DEEP MIXING IN EVOLVED STARS. II. INTERPRETING Li ABUNDANCES IN RED GIANT BRANCH AND ASYMPTOTIC GIANT BRANCH STARS

We reanalyze the problem of Li abundances in red giants of nearly solar metallicity. After outlining the problems affecting our knowledge of the Li content in low-mass stars (M ⩽ 3 M☉), we discuss deep-mixing models for the red giant branch stages suitable to account for the observed trends and for the correlated variations of the carbon isotope ratio; we find that Li destruction in these phases is limited to masses below about 2.3 M☉. Subsequently, we concentrate on the final stages of evolution for both O-rich and C-rich asymptotic giant branch (AGB) stars. Here, the constraints on extra-mixing phenomena previously derived from heavier nuclei (from C to Al), coupled to recent updates in stellar structure models (including both the input physics and the set of reaction rates used), are suitable to account for the observations of Li abundances below A(Li) ≡ log ϵ(Li) ≃ 1.5 (and sometimes more). Also, their relations with other nucleosynthesis signatures of AGB phases (like the abundance of F, and the C/O and 12C/13C ratios) can be explained. This requires generally moderate efficiencies ( yr−1) for non-convective mass transport. At such rates, slow extra mixing does not remarkably modify Li abundances in early AGB phases; on the other hand, faster mixing encounters a physical limit in destroying Li, set by the mixing velocity. Beyond this limit, Li starts to be produced; therefore, its destruction on the AGB is modest. Li is then significantly produced by the third dredge up. We also show that effective circulation episodes, while not destroying Li, would easily bring the 12C/13C ratios to equilibrium, contrary to the evidence in most AGB stars, and would burn F beyond the limits shown by C(N) giants. Hence, we do not confirm the common idea that efficient extra mixing drastically reduces the Li content of C stars with respect to K–M giants. This misleading appearance is induced by biases in the data, namely: (1) the difficulty of measuring very low Li abundances in O-rich AGB stars due to the presence of TiO bands and (2) the fact that many, relatively massive (M > 3 M☉) K- and M-type giants may remain Li-rich, not evolving to the C-rich stages. Efficient extra mixing on the AGB is instead typical of very low masses (M ≲ 1.5 M☉). It also characterizes CJ stars, where it produces Li and reduces F and the carbon isotope ratio, as observed in these peculiar objects.

[1]  Belgium,et al.  The evolutionary state of Miras with changing pulsation periods , 2011, 1105.2198.

[2]  B. E. Reddy,et al.  ORIGIN OF LITHIUM ENRICHMENT IN K GIANTS , 2011, 1102.2299.

[3]  P. D. Laverny,et al.  Lithium abundances and extra mixing processes in evolved stars of M 67 , 2011, 1101.3757.

[4]  J. Lattanzio,et al.  THERMOHALINE MIXING AND ITS ROLE IN THE EVOLUTION OF CARBON AND NITROGEN ABUNDANCES IN GLOBULAR CLUSTER RED GIANTS: THE TEST CASE OF MESSIER 3 , 2010, 1012.1925.

[5]  S. Cristallo,et al.  DEEP MIXING IN EVOLVED STARS. I. THE EFFECT OF REACTION RATE REVISIONS FROM C TO Al , 2010, 1011.3948.

[6]  T. Neff Microscopic calculation of the 3He(α,γ)7Be and 3H(α,γ)7Li capture cross sections using realistic interactions. , 2010, Physical review letters.

[7]  A. B. Balantekin,et al.  Solar fusion cross sections II: the pp chain and CNO cycles , 2010, 1004.2318.

[8]  Charles W. Smith,et al.  INTERPLANETARY MAGNETIC FLUX DEPLETION DURING PROTRACTED SOLAR MINIMA , 2011 .

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

[10]  P. Eggenberger,et al.  Effects of rotational mixing on the asteroseismic properties of solar-type stars , 2010, 1009.4541.

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

[12]  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.

[13]  N. Langer,et al.  Thermohaline mixing in evolved low-mass stars , 2010, 1006.1354.

[14]  K. Cunha,et al.  FLUORINE ABUNDANCES IN GALACTIC ASYMPTOTIC GIANT BRANCH STARS , 2010 .

[15]  S. Cristallo,et al.  ON THE NEED FOR DEEP-MIXING IN ASYMPTOTIC GIANT BRANCH STARS OF LOW MASS , 2010, 1005.3549.

[16]  M. Busso,et al.  Computing Cool Bottom Process Effects in Low Mass AGB Stars , 2010 .

[17]  S. Campbell,et al.  IS EXTRA MIXING REALLY NEEDED IN ASYMPTOTIC GIANT BRANCH STARS? , 2010, 1002.4904.

[18]  T. Lebzelter,et al.  Correlation between technetium and lithium in a sample of oxygen-rich AGB variables ⋆ , 2009, 0911.3507.

[19]  A. Serenelli New results on standard solar models , 2009, 0910.3690.

[20]  M. Asplund,et al.  The chemical composition of the Sun , 2009, 0909.0948.

