Evolution and CNO yields of<i>Z</i>= 10<sup>-5</sup>stars and possible effects on carbon-enhanced metal-poor production

Gil‐Pons, Pilar; Doherty, Carolyn; Lau, Herbert H. B.; Campbell, Simon; Suda, Takuma; Guilani, S. M.; Gutiérrez, Javier Franch; Lattanzio, John C.

doi:10.1051/0004-6361/201321127

Cited by 34 publications

(89 citation statements)

References 73 publications

(122 reference statements)

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“…In order to model the intricate phase of evolution near the end of carbon burning a time-dependent mixing scheme was required and a diffusion approximation was used, as described in Campbell & Lattanzio (2008) and Gil-Pons et al (2013).…”

Section: Stellar Evolution Programmentioning

confidence: 99%

Super- and massive AGB stars – IV. Final fates – initial-to-final mass relation

Doherty

Gil‐Pons

Siess

et al. 2014

Monthly Notices of the Royal Astronomical Society

224

278

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We explore the final fates of massive intermediate-mass stars by computing detailed stellar models from the zero age main sequence until near the end of the thermally pulsing phase. These super-AGB and massive AGB star models are in the mass range between 5.0 and 10.0 M ⊙ for metallicities spanning the range Z=0.02−0.0001. We probe the mass limits M up , M n and M mass , the minimum masses for the onset of carbon burning, the formation of a neutron star, and the iron core-collapse supernovae respectively, to constrain the white dwarf/electron-capture supernova boundary. We provide a theoretical initial to final mass relation for the massive and ultra-massive white dwarfs and specify the mass range for the occurrence of hybrid CO(Ne) white dwarfs. We predict electron-capture supernova (EC-SN) rates for lower metallicities which are significantly lower than existing values from parametric studies in the literature. We conclude the EC-SN channel (for single stars and with the critical assumption being the choice of mass-loss rate) is very narrow in initial mass, at most ≈ 0.2 M ⊙ . This implies that between ∼ 2−5 per cent of all gravitational collapse supernova are EC-SNe in the metallicity range Z=0.02 to 0.0001. With our choice for mass-loss prescription and computed core growth rates we find, within our metallicity range, that CO cores cannot grow sufficiently massive to undergo a Type 1.5 SN explosion.

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Section: Stellar Evolution Programmentioning

confidence: 99%

Super- and massive AGB stars – IV. Final fates – initial-to-final mass relation

Doherty

Gil‐Pons

Siess

et al. 2014

Monthly Notices of the Royal Astronomical Society

224

278

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“…In this work the solar metallicity is set to Z = 0.02. Gil-Pons et al (2013) (see Table 2). Some more recent library of massive stars yields are currently available (e.g.…”

Section: The Chemodynamical Modelmentioning

confidence: 99%

“…bin in our chemodynamical model. We use stellar evolution models from Campbell & Lattanzio (2008) and Gil-Pons et al (2013) for LIMS and from Heger & Woosley (2010) for MS. The instantaneous ejecta rate is given by Eq.…”

Section: Metal-free Primordial Interstellar Mediummentioning

confidence: 99%

Metal enrichment in a semi-analytical model, fundamental scaling relations, and the case of Milky Way galaxies

