Kinematics and chemical properties of the Galactic stellar populations

Adibekyan, V.; Figueira, P.; Santos, N. C.; Hakobyan, A. A.; Sousa, S. G.; Pace, G.; Delgado-Mena, E.; Robin, A. C.; Israelian, G.; Hernández, J. I. González

doi:10.1051/0004-6361/201321520

Cited by 158 publications

(253 citation statements)

References 64 publications

(161 reference statements)

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“…This result is in agreement with previous studies, (e.g. Adibekyan et al 2013;Bensby et al 2014;Nidever et al 2014, most recently); see also Bensby et al (2007), Kordopatis et al (2013bKordopatis et al ( , 2015 for further evidence of metal-rich, thick-disc stars, defined kinematically. We find that the dispersion in [Mg/Fe] at fixed iron abundance for thick-disc stars is marginally smaller than the values derived for thin-disc stars.…”

Section: The High-metallicity Extent Of the Thick Discsupporting

confidence: 93%

“…This overlap in metallicity was already suggested from the α-abundance trends derived from very high-resolution studies of stars in the immediate solar neighbourhood (d < 100 pc; e.g. Reddy et al 2006;Adibekyan et al 2013;Bensby et al 2014;Nissen 2015), and by Nidever et al (2014) for stars in a wide range of Galactic radii (0 R 15 kpc). We can further assess the presence of thin-disc stars below [Fe/H] = −0.5 dex by making a rough separation of the stars within a given [Fe/H] bin into either high-α ([Mg/Fe] > 0.3 dex) or low-α ([Mg/Fe] < 0.2 dex, see also Sect.…”

Section: Azimuthal Velocity Componentsupporting

confidence: 54%

“…The top, middle, and bottom rows show the Gaia-ESO iDR2 results for the inner Galaxy, solar suburb and outer Galaxy, respectively. The over-plotted grey points in the panel 7.5 < R < 8.5 kpc and 0 < |Z| < 1 kpc are the α-abundance measurements of Adibekyan et al (2013), obtained for a very local sample (d 150 pc). No significant differences in the derived trends are found as a function of S/N, which is indicative of the robustness of our fitting method.…”

Section: Tests On Mock Datamentioning

confidence: 99%

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TheGaia-ESO Survey: characterisation of the [α/Fe] sequences in the Milky Way discs

Kordopatis

Wyse

Gilmore

et al. 2015

A&A

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Context. High-resolution spectroscopic surveys of stars indicate that the Milky Way thin and thick discs follow different paths in the chemical space defined by [α/Fe] vs. [Fe/H], possibly suggesting different formation mechanisms for each of these structures. Aims. We investigate, using the Gaia-ESO Survey internal Data-Release 2, the properties of the double sequence of the Milky Way discs, which are defined chemically as the high-α and low-α populations. We discuss their compatibility with discs defined by other means, such as metallicity, kinematics, or positions. Methods. This investigation uses two different approaches: in velocity space, for stars located in the extended solar neighbourhood; and, in chemical space, for stars at different ranges of Galactocentric radii and heights from the Galactic mid-plane. The separation we find in velocity space allows us to investigate, using a novel approach, the extent of metallicity of each of the two chemical sequences, without making any assumption about the shape of their metallicity distribution functions. Then, using the separation in chemical space, adopting the magnesium abundance as a tracer of the α-elements, we characterise the spatial variation of the slopes of the [α/Fe]−[Fe/H] sequences for the thick and thin discs and the way in which the relative proportions of the two discs change across the Galaxy. Results. We find that the thick disc, defined as the stars tracing the high-α sequence, extends up to super-solar metallicities ([Fe/H] ≈ +0.2 dex), and the thin disc, defined as the stars tracing the low-α sequence, extends at least down to [Fe/H] ≈ −0.8 dex, with hints pointing towards even lower values. Radial and vertical gradients in α-abundances are found for the thin disc, with mild spatial variations in its [α/Fe]−[Fe/H] paths, whereas for the thick disc we do not detect any spatial variations of this kind. This is in agreement with results obtained recently from other high-resolution spectroscopic surveys. Conclusions. The small variations in the spatial [α/Fe]−[Fe/H] paths of the thin disc do not allow us to distinguish between formation models of this structure. On the other hand, the lack of radial gradients and [α/Fe]−[Fe/H] variations for the thick disc indicate that the mechanism responsible for the mixing of metals in the young Galaxy (e.g. radial stellar migration or turbulent gaseous disc) was more efficient before the (present) thin disc started forming.

