Chemical evolution models for spiral disks: the Milky Way, M 31, and M 33

AbstractThe planetary nebulae (PNe) of M 31 are receiving considerable attention as probes of its structure and chemical evolution in a galactic environment that is putatively similar to the Milky Way. We have obtained deep spectra for about 30 luminous PNe in M 31’s inner disk and beyond (Rgal < 105 kpc). The entire ensemble of PNe exhibit O/H ~ 2/3 solar with no discernible radial gradient, in stark contrast to the H ii regions of M 31. This suggests that the outer PNe in M 31 formed from a common O-rich ISM at least 5 GY ago. We infer that the outer PNe and the underlying stellar population have little common history in M 31, and that the formation of the O-rich PNe preceded any putative encounter with M 33 ~2–3 Gy ago.

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The AMBRE Project: r-process elements in the Milky Way thin and thick discs

Astronomy and Astrophysics ◽

10.1051/0004-6361/201833782 ◽

2018 ◽

Vol 619 ◽

pp. A143 ◽

Cited By ~ 11

Author(s):

G. Guiglion ◽

P. de Laverny ◽

A. Recio-Blanco ◽

N. Prantzos

Keyword(s):

Chemical Evolution ◽

Milky Way ◽

Element Abundances ◽

Thick Disc ◽

Thin Disc ◽

Solar Metallicity ◽

R Process ◽

Process Elements ◽

Process Element ◽

The Eu

Context. The chemical evolution of neutron capture elements in the Milky Way disc is still a matter of debate. There is a lack of statistically significant catalogues of such element abundances, especially those of the r-process. Aims. We aim to understand the chemical evolution of r-process elements in Milky Way disc. We focus on three pure r-process elements Eu, Gd, and Dy. We also consider a pure s-process element, Ba, in order to disentangle the different nucleosynthesis processes. Methods. We take advantage of high-resolution FEROS, HARPS, and UVES spectra from the ESO archive in order to perform a homogeneous analysis on 6500 FGK Milky Way stars. The chemical analysis is performed thanks to the automatic optimization pipeline GAUGUIN. We present abundances of Ba (5057 stars), Eu (6268 stars), Gd (5431 stars), and Dy (5479 stars). Based on the [α/Fe] ratio determined previously by the AMBRE Project, we chemically characterize the thin and the thick discs, and a metal-rich α-rich population. Results. First, we find that the [Eu/Fe] ratio follows a continuous sequence from the thin disc to the thick disc as a function of the metallicity. Second, in thick disc stars, the [Eu/Ba] ratio is found to be constant, while the [Gd/Ba] and [Dy/Ba] ratios decrease as a function of the metallicity. These observations clearly indicate a different nucleosynthesis history in the thick disc between Eu and Gd–Dy. The [r/Fe] ratio in the thin disc is roughly around +0.1 dex at solar metallicity, which is not the case for Ba. We also find that the α-rich metal-rich stars are also enriched in r-process elements (like thick disc stars), but their [Ba/Fe] is very different from thick disc stars. Finally, we find that the [r/α] ratio tends to decrease with metallicity, indicating that supernovae of different properties probably contribute differently to the synthesis of r-process elements and α-elements. Conclusions. We provide average abundance trends for [Ba/Fe] and [Eu/Fe] with rather small dispersions, and for the first time for [Gd/Fe] and [Dy/Fe]. This data may help to constrain chemical evolution models of Milky Way r- and s-process elements and the yields of massive stars. We emphasize that including yields of neutron-star or black hole mergers is now crucial if we want to quantitatively compare observations to Galactic chemical evolution models.

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The effects of different Type Ia SN yields on Milky Way chemical evolution

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stab293 ◽

2021 ◽

Vol 503 (3) ◽

pp. 3216-3231

Author(s):

Marco Palla

Keyword(s):

Chemical Evolution ◽

White Dwarf ◽

Time Distribution ◽

Milky Way ◽

Massive Stars ◽

Abundance Patterns ◽

Type Ia ◽

Low Metallicity ◽

Explosion Mechanism ◽

Chemical Evolution Model

ABSTRACT We study the effect of different Type Ia SN nucleosynthesis prescriptions on the Milky Way chemical evolution. To this aim, we run detailed one-infall and two-infall chemical evolution models, adopting a large compilation of yield sets corresponding to different white dwarf progenitors (near-Chandrasekar and sub-Chandrasekar) taken from the literature. We adopt a fixed delay time distribution function for Type Ia SNe, in order to avoid degeneracies in the analysis of the different nucleosynthesis channels. We also combine yields for different Type Ia SN progenitors in order to test the contribution to chemical evolution of different Type Ia SN channels. The results of the models are compared with recent LTE and NLTE observational data. We find that ‘classical’ W7 and WDD2 models produce Fe masses and [α/Fe] abundance patterns similar to more recent and physical near-Chandrasekar and sub-Chandrasekar models. For Fe-peak elements, we find that the results strongly depend either on the white dwarf explosion mechanism (deflagration-to-detonation, pure deflagration, double detonation) or on the initial white dwarf conditions (central density, explosion pattern). The comparison of chemical evolution model results with observations suggests that a combination of near-Chandrasekar and sub-Chandrasekar yields is necessary to reproduce the data of V, Cr, Mn and Ni, with different fractions depending on the adopted massive stars stellar yields. This comparison also suggests that NLTE and singly ionized abundances should be definitely preferred when dealing with most of Fe-peak elements at low metallicity.