Cousin

Buat

Boissier

et al. 2016

A&A

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Context. Gas flows play a fundamental role in galaxy formation and evolution, providing the fuel for the star formation process. These mechanisms leave an imprint in the amount of heavy elements that enrich the interstellar medium. Thus, the analysis of this metallicity signature provides additional constraint on the galaxy formation scenario. Aims. We aim to discriminate between four different galaxy formation models based on two accretion scenarios and two different star formation recipes. We address the impact of a bimodal accretion scenario and a strongly regulated star formation recipe on the metal enrichment process of galaxies. Methods. We present a new extension of the eGalICS model, which allows us to track the metal enrichment process in both stellar populations and in the gas phase. Based on stellar metallicity bins from 0 to 2.5 Z , our new chemodynamical model is applicable for situations ranging from metal-free primordial accretion to very enriched interstellar gas contents. We use this new tool to predict the metallicity evolution of both the stellar populations and gas phase. We compare these predictions with recent observational measurements. We also address the evolution of the gas metallicity with the star formation rate (SFR). We then focus on a subsample of Milky Way-like galaxies. We compare both the cosmic stellar mass assembly and the metal enrichment process of such galaxies with observations and detailed chemical evolution models. Results. Our models, based on a strong star formation regulation, allow us to reproduce well the stellar mass to gas-phase metallicity relation observed in the local Universe. The shape of our average stellar mass to stellar metallicity relations is in good agreement with observations. However, we observe a systematic shift towards high masses. Our M −Z g −SFR relation is in good agreement with recent measurements: our best model predicts a clear dependence with the SFR. Both SFR and metal enrichment histories of our Milky Way-like galaxies are consistent with observational measurements and detailed chemical evolution models. We finally show that Milky Way progenitors start their evolution below the observed main sequence and progressively reach this observed relation at z 0.

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“…The SDU is deeper than the FDU in every model with FDU, and the depth of the SDU decreases with increasing He abundance. However, due to the increased core mass in the 6 M model with Y = 0.40, a "corrosive SDU" takes place (Gil-Pons et al 2013;Doherty et al 2014). In this model, the inner edge of the convective envelope reaches below the top of the CO core, which dredges up C and O to the surface.…”

Section: The First and Second Dredge-upmentioning

confidence: 99%

Evolution and nucleosynthesis of helium-rich asymptotic giant branch models

Shingles

Doherty

Karakas

et al. 2015

Mon. Not. R. Astron. Soc.

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There is now strong evidence that some stars have been born with He mass fractions as high as Y ≈ 0.40 (e.g., in ω Centauri). However, the advanced evolution, chemical yields, and final fates of He-rich stars are largely unexplored. We investigate the consequences of He-enhancement on the evolution and nucleosynthesis of intermediatemass asymptotic giant branch (AGB) models of 3, 4, 5, and 6 M with a metallicity of Z = 0.0006 ([Fe/H] ≈ −1.4). We compare models with He-enhanced compositions (Y = 0.30, 0.35, 0.40) to those with primordial He (Y = 0.24). We find that the minimum initial mass for C burning and super-AGB stars with CO(Ne) or ONe cores decreases from above our highest mass of 6 M to ∼ 4-5 M with Y = 0.40. We also model the production of trans-Fe elements via the slow neutron-capture process (s-process). He-enhancement substantially reduces the third dredge-up efficiency and the stellar yields of s-process elements (e.g., 90% less Ba for 6 M , Y = 0.40). An exception occurs for 3 M , where the near-doubling in the number of thermal pulses with Y = 0.40 leads to ∼ 50% higher yields of Ba-peak elements and Pb if the 13 C neutron source is included. However, the thinner intershell and increased temperatures at the base of the convective envelope with Y = 0.40 probably inhibit the 13 C neutron source at this mass. Future chemical evolution models with our yields might explain the evolution of s-process elements among He-rich stars in ω Centauri.

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Evolution and CNO yields ofZ= 10^-5stars and possible effects on carbon-enhanced metal-poor production

Cited by 34 publications

References 73 publications

Super- and massive AGB stars – IV. Final fates – initial-to-final mass relation

Super- and massive AGB stars – IV. Final fates – initial-to-final mass relation

Metal enrichment in a semi-analytical model, fundamental scaling relations, and the case of Milky Way galaxies

Evolution and nucleosynthesis of helium-rich asymptotic giant branch models

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Evolution and CNO yields ofZ= 10-5stars and possible effects on carbon-enhanced metal-poor production

Cited by 34 publications

References 73 publications

Super- and massive AGB stars – IV. Final fates – initial-to-final mass relation

Super- and massive AGB stars – IV. Final fates – initial-to-final mass relation

Metal enrichment in a semi-analytical model, fundamental scaling relations, and the case of Milky Way galaxies

Evolution and nucleosynthesis of helium-rich asymptotic giant branch models

Contact Info

Product

Resources

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Evolution and CNO yields ofZ= 10^-5stars and possible effects on carbon-enhanced metal-poor production