[21]  M. Busso,et al.  Extra-Mixing in Luminous Cool Red Giants: Hints from Evolved Stars With and Without Li , 2009, Publications of the Astronomical Society of Australia.

[22]  S. Cristallo,et al.  EVOLUTION, NUCLEOSYNTHESIS, AND YIELDS OF LOW-MASS ASYMPTOTIC GIANT BRANCH STARS AT DIFFERENT METALLICITIES , 2009, 1109.1176.

[23]  I. Kamp,et al.  The solar photospheric nitrogen abundance - Analysis of atomic transitions with 3D and 1D model atmospheres , 2009, 0903.3406.

[24]  Nuclear electron capture rate in stellar interiors and the case of 7Be , 2008, 0811.4053.

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

[26]  J. Zahn,et al.  Stellar Nucleosynthesis: 50 years after B2FH , 2008 .

[27]  M. Busso,et al.  Infrared Photometry and Evolution of Mass-Losing AGB Stars. II. Luminosity and Colors of MS and S Stars , 2008, 0806.4591.

[28]  Caltech,et al.  Magnetic Mixing in Red Giant and Asymptotic Giant Branch Stars , 2008, 0806.3933.

[29]  M. Busso,et al.  26Al production from magnetically induced extramixing in AGB stars , 2008, 0806.2733.

[30]  R. Siebenmorgen,et al.  The Fluorine Abundance in a Galactic Bulge AGB Star Measured from CRIRES Spectra , 2008, 0804.4057.

[31]  F. C. Barker,et al.  Experimental study of proton-induced nuclear reactions in 6,7 Li , 2008 .

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

[33]  F. Pantillon,et al.  Angular momentum transport by internal gravity waves. III. Wave excitation by core convection and the Coriolis effect , 2007, 0708.1477.

[34]  Italy.,et al.  Low-mass lithium-rich AGB stars in the Galactic bulge: evidence for Cool Bottom Processing? ? , 2007, 0707.1380.

[35]  J. Lattanzio,et al.  Compulsory Deep Mixing of 3He and CNO Isotopes in the Envelopes of Low-Mass Red Giants , 2007, 0706.2710.

[36]  C. Zahn Thermohaline mixing: a physical mechanism governing the photospheric composition of low-mass giants , 2007, astro-ph/0703302.

[37]  V. Smith,et al.  Correlations between Lithium and Technetium Absorption Lines in the Spectra of Galactic S Stars , 2007 .

[38]  L. Corcione,et al.  Mid-Infrared Photometry of Mass-losing Asymptotic Giant Branch Stars , 2007, astro-ph/0701501.

[39]  S. Vauclair,et al.  Low abundances of heavy elements in the solar outer layers: comparisons of solar models with helioseismic inversions , 2006, astro-ph/0611619.

[40]  S. Cristallo,et al.  A method to derive the absolute composition of the Sun, the solar system, and the stars , 2006, astro-ph/0611229.

[41]  D. A. García-Hernández,et al.  Lithium and zirconium abundances in massive Galactic O-rich AGB stars , 2006, astro-ph/0609106.

[42]  J. Lattanzio,et al.  Deep Mixing of 3He: Reconciling Big Bang and Stellar Nucleosynthesis , 2006, Science.

[43]  M. Pinsonneault,et al.  Fluorine Abundance Variations as a Signature of Enhanced Extra Mixing in Red Giants of the Globular Cluster M4 , 2006, astro-ph/0604503.

[44]  P. Moroni,et al.  The effect of heavy element opacity on pre-main sequence Li depletion , 2006, astro-ph/0604157.

[45]  C. Charbonnel,et al.  Rotational mixing in low-mass stars: II. Self-consistent models of Pop II RGB stars , 2006, astro-ph/0602389.

[46]  C. Charbonnel,et al.  Influence of Gravity Waves on the Internal Rotation and Li Abundance of Solar-Type Stars , 2005, Science.

[47]  Roma,et al.  Infrared photometry and evolution of mass-losing AGB stars - I. Carbon stars revisited , 2005, astro-ph/0509739.

[48]  H. Esbensen Sensitivity to multi-phonon excitations in heavy-ion fusion reactions , 2005, nucl-th/0509008.

[49]  C. Charbonnel,et al.  Hydrodynamical stellar models including rotation, internal gravity waves, and atomic diffusion - I. Formalism and tests on Pop I dwarfs , 2005 .

[50]  B. E. Reddy,et al.  Three Li-rich K Giants: IRAS 12327−6523, 13539−4153, and 17596−3952 , 2005, astro-ph/0503253.

[51]  Y. Pavlenko,et al.  First detection of a lithium rich carbon star in the Draco dwarf galaxy: Evidence for a young stellar population , 2004, astro-ph/0405305.

[52]  M. Pinsonneault,et al.  How Accurately Can We Calculate the Depth of the Solar Convective Zone? , 2004, astro-ph/0403604.

[53]  B. Croke,et al.  Lithium in Large Magellanic Cloud carbon stars , 2003 .

