Constraining Metallicity-dependent Mixing and Extra Mixing Using [C/N] in Alpha-rich Field Giants

Internal mixing on the giant branch is an important process which affects the evolution of stars and the chemical evolution of the galaxy. While several mechanisms have been proposed to explain this mixing, better empirical constraints are necessary. Here, we use [C/N] abundances in 26,097 evolved stars from the SDSS-IV/APOGEE-2 Data Release 14 to trace mixing and extra mixing in old field giants with −1.7 < [Fe/H] < 0.1. We show that the APOGEE [C/N] ratios before any dredge-up occurs are metallicity dependent, but that the change in [C/N] at the first dredge-up is metallicity independent for stars above [Fe/H] ∼ −1. We identify the position of the red giant branch (RGB) bump as a function of metallicity, note that a metallicity-dependent extra mixing episode takes place for low-metallicity stars ([Fe/H] < −0.4) 0.14 dex in log g above the bump, and confirm that this extra mixing is stronger at low metallicity, reaching Δ[C/N] = 0.58 dex at [Fe/H] = −1.4. We show evidence for further extra mixing on the upper giant branch, well above the bump, among the stars with [Fe/H] < −1.0. This upper giant branch mixing is stronger in the more metal-poor stars, reaching 0.38 dex in [C/N] for each 1.0 dex in log g. The APOGEE [C/N] ratios for red clump (RC) stars are significantly higher than for stars at the tip of the RGB, suggesting additional mixing processes occur during the helium flash or that unknown abundance zero points for C and N may exist among the RC sample. Finally, because of extra mixing, we note that current empirical calibrations between [C/N] ratios and ages cannot be naively extrapolated for use in low-metallicity stars specifically for those above the bump in the luminosity function.

[1]  C. Prieto,et al.  APOGEE Data Releases 13 and 14: Stellar Parameter and Abundance Comparisons with Independent Analyses , 2018, The Astronomical Journal.

[2]  C. Prieto,et al.  APOGEE Data Releases 13 and 14: Data and Analysis , 2018, The Astronomical Journal.

[3]  L. Stanghellini,et al.  Galactic Planetary Nebulae as Probes of Radial Metallicity Gradients and Other Abundance Patterns , 2018, The Astrophysical Journal.

[4]  J. Zinn,et al.  The Second APOKASC Catalog: The Empirical Approach , 2018, The Astrophysical Journal Supplement Series.

[5]  C. Kobayashi,et al.  Extragalactic archaeology with the C, N, and O chemical abundances , 2018, 1802.03353.

[6]  Miguel de Val-Borro,et al.  The Astropy Project: Building an Open-science Project and Status of the v2.0 Core Package , 2018, The Astronomical Journal.

[7]  D. A. García-Hernández,et al.  University of Birmingham The Fourteenth Data Release of the Sloan Digital Sky Survey: , 2017 .

[8]  S. P. Littlefair,et al.  THE ASTROPY PROJECT: BUILDING AN INCLUSIVE, OPEN-SCIENCE PROJECT AND STATUS OF THE V2.0 CORE PACKAGE , 2018 .

[9]  D. A. García-Hernández,et al.  Target Selection for the SDSS-IV APOGEE-2 Survey , 2017, 1708.00155.

[10]  T. Beers,et al.  APOGEE Chemical Abundances of the Sagittarius Dwarf Galaxy , 2017, 1707.03456.

[11]  C. Prieto,et al.  The Correlation between Mixing Length and Metallicity on the Giant Branch: Implications for Ages in the Gaia Era , 2017, 1704.01164.

[12]  Aniruddha R. Thakar,et al.  Sloan Digital Sky Survey IV: Mapping the Milky Way, Nearby Galaxies, and the Distant Universe , 2017, 1703.00052.

[13]  S. Basu,et al.  A new method for the asteroseismic determination of the evolutionary state of red-giant stars , 2016, 1612.04751.

[14]  Y. Elsworth,et al.  Nitrogen depletion in field red giants: mixing during the He flash? , 2016, 1610.03286.

