First stars V - Abundance patterns from C to Zn and supernova yields in the early Galaxy

AbstractAfter the Big Bang, production of heavy elements in the early Universe takes place in the first stars and their supernova explosions. The nature of the first supernovae, however, has not been well understood. The signature of nucleosynthesis yields of the first supernovae can be seen in the elemental abundance patterns observed in extremely metal-poor stars. Interestingly, those abundance patterns show some peculiarities relative to the solar abundance pattern, which should provide important clues to understanding the nature of early generations of supernovae. We review the recent results of the nucleosynthesis yields of massive stars. We examine how those yields are affected by some hydrodynamical effects during the supernova explosions, namely, explosion energies from those of hypernovae to faint supernovae, mixing and fallback of processed materials, asphericity, etc. Those parameters in the supernova nucleosynthesis models are constrained from observational data of supernovae and metal-poor stars.

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Study of the Abundance Patterns in the Metal-Poor Stellar Stream

Publications of the Astronomical Society of Australia ◽

10.1017/pasa.2012.015 ◽

2013 ◽

Vol 30 ◽

Cited By ~ 1

Author(s):

Hongjie Li ◽

Shuai Liang ◽

Wenyuan Cui ◽

Bo Zhang

Keyword(s):

Gradual Increase ◽

Type Ii ◽

Constant Mass ◽

Chemical Abundances ◽

Abundance Patterns ◽

The Difference ◽

The Masses ◽

Process Component ◽

Process Elements ◽

Early Galaxy

AbstractThe chemical abundances of the metal-poor stars in the stellar stream provide important information for setting constraints on models of neutron-capture processes. The study of these stars could gives us a better understanding of the r-process nucleosynthesis and chemical composition of the early Galaxy. Using the updated main r-process and weak r-process patterns, we fit abundances in the stellar stream stars. The weak r-process component coefficients are almost constant for the sample stars, including r-rich stars, which means that both the weak r-process and Fe are produced as primary elements from Type II supernovae and their yields have nearly a constant mass fraction. The difference between the stream stars and r-rich stars is obvious. For the stream stars, the fact that the increased trend in the main r-process component coefficients as metallicity increases means a gradual increase in the production of main r-process elements relative to iron. This behaviour implies that the masses of progenitors for the main r-process are smaller than those of the weak r-process. Furthermore, we find that the metal-poor stream star HD 237846 is a weak r-process star.

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Stellar Archaeology: Using Metal-Poor Stars to Test Theories of the Early Universe

Proceedings of the International Astronomical Union ◽

10.1017/s1743921308025039 ◽

2008 ◽

Vol 4 (S255) ◽

pp. 336-340

Author(s):

Anna Frebel ◽

Jarrett L. Johnson ◽

Volker Bromm

Keyword(s):

Fine Structure ◽

Low Mass Stars ◽

First Stars ◽

Abundance Patterns ◽

Cosmological Context ◽

Different Types ◽

The Galaxy ◽

Structure Line ◽

History Of ◽

Low Mass

AbstractConstraints on the chemical yields of the first stars and supernova can be derived by examining the abundance patterns of different types of metal-poor stars. We show how metal-poor stars are employed to derive constraints of the formation of the first low-mass stars by testing a fine-structure line cooling theory. The concept of stellar archaeology, that stellar abundances truly reflect the chemical composition of the earliest times, is then addressed. The accretion history of a sample of metal-poor stars is examined in detail in a cosmological context, and found to have no impact on the observed abundances. Predictions are made for the lowest possible Fe and Mg abundances observable in the Galaxy, [Fe/H]min = −7.5 and [Mg/H]min = −5.5. The absence of stars below these values is so far consistent with a top-heavy IMF. These predictions are directly relevant for future surveys and the next generation of telescopes.

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First stars, hypernovae, and superluminous supernovae

International Journal of Modern Physics D ◽

10.1142/s0218271816300251 ◽

2016 ◽

Vol 25 (10) ◽

pp. 1630025

Author(s):

Ken’ichi Nomoto

Keyword(s):

Early Universe ◽

Big Bang ◽

Elemental Abundance ◽

Heavy Elements ◽

Relativistic Jets ◽

First Stars ◽

Evolution Of Galaxies ◽

Abundance Patterns ◽

The Big Bang

After the big bang, production of heavy elements in the early universe takes place starting from the formation of the first (Pop III) stars, their evolution, and explosion. The Pop III supernova (SN) explosions have strong dynamical, thermal, and chemical feedback on the formation of subsequent stars and evolution of galaxies. However, the nature of Pop III stars/supernovae (SNe) have not been well-understood. The signature of nucleosynthesis yields of the first SN can be seen in the elemental abundance patterns observed in extremely metal-poor (EMP) stars. We show that the abundance patterns of EMP stars, e.g. the excess of C, Co, Zn relative to Fe, are in better agreement with the yields of hyper-energetic explosions (Hypernovae, (HNe)) rather than normal supernovae. We note the large variation of the abundance patterns of EMP stars propose that such a variation is related to the diversity of the GRB-SNe and posssibly superluminous supernovae (SLSNe). For example, the carbon-enhanced metal-poor (CEMP) stars may be related to the faint SNe (or dark HNe), which could be the explosions induced by relativistic jets. Finally, we examine the various mechanisms of SLSNe.

