Chronologically dating the early assembly of the Milky Way

Josefina Montalbán; John Ted Mackereth; Andrea Miglio; Fiorenzo Vincenzo; Cristina Chiappini; Gaël Buldgen; Benoît Mosser; Arlette Noels; Richard Scuflaire; Mathieu Vrard; Emma Willett; Guy R. Davies; Oliver Hall; Martin Bo Nielsen; Saniya Khan; Ben M. Rendle; Walter E. van Rossem; Jason W. Ferguson; William J. Chaplin

doi:10.1038/s41550-021-01347-7

Chronologically dating the early assembly of the Milky Way

Josefina Montalbán, John Ted Mackereth, Andrea Miglio, Fiorenzo Vincenzo, Cristina Chiappini, Gaël Buldgen, Benoît Mosser, Arlette Noels, Richard Scuflaire, Mathieu Vrard, Emma Willett, Guy R. Davies, Oliver Hall, Martin Bo Nielsen, Saniya Khan, Ben M. Rendle, Walter E. van Rossem, Jason W. Ferguson, William J. Chaplin

Physics and Astronomy

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Abstract

The standard cosmological model predicts that galaxies are built through hierarchical assembly on cosmological timescales^1,2. The Milky Way, like other disk galaxies, underwent violent mergers and accretion of small satellite galaxies in its early history. Owing to Gaia Data Release 2³ and spectroscopic surveys⁴, the stellar remnants of such mergers have been identified^5,6,7. The chronological dating of such events is crucial to uncover the formation and evolution of the Galaxy at high redshift, but it has so far been challenging due to difficulties in obtaining precise ages for these oldest stars. Here we combine asteroseismology—the study of stellar oscillations—with kinematics and chemical abundances to estimate precise stellar ages (~11%) for a sample of stars observed by the Kepler space mission⁸. Crucially, this sample includes not only some of the oldest stars that were formed inside the Galaxy but also stars formed externally and subsequently accreted onto the Milky Way. Leveraging this resolution in age, we provide compelling evidence in favour of models in which the Galaxy had already formed a substantial population of its stars (which now reside mainly in its thick disk) before the infall of the satellite galaxy Gaia-Enceladus/Sausage^5,6around 10 billion years ago.

Original language	English
Pages (from-to)	640-647
Journal	Nature Astronomy
Volume	5
Issue number	7
Early online date	17 May 2021
DOIs	https://doi.org/10.1038/s41550-021-01347-7
Publication status	E-pub ahead of print - 17 May 2021

Bibliographical note

Updated with the final version accepted for publication as a Letter in Nature Astronomy (29 pages, 10 figures, 2 tables, including main article and methods section). Improved presentation of results, which have not changed from the previous version

Keywords

astro-ph.GA
astro-ph.SR

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MontalbánJ2021Chronologically
Montalbán, J., Mackereth, J.T., Miglio, A. et al. Chronologically dating the early assembly of the Milky Way. Nat Astron (2021). https://doi.org/10.1038/s41550-021-01347-7 This document is subject to Springer Nature re-use terms: https://www.nature.com/nature-portfolio/editorial-policies/self-archiving-and-license-to-publish#AAMtermsV1
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Montalbán, J., Mackereth, J. T., Miglio, A., Vincenzo, F., Chiappini, C., Buldgen, G., Mosser, B., Noels, A., Scuflaire, R., Vrard, M., Willett, E., Davies, G. R., Hall, O., Nielsen, M. B., Khan, S., Rendle, B. M., Rossem, W. E. V., Ferguson, J. W., & Chaplin, W. J. (2021). Chronologically dating the early assembly of the Milky Way. Nature Astronomy, 5(7), 640-647. Advance online publication. https://doi.org/10.1038/s41550-021-01347-7

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title = "Chronologically dating the early assembly of the Milky Way",

abstract = "The standard cosmological model predicts that galaxies are built through hierarchical assembly on cosmological timescales1,2. The Milky Way, like other disk galaxies, underwent violent mergers and accretion of small satellite galaxies in its early history. Owing to Gaia