[54]  G. Shaviv,et al.  The state of 7Be in the core of the Sun and the solar neutrino flux , 2002, astro-ph/0209253.

[55]  G. Wasserburg,et al.  Cool Bottom Processes on the Thermally Pulsing Asymptotic Giant Branch and the Isotopic Composition of Circumstellar Dust Grains , 2002, astro-ph/0211271.

[56]  C. Rossi-Alvarez,et al.  First measurement of the d(p,γ)3He cross section down to the solar Gamow peak , 2002 .

[57]  P. de Laverny,et al.  s-Process Nucleosynthesis in Carbon Stars , 2002, astro-ph/0207245.

[58]  J. Bahcall,et al.  Erratum: The Salpeter plasma corrections for solar fusion reactions , 2002 .

[59]  F. C. Barker R-Matrix Fits Involving Levels of 8Be , 2000 .

[60]  J. Isern,et al.  The Chemical Composition of Carbon Stars. II. The J-Type Stars , 2000, astro-ph/0001144.

[61]  P. Aguer,et al.  A compilation of charged-particle induced thermonuclear reaction rates , 1999 .

[62]  F. Terrasi,et al.  First Measurement of the 3 He ( 3 He , 2 p ) 4 He Cross Section down to the Lower Edge of the Solar Gamow Peak , 1999, nucl-ex/9902004.

[63]  F. Rogers,et al.  Consistent Solar Evolution Model Including Diffusion and Radiative Acceleration Effects , 1998 .

[64]  D. Lambert,et al.  Boron in Lithium- and Beryllium-deficient F Stars , 1998 .

[65]  W. Wamsteker,et al.  Ultraviolet astrophysics beyond the IUE final archive : proceedings of the conference held in Sevilla, Spain, from 11th to 14th November 1997 , 1998 .

[66]  M. Pinsonneault MIXING IN STARS , 1997 .

[67]  J. Isern,et al.  12C/13C ratios and Li abundances in C stars: evidence for deep mixing? , 1997 .

[68]  H. Richer,et al.  Late-Type Stars in M31. II. C-, S-, and M-Star Spectra , 1996 .

[69]  A. I. Boothroyd,et al.  Creation of 7Li and Destruction of 3He, 9Be, 10B, and 11B in Low-Mass Red Giants, Due to Deep Circulation , 1995, astro-ph/9512122.

[70]  G. Wasserburg,et al.  Deep Circulation in Red Giant Stars: A Solution to the Carbon and Oxygen Isotope Puzzles? , 1995 .

[71]  S. Balachandran The Lithium Dip in M67: Comparison with the Hyades, Praesepe, and NGC 752 Clusters , 1995 .

[72]  V. Smith,et al.  A Survey of Lithium in the Red Giants of the Magellanic Clouds , 1995 .

[73]  V. Smith,et al.  Lithium abundances and other clues to envelope burning in small Magellanic Cloud asymptotic giant branch stars , 1993 .

[74]  A. Loeb,et al.  Element Diffusion in the Solar Interior , 1993, astro-ph/9304005.

[75]  G. Denn,et al.  Lithium abundances in carbon stars , 1991 .

[76]  P. Charbonneau,et al.  The lithium abundance in stars , 1991 .

[77]  V. Smith,et al.  On the occurrence of enhanced lithium in Magellanic Cloud red giants , 1990 .

[78]  G. Wallerstein,et al.  LITHIUM ABUNDANCES IN SC STARS , 1990 .

[79]  K. K. Gilroy Carbon isotope ratios and lithium abundances in open cluster giants , 1989 .

[80]  V. Smith,et al.  Synthesis of Lithium and s-Process Elements in Small Magellanic Cloud Asymptotic Giant Branch Stars , 1989 .

[81]  Ann Merchant Boesgaard,et al.  Lithium in early F dwarfs , 1986 .

[82]  A. Boesgaard,et al.  Lithium in the Hyades Cluster , 1986 .

[83]  G. Michaud The lithium abundance gap in the Hyades F stars - The signature of diffusion , 1986 .

[84]  C. Sneden,et al.  A Search for Lithium-rich Giant Stars , 1984 .

[85]  D. Lambert,et al.  Lithium in late-type giants. II. 31 M giants and supergiants , 1982 .

[86]  D. Lambert,et al.  Lithium in late-type giants. I. G and K giants , 1980 .

[87]  J. Swings,et al.  29. Stellar Spectra (Spectres Stellaires) , 1976 .

[88]  I. Iben On the abundance of lithium in red giants of intermediate mass , 1973 .

[89]  A. G. W. Cameron,et al.  Lithium and the s-process in red-giant stars , 1971 .

[90]  C. Moeller,et al.  The ^{7}Be Electron-Capture Rate , 1969 .

[91]  I. Iben,et al.  The effect of Be super 7 K-capture on the solar neutrino flux. , 1967 .

[92]  G. Wallerstein,et al.  Lithium in Carbon Stars. II , 1966 .

[93]  A. Mckellar INTENSE Λ 6708 RESONANCE DOUBLET OF LI I IN THE SPECTRUM OF WZ CASSIOPEIAE , 1940 .