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Halo chemistry and first stars. The chemical composition of the matter in the early Galaxy, from C to Mg

Proceedings of the International Astronomical Union ◽

10.1017/s1743921308027804 ◽

2008 ◽

Vol 4 (S254) ◽

pp. 349-354

Author(s):

M. Spite ◽

P. Bonifacio ◽

R. Cayrel ◽

F. Spite ◽

P. Francois ◽

...

Keyword(s):

Chemical Composition ◽

Large Scatter ◽

First Stars ◽

Early Galaxy

AbstractFrom NLTE computations of the magnesium abundance in a sample of extremely metal-poor giants we derive [Mg/Fe]=+0.7, leading to [Al/Mg]=−0.80 and [Na/Mg]=−0.85 in the early Galaxy. The ratio [O/Mg] should be near to the solar value. Measurements of nitrogen abundances derived from the analysis of the NH band in eight more stars confirm the large scatter of the ratios [N/Fe] and [N/O] in the early Galaxy.

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First Stars – Type Ib Supernovae Connection

Proceedings of the International Astronomical Union ◽

10.1017/s1743921308024794 ◽

2008 ◽

Vol 4 (S255) ◽

pp. 182-188

Author(s):

Ken'ichi Nomoto ◽

Masaomi Tanaka ◽

Yasuomi Kamiya ◽

Nozomu Tominaga ◽

Keiichi Maeda

Keyword(s):

Kinetic Energy ◽

Main Sequence ◽

Gamma Ray ◽

Gamma Ray Bursts ◽

Core Collapse ◽

First Stars ◽

X Ray ◽

Chemical Enrichment ◽

Abundance Patterns ◽

Normal Core

AbstractThe very peculiar abundance patterns observed in extremely metal-poor (EMP) stars can not be explained by conventional normal supernova nucleosynthesis but can be well-reproduced by nucleosynthesis in hyper-energetic and hyper-aspherical explosions, i.e., Hypernovae (HNe). Previously, such HNe have been observed only as Type Ic supernovae. Here, we examine the properties of recent Type Ib supernovae (SNe Ib). In particular, SN Ib 2008D associated with the luminous X-ray transient 080109 is found to be a more energetic explosion than normal core-collapse supernovae. We estimate that the progenitor's main sequence mass is MMS = 20 − 25M⊙ with an explosion of kinetic energy of EK ~ 6.0 × 1051 erg. These properties are intermediate between those of normal SNe and hypernovae associated with gamma-ray bursts. Therefore, such energetic SNe Ib could also make an important contribution to the chemical enrichment in the early Universe.

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Abundance Patterns Among Very Metal-Poor Stars in the Halo of the Galaxy: A Statistical Approach

Proceedings of the International Astronomical Union ◽

10.1017/s1743921310003479 ◽

2009 ◽

Vol 5 (S262) ◽

pp. 412-413

Author(s):

Vinicius M. Placco ◽

Silvia Rossi ◽

Timothy C. Beers ◽

Sara Lucatello

Keyword(s):

Neutron Capture ◽

Statistical Approach ◽

Chemical Elements ◽

Comprehensive Analysis ◽

Elemental Abundances ◽

Abundance Patterns ◽

The Galaxy ◽

R Process ◽

Early Galaxy ◽

Natural Groups

AbstractThe main goal of this work is to explore the abundance patterns of the very metal-poor stars ([Fe/H]<−2.0) observed by the HERES (Hamburg ESO R-process Enhanced Star - Christlieb et al. 2004) survey. This type of study allows the analysis of the correlations among chemical elements, and place some constraints on the operation of the neutron-capture (r and s) processes in the early Galaxy. This approach makes use of statistical tools, such as agglomerative nesting, which can identify the formation of natural groups based on relations among elemental abundances (e.g. [C/Fe], [Sr/Fe], [Ba/Fe], and [Eu/Fe]), and can also be used in a series of “large-sample like” studies.This study provides a comprehensive analysis of a sample of 326 metal-poor stars, and introduces two new subclasses (r-0 and s-I) for metal-poor stars with determined abundances of neutron-capture elements, aiming to standardize the nomenclature for those objects and, by reproducing previous results, confirms the validity of the statistical method used.

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Reviving old controversies: is the early Galaxy flat or round?