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Section: The High-metallicity Extent Of the Thick Discsupporting

confidence: 93%

Section: Azimuthal Velocity Componentsupporting

confidence: 54%

Section: Tests On Mock Datamentioning

confidence: 99%

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TheGaia-ESO Survey: characterisation of the [α/Fe] sequences in the Milky Way discs

Kordopatis

Wyse

Gilmore

et al. 2015

A&A

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“…A similar behaviour is observable for Galactic field stars where the older thin and thick disc field dwarfs from Bensby et al (2014) yield more positive [α/Fe] ratios than the younger field dwarfs with thin disc kinematics. The similarity in [α/Fe] between the thin and thick disc clusters with ages of 4 to 9 Gyr suggest that age cannot be the key variable, but different proportions of Type II to Type Ia supernovae products in clusters formed at dif- Adibekyan et al 2013;Bensby et al 2014). Although the origin of such objects is still in debate, Adibekyan et al (2011Adibekyan et al ( , 2013 have suggested a possible origin of these α-enhanced metal-rich stars in the inner Galaxy (bulge) followed by a subsequent migration to the solar vicinity.…”

Section: [α/Fe] Vs Cluster's Agementioning

confidence: 99%

The evolution of the Milky Way: new insights from open clusters

Reddy¹,

Lambert²,

Giridhar³

2016

Mon. Not. R. Astron. Soc.

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We have collected high-dispersion echelle spectra of red giant members in the twelve open clusters (OCs) and derived stellar parameters and chemical abundances for 26 species by either line equivalent widths or synthetic spectrum analyses. We confirm the lack of an age−metallicity relation for OCs but argue that such a lack of trend for OCs arise from the limited coverage in metallicity compared to that of field stars which span a wide range in metallicity and age. We confirm that the radial metallicity gradient of OCs is steeper (flatter) for R gc < 12 kpc (>12 kpc). We demonstrate that the sample of clusters constituting a steep radial metallicity gradient of slope −0.052±0.011 dex kpc −1 at R gc < 12 kpc are younger than 1.5 Gyr and located close to the Galactic midplane (| z| < 0.5 kpc) with kinematics typical of the thin disc. Whereas the clusters describing a shallow slope of −0.015±0.007 dex kpc −1 at R gc > 12 kpc are relatively old, thick disc members with a striking spread in age and height above the midplane (0.5 < | z| < 2.5 kpc). Our investigation reveals that the OCs and field stars yield consistent radial metallicity gradients if the comparison is limited to samples drawn from the similar vertical heights. We argue via the computation of Galactic orbits that all the outer disc clusters were actually born inward of 12 kpc but the orbital eccentricity has taken them to present locations very far from their birthplaces.

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“…This model needs to be improved to account also for the gap in the [α/Fe]-[Fe/H] relation seen for a long time in high-resolution spectroscopic data in the solar vicinity (e.g., Adibekyan et al 2013;Bensby et al 2013;Fuhrmann 2004) and more recently found in a range of Galactic radii using APOGEE data (Anders et al 2014;Nidever et al 2014). This separation into low-and high-[α/Fe] sequences (sometime referred to as the thin and thick discs) 8 is most likely the result of a gap in the SFH at high redshift, as first suggested in the Two-Infall Model by Chiappini et al (1997).…”

Section: Comparison With Observationsmentioning

confidence: 99%

Constraining the Milky Way assembly history with Galactic Archaeology

Minchev

2016

Astron Nachr

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The aim of Galactic Archaeology is to recover the evolutionary history of the Milky Way from its present day kinematical and chemical state. Because stars move away from their birth sites, the current dynamical information alone is not sufficient for this task. The chemical composition of stellar atmospheres, on the other hand, is largely preserved over the stellar lifetime and, together with accurate ages, can be used to recover the birthplaces of stars currently found at the same Galactic radius. In addition to the availability of large stellar samples with accurate 6D kinematics and chemical abundance measurements, this requires detailed modeling with both dynamical and chemical evolution taken into account. An important first step is to understand the variety of dynamical processes that can take place in the Milky Way, including the perturbative effects of both internal (bar and spiral structure) and external (infalling satellites) agents. We discuss here (1) how to constrain the Galactic bar, spiral structure, and merging satellites by their effect on the local and global disc phase-space, (2) the effect of multiple patterns on the disc dynamics, and (3) the importance of radial migration and merger perturbations for the formation of the Galactic thick disc. Finally, we discuss the construction of Milky Way chemo-dynamical models and relate to observations.

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Kinematics and chemical properties of the Galactic stellar populations

Cited by 158 publications

References 64 publications

TheGaia-ESO Survey: characterisation of the [α/Fe] sequences in the Milky Way discs

TheGaia-ESO Survey: characterisation of the [α/Fe] sequences in the Milky Way discs

The evolution of the Milky Way: new insights from open clusters

Constraining the Milky Way assembly history with Galactic Archaeology

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