[15]  J. Ferguson,et al.  THE EFFECTS OF INDIVIDUAL METAL CONTENTS ON ISOCHRONES FOR C, N, O, Na, Mg, Al, Si, AND Fe , 2016, 1608.05078.

[16]  J. Valenti,et al.  SPECTRAL PROPERTIES OF COOL STARS: EXTENDED ABUNDANCE ANALYSIS OF 1,617 PLANET-SEARCH STARS , 2016, 1606.07929.

[17]  A. Jorissen,et al.  Cannibals in the thick disk: the young α-rich stars as evolved blue stragglers , 2016, 1603.08992.

[18]  D. A. García-Hernández,et al.  Red giant masses and ages derived from carbon and nitrogen abundances , 2015, 1511.08203.

[19]  Nicholas Troup,et al.  ASPCAP: THE APOGEE STELLAR PARAMETER AND CHEMICAL ABUNDANCES PIPELINE , 2015, 1510.07635.

[20]  H. Rix,et al.  SPECTROSCOPIC DETERMINATION OF MASSES (AND IMPLIED AGES) FOR RED GIANTS , 2015, 1511.08204.

[21]  M. Irwin,et al.  Carbon and nitrogen abundances of individual stars in the Sculptor dwarf spheroidal galaxy , 2015, 1511.01322.

[22]  P. Garaud,et al.  2D OR NOT 2D: THE EFFECT OF DIMENSIONALITY ON THE DYNAMICS OF FINGERING CONVECTION AT LOW PRANDTL NUMBER , 2015, 1508.07093.

[23]  D. A. García-Hernández,et al.  Young α-enriched giant stars in the solar neighbourhood , 2015 .

[24]  H. Rocha-Pinto,et al.  Homogeneous abundance analysis of FGK dwarf, subgiant, and giant stars with and without giant planets , 2015, 1505.01726.

[25]  M. Lehnert,et al.  Clues to the formation of the Milky Way's thick disk , 2015, 1504.02019.

[26]  C. Prieto,et al.  Young [α/Fe]-enhanced stars discovered by CoRoT and APOGEE: What is their origin? , 2015, 1503.06990.

[27]  F. Castelli,et al.  NEW H-BAND STELLAR SPECTRAL LIBRARIES FOR THE SDSS-III/APOGEE SURVEY , 2015, 1502.05237.

[28]  Young Sun Lee,et al.  CARBON IN RED GIANTS IN GLOBULAR CLUSTERS AND DWARF SPHEROIDAL GALAXIES , 2015, 1501.06908.

[29]  Annie C. Robin,et al.  ABUNDANCES, STELLAR PARAMETERS, AND SPECTRA FROM THE SDSS-III/APOGEE SURVEY , 2015, 1501.04110.

[30]  Scott W. Fleming,et al.  THE DATA REDUCTION PIPELINE FOR THE APACHE POINT OBSERVATORY GALACTIC EVOLUTION EXPERIMENT , 2015, 1501.03742.

[31]  Hilo,et al.  THE ELEVENTH AND TWELFTH DATA RELEASES OF THE SLOAN DIGITAL SKY SURVEY: FINAL DATA FROM SDSS-III , 2015, 1501.00963.

[32]  T. Beers,et al.  THE APOKASC CATALOG: AN ASTEROSEISMIC AND SPECTROSCOPIC JOINT SURVEY OF TARGETS IN THE KEPLER FIELDS , 2014, 1410.2503.

[33]  T. Beers,et al.  CARBON-ENHANCED METAL-POOR STAR FREQUENCIES IN THE GALAXY: CORRECTIONS FOR THE EFFECT OF EVOLUTIONARY STATUS ON CARBON ABUNDANCES , 2014, 1410.2223.

[34]  Prasanth H. Nair,et al.  Astropy: A community Python package for astronomy , 2013, 1307.6212.

[35]  W. Chaplin,et al.  Asteroseismic surface gravity for evolved stars , 2013, 1305.6586.

