394.

[31]  Timothy M. Heckman,et al.  Dust Absorption and the Ultraviolet Luminosity Density at z ≈ 3 as Calibrated by Local Starburst Galaxies , 1999, astro-ph/9903054.

[32]  M. Dickinson,et al.  Cosmic Star-Formation History , 1996, 1403.0007.

[33]  L. E. Davis,et al.  CCD surface photometry of galaxies with dynamical data. II. UBR photometry of 39 elliptical galaxies , 1990 .

[34]  J. Mathis,et al.  The relationship between infrared, optical, and ultraviolet extinction , 1989 .