The evolution of the Milky Way from its earliest phases: Constraints on stellar nucleosynthesis

We computed the evolution of the abundances of O, Mg, Si, Ca, K, Ti, Sc, Ni, Mn, Co, Fe and Zn in the Milky Way. We made use of the most widely adopted nucleosynthesis calculations and compared the model results with observational data with the aim of imposing constraints upon stellar yields. To best fit the data in the solar neighborhood, when adopting the Woosley & Weaver (1995, ApJS, 101, 181) yields for massive stars and the Iwamoto et al. (1999, ApJS, 125, 439) ones for type Ia SNe, it is required that: i) the Mg yields should be increased in stars with masses from 11 to 20 Mand decreased in masses larger than 20 M� . The Mg yield should be also increased in SNe Ia. ii) The Si yields should be slightly increased in stars above 40 M� , whereas those of Ti should be increased between 11 and 20 Mand above 30 M� . iii) The Cr and Mn yields should be increased in stars with masses in the range 11-20 M� ; iv) the Co yields in SNe Ia should be larger and smaller in stars in the range 11-20 M� ; v) the Ni yield from type Ia SNe should be decreased; vi) the Zn yield from type Ia SNe should be increased. vii) The yields of O (metallicity dependent SN models), Ca, Fe, Ni, and Zn (the solar abundance case) in massive stars from Woosley & Weaver (1995) are the best to fit the abundance patterns of these elements since they do not need any changes. We also adopted the yields by Nomoto et al. (1997, Nucl. Phys. A, 621, 467) and Limongi & Chieffi (2003, ApJ, 592, 404) for massive stars and discuss the corrections required in these yields in order to fit the observations. Finally, the small spread in the (el/Fe) ratios in the metallicity range from (Fe/H) = − 4.0 up to−3.0 dex (Cayrel et al. 2004, A&A, 416, 1117) is a clear sign that the halo of the Milky Way was well mixed even in the earliest phases of its evolution.

[1]  T. Beers,et al.  First stars V - Abundance patterns from C to Zn and supernova yields in the early Galaxy , 2003, astro-ph/0311082.

[2]  F. Matteucci The chemical evolution of the galaxy , 2003 .

[3]  A. Chieffi,et al.  Evolution, Explosion, and Nucleosynthesis of Core-Collapse Supernovae , 2003, astro-ph/0304185.

[4]  M. Asplund,et al.  O/Fe in metal-poor main sequence and subgiant stars ? , 2002, astro-ph/0205372.

[5]  T. Beers,et al.  Stellar Archaeology: A Keck Pilot Program on Extremely Metal-poor Stars from the Hamburg/ESO Survey. II. Abundance Analysis , 2002, astro-ph/0204083.

[6]  Usa,et al.  Nucleosynthesis in Massive Stars with Improved Nuclear and Stellar Physics , 2001, astro-ph/0112478.

[7]  T. Beers,et al.  Extremely Metal-Poor Stars. VIII. High-Resolution, High Signal-to-Noise Ratio Analysis of Five Stars with [Fe/H] ≲ –3.5 , 2001, astro-ph/0107304.

[8]  F. Terrasi,et al.  The 12C(α, γ)16O Reaction Rate and the Evolution of Stars in the Mass Range 0.8 ≤ M/M☉ ≤ 25 , 2001, astro-ph/0107172.

[9]  O. Gerhard,et al.  Implications of O and Mg abundances in metal-poor halo stars for stellar iron yields , 2001, astro-ph/0107153.

[10]  F. Matteucci,et al.  On the Typical Timescale for the Chemical Enrichment from Type Ia Supernovae in Galaxies , 2001, astro-ph/0105074.

[11]  K. Nomoto,et al.  Nucleosynthesis of Zinc and Iron Peak Elements in Population III Type II Supernovae: Comparison with Abundances of Very Metal Poor Halo Stars , 2001, astro-ph/0103241.

[12]  C. Martin,et al.  Star Formation Thresholds in Galactic Disks , 2001, astro-ph/0103181.

[13]  C. Chiappini,et al.  Abundance Gradients and the Formation of the Milky Way , 2001, astro-ph/0102134.

[14]  Andreu Alibés,et al.  Galactic chemical abundance evolution in the solar neighborhood up to the iron peak , 2000, astro-ph/0012505.

[15]  J. Fulbright Abundances and Kinematics of Field Halo and Disk Stars. I. Observational Data and Abundance Analysis , 2000, astro-ph/0006260.

[16]  Koichi Iwamoto,et al.  Nucleosynthesis in Chandrasekhar Mass Models for Type Ia Supernovae and Constraints on Progenitor Systems and Burning-Front Propagation , 1999 .

[17]  G. Hensler The Evolution of the Milky way , 1999 .

[18]  A. Stephens The Chemical Composition of Halo Stars on Extreme Orbits , 1999 .

[19]  F. Ferrini,et al.  Galactic Chemical Evolution of Heavy Elements: From Barium to Europium , 1999, astro-ph/9903451.

[20]  John E. Norris,et al.  Estimation of Stellar Metal Abundance. II. A Recalibration of the Ca II K Technique, and the Autocorrelation Function Method , 1999 .

[21]  T. Beers,et al.  The Earliest Phases of Galaxy Evolution , 1998, astro-ph/9810422.

[22]  A. Burrows,et al.  Nucleosynthesis in Type II Supernovae and the Abundances in Metal-poor Stars , 1998, astro-ph/9809307.

[23]  N. Grevesse,et al.  Standard Solar Composition , 1998 .

[24]  M. Valle,et al.  On the evolution of the cosmic supernova rates , 1998, astro-ph/9803284.

[25]  Jr.,et al.  The Global Schmidt law in star forming galaxies , 1997, astro-ph/9712213.

[26]  J. S. Wright,et al.  Discovery of an "alpha" Element-Poor Halo Star in a Search for Very Low- Metallicity Disk Stars , 1997 .

[27]  T. Beers,et al.  Extremely Metal-Poor Stars. II. Elemental Abundances and the Early Chemical Enrichment of The Galaxy , 1996 .

[28]  M. Groenewegen,et al.  New theoretical yields of intermediate mass stars , 1996, astro-ph/9610030.

[29]  C. Chiappini,et al.  The Chemical Evolution of the Galaxy: The Two-Infall Model , 1996, astro-ph/9609199.

[30]  B. Pagel,et al.  Chemical evolution of primary elements in the Galactic disc: an analytical model , 1995 .

[31]  S. Woosley,et al.  The Evolution and Explosion of Massive Stars. II. Explosive Hydrodynamics and Nucleosynthesis , 1995 .

[32]  J. Silk,et al.  The First Generation of Stars: First Steps toward Chemical Evolution of Galaxies , 1995, astro-ph/9508040.

[33]  M. Bessell,et al.  Subdwarf studies. IV - Abundance ratios in extremely metal-deficient stars , 1991 .

[34]  R. Kennicutt The Star Formation Law in Galactic Disks , 1989 .

[35]  P. François,et al.  Galactic chemical evolution: abundance gradients of individual elements , 1989 .

[36]  C. Sneden,et al.  Abundances of neutron capture elements in population II stars , 1988 .

[37]  M. Reid,et al.  The distance to the center of the Galaxy , 1987 .

[38]  R. Wyse,et al.  The chemical evolution of the Galaxy , 1986, Nature.

[39]  T. Beers,et al.  A Search for Stars of Very Low Metal Abundance. III. UBV Photometry of Metal-weak Candidates , 1985 .

[40]  K. Nomoto,et al.  Accreting white dwarf models for type I supernovae. III. Carbon deflagration supernovae , 1984 .