[36]  M. Shetrone,et al.  CARBON ABUNDANCES FOR RED GIANTS IN THE DRACO DWARF SPHEROIDAL GALAXY , 2013, 1303.3211.

[37]  P. Garaud,et al.  CHEMICAL TRANSPORT AND SPONTANEOUS LAYER FORMATION IN FINGERING CONVECTION IN ASTROPHYSICS , 2012, 1212.1688.

[38]  T. Radko,et al.  Equilibrium transport in double-diffusive convection , 2011, Journal of Fluid Mechanics.

[39]  Conny Aerts,et al.  Gravity modes as a way to distinguish between hydrogen- and helium-burning red giant stars , 2011, Nature.

[40]  W. Merryfield,et al.  THERMOHALINE MIXING: DOES IT REALLY GOVERN THE ATMOSPHERIC CHEMICAL COMPOSITION OF LOW-MASS RED GIANTS? , 2010, 1011.2191.

[41]  P. Denissenkov NUMERICAL SIMULATIONS OF THERMOHALINE CONVECTION: IMPLICATIONS FOR EXTRA-MIXING IN LOW-MASS RGB STARS , 2010, 1006.5481.

[42]  C. Charbonnel,et al.  Thermohaline instability and rotation-induced mixing I. Low- and intermediate-mass solar metallicity stars up to the end of the AGB , 2010, 1006.5359.

[43]  Robert Barkhouser,et al.  The Apache Point Observatory Galactic Evolution Experiment (APOGEE) , 2007, Astronomical Telescopes + Instrumentation.

[44]  M. Pinsonneault,et al.  MAGNETO-THERMOHALINE MIXING IN RED GIANTS , 2008, 0806.4346.

[45]  G. Wasserburg,et al.  Can Extra Mixing in RGB and AGB Stars Be Attributed to Magnetic Mechanisms? , 2007, 0708.2949.

[46]  A. Dotter,et al.  Stellar Population Models and Individual Element Abundances. I. Sensitivity of Stellar Evolution Models , 2007, 0706.0808.

[47]  Walter A. Siegmund,et al.  The 2.5 m Telescope of the Sloan Digital Sky Survey , 2006, astro-ph/0602326.

[48]  P. Marigo Asymptotic Giant Branch evolution at varying surface C/O ratio: effects of changes in molecular opacities , 2002, astro-ph/0203036.

[49]  S. Lucatello,et al.  The O-Na and Mg-Al anticorrelations in turn-off and early subgiants in globular clusters , 2000, astro-ph/0012457.

[50]  William E. Harris,et al.  A Catalog of Parameters for Globular Clusters in the Milky Way , 1996 .

[51]  R. P. Kraft ABUNDANCE DIFFERENCES AMONG GLOBULAR CLUSTER GIANTS: PRIMORDIAL VS. EVOLUTIONARY SCENARIOS , 1994 .

[52]  V. Smith,et al.  Sodium, aluminum, and oxygen abundance variations in giants in the globular cluster M4 , 1992 .

[53]  C. Sneden,et al.  Oxygen abundances in halo giants. III. Giants in the mildly metal-poor globular cluster M5 , 1992 .

[54]  Jeffery A. Brown Carbon-to-nitrogen ratios along the evolutionary sequence of M67 , 1987 .

[55]  N. Suntzeff,et al.  Carbon and nitrogen abundances in giant stars of the metal-poor globular cluster M92 , 1982 .

[56]  N. Suntzeff Carbon and nitrogen abundances in the giant stars of the globular clusters M3 and M13 , 1981 .

[57]  B. Tinsley Stellar lifetimes and abundance ratios in chemical evolution , 1979 .

[58]  C. Sneden,et al.  The 12 C/ 13 C ratio in stellar atmospheres. VIII. The very metal-deficient giant HD 122563. , 1977 .

[59]  I. Iben The surface ratio of n super 14 to c super 12 during helium burning. , 1964 .