Astronomy and Astrophysics ◽

10.1051/0004-6361/201937016 ◽

2020 ◽

Vol 636 ◽

pp. A115 ◽

Cited By ~ 3

Author(s):

P. Di Matteo ◽

M. Spite ◽

M. Haywood ◽

P. Bonifacio ◽

A. Gómez ◽

...

Keyword(s):

Stellar Population ◽

Milky Way ◽

Galactic Disc ◽

Chemical Abundances ◽

First Stars ◽

Thick Disc ◽

Large Program ◽

The Galaxy ◽

Early Galaxy ◽

Two Populations

We analysed a set of very metal-poor stars, for which accurate chemical abundances have been obtained as part of the ESO Large Program “First stars” in the light of the Gaia DR2 data. The kinematics and orbital properties of the stars in the sample show they probably belong to the thick disc, partially heated to halo kinematics, and to the accreted Gaia Sausage-Enceladus satellite. The continuity of these properties with stars at both higher ([Fe/H] > −2) and lower metallicities ([Fe/H] < −4.) suggests that the Galaxy at [Fe/H] ≲ −0.5 and down to at least [Fe/H] ∼ −6 is dominated by these two populations. In particular, we show that the disc extends continuously from [Fe/H] ≤ −4 (where stars with disc-like kinematics have recently been discovered) up to [Fe/H] ≥ −2, the metallicity regime of the Galactic thick disc. An “ultra metal-poor thick disc” does indeed exist, constituting the extremely metal-poor tail of the canonical Galactic thick disc, and extending the latter from [Fe/H] ∼ −0.5 up to the most metal-poor stars discovered in the Galaxy to date. These results suggest that the disc may be the main, and possibly the only, stellar population that has formed in the Galaxy at these metallicities. This would mean that the dissipative collapse that led to the formation of the old Galactic disc must have been extremely fast. We also discuss these results in the light of recent simulation efforts made to reproduce the first stages of Milky Way-type galaxies.

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Mono-enriched stars and Galactic chemical evolution

Astronomy and Astrophysics ◽

10.1051/0004-6361/202038805 ◽

2020 ◽

Vol 643 ◽

pp. A49

Author(s):

C. J. Hansen ◽

A. Koch ◽

L. Mashonkina ◽

M. Magg ◽

M. Bergemann ◽

...

Keyword(s):

Chemical Evolution ◽

Second Generation ◽

Asymptotic Giant Branch ◽

Three Dimensional Model ◽

First Stars ◽

Abundance Pattern ◽

Abundance Patterns ◽

The Galaxy ◽

Bona Fide ◽

R Process

A long sought after goal using chemical abundance patterns derived from metal-poor stars is to understand the chemical evolution of the Galaxy and to pin down the nature of the first stars (Pop III). Metal-poor, old, unevolved stars are excellent tracers as they preserve the abundance pattern of the gas from which they were born, and hence they are frequently targeted in chemical tagging studies. Here, we use a sample of 14 metal-poor stars observed with the high-resolution spectrograph called the Potsdam Echelle Polarimetric and Spectroscopic Instrument (PEPSI) at the Large Binocular Telescope (LBT) to derive abundances of 32 elements (34 including upper limits). We present well-sampled abundance patterns for all stars obtained using local thermodynamic equilibrium (LTE) radiative transfer codes and one-dimensional (1D) hydrostatic model atmospheres. However, it is currently well-known that the assumptions of 1D and LTE may hide several issues, thereby introducing biases in our interpretation as to the nature of the first stars and the chemical evolution of the Galaxy. Hence, we use non-LTE (NLTE) and correct the abundances using three-dimensional model atmospheres to present a physically more reliable pattern. In order to infer the nature of the first stars, we compare unevolved, cool stars, which have been enriched by a single event (“mono-enriched”), with a set of yield predictions to pin down the mass and energy of the Pop III progenitor. To date, only few bona fide second generation stars that are mono-enriched are known. A simple χ2-fit may bias our inferred mass and energy just as much as the simple 1D LTE abundance pattern, and we therefore carried out our study with an improved fitting technique considering dilution and mixing. Our sample presents Carbon Enhanced Metal-Poor (CEMP) stars, some of which are promising bona fide second generation (mono-enriched) stars. The unevolved, dwarf BD+09_2190 shows a mono-enriched signature which, combined with kinematical data, indicates that it moves in the outer halo and likely has been accreted onto the Milky Way early on. The Pop III progenitor was likely of 25.5 M⊙ and 0.6 foe (0.6 1051 erg) in LTE and 19.2 M⊙ and 1.5 foe in NLTE, respectively. Finally, we explore the predominant donor and formation site of the rapid and slow neutron-capture elements. In BD-10_3742, we find an almost clean r-process trace, as is represented in the star HD20, which is a “metal-poor Sun benchmark” for the r-process, while TYC5481-00786-1 is a promising CEMP-r/-s candidate that may be enriched by an asymptotic giant branch star of an intermediate mass and metallicity.

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