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Highlights in the Milky Way

Proceedings of the International Astronomical Union ◽

10.1017/s174392131700789x ◽

2017 ◽

Vol 13 (S334) ◽

pp. 298-299 ◽

Cited By ~ 2

Author(s):

Francesca Matteucci ◽

Emanuele Spitoni ◽

Valeria Grisoni

Keyword(s):

Observational Data ◽

Chemical Evolution ◽

Milky Way ◽

Chemical Models ◽

Formation And Evolution

AbstractWe discuss some important topics concerning the chemical evolution of the Milky Way. In particular, we compare the predictions of theoretical chemical models for our Galaxy with the latest observational data in order to derive constraint on the formation and evolution of the various Galactic components.

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Chemical Evolution of the Milky Way Galaxy and its Relevance to Life on Earth

Environmental Management, Sustainable Development and Human Health ◽

10.1201/9780203881255.ch23 ◽

2008 ◽

pp. 265-269

Author(s):

Ahmad Abdelhadi

Keyword(s):

Chemical Evolution ◽

Milky Way ◽

Milky Way Galaxy ◽

Life On Earth

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The AMBRE project: chemical evolution models for the Milky Way thick and thin discs

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stx2201 ◽

2017 ◽

Vol 472 (3) ◽

pp. 3637-3647 ◽

Cited By ~ 33

Author(s):

V. Grisoni ◽

E. Spitoni ◽

F. Matteucci ◽

A. Recio-Blanco ◽

P. de Laverny ◽

...

Keyword(s):

Chemical Evolution ◽

Milky Way

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High-Velocity Clouds and the Local Group

Symposium - International Astronomical Union ◽

10.1017/s0074180900197037 ◽

2004 ◽

Vol 217 ◽

pp. 2-11 ◽

Cited By ~ 1

Author(s):

B. P. Wakker

Keyword(s):

High Velocity ◽

Milky Way ◽

Local Group ◽

Current Data ◽

The Other ◽

Hot Gas ◽

Neutral Gas ◽

Hα Emission ◽

M 31 ◽

High Velocity Clouds

I examine some of the evidence relevant to the idea that high-velocity clouds (HVCs) are gas clouds distributed throughout the Local Group, as proposed by Blitz et al. (1999) and Braun & Burton (1999). This model makes several predictions: a) the clouds have low metallicities; b) there should be no detectable Hα emission; c) analogues near other galaxies should exist; and d) many faint HVCs in the region around M 31 can be found. Low metallicities are indeed found in several HVCs, although they are also expected in several other models. Hα emission detected in most HVCs and, when examined more closely, distant (D>200 kpc) HVCs should be almost fully ionized, implying that most HVCs with H I must lie near the Milky Way. No clear extragalactic analogues have been found, even though the current data appear sensitive enough. The final prediction (d) has not yet been tested. on balance there appears to be no strong evidence for neutral gas clouds distributed throughout the Local Group, but there may be many such clouds within 100 or so kpc from the Milky Way (and M31). on the other hand, some (but not all) of the high-velocity O VI recently discovered may originate in hot gas distributed throughout the Local Group.

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Globular clusters and their link with stellar populations in the Milky Way

Proceedings of the International Astronomical Union ◽

10.1017/s1743921319007361 ◽

2019 ◽

Vol 14 (S351) ◽

pp. 19-23

Author(s):

David Yong

Keyword(s):

Chemical Evolution ◽

Globular Clusters ◽

Milky Way ◽

Star Clusters ◽

Stellar Populations ◽

Chemical Compositions ◽

Chemical Abundance ◽

Chemical Enrichment ◽

Similarities And Differences ◽

Insight Into

AbstractObservations of stellar chemical compositions enable us to identify connections between globular clusters and stellar populations in the Milky Way. In particular, chemical abundance ratios provide detailed insight into the chemical enrichment histories of star clusters and the field populations. For some elements, there are striking differences between field and cluster stars which reflect different nucleosynthetic processes and/or chemical evolution. The goal of this talk was to provide an overview of similarities and differences in chemical compositions between globular clusters and the Milky Way as well as highlighting a few areas for further examination.

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Dark halos of M 31 and the Milky Way

Publications of the Astronomical Society of Japan ◽

10.1093/pasj/psv042 ◽

2015 ◽

Vol 67 (4) ◽

pp. 75 ◽

Cited By ~ 41

Author(s):

Yoshiaki Sofue

Keyword(s):

Milky Way ◽

M 31

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A Comparison of Chemical Evolution between the Milky Way and M31 Galaxy

Proceedings of the International Astronomical Union ◽

10.1017/s1743921306006788 ◽

2006 ◽

Vol 2 (S235) ◽

pp. 313-313

Author(s):

J. Yin ◽

J.L. Hou ◽

R.X. Chang ◽

S. Boissier ◽

N. Prantzos

Keyword(s):

Star Formation ◽

Chemical Evolution ◽

Milky Way ◽

Local Group ◽

Spiral Galaxies ◽

Star Formation History ◽

Milky Way Galaxy ◽

Andromeda Galaxy ◽

Formation History ◽

Formation And Evolution

Andromeda galaxy (M31,NGC224) is the biggest spiral in the Local Group. By studying the star formation history(SFH) and chemical evolution of M31, and comparing with the Milky Way Galaxy, we are able to understand more about the formation and evolution of spiral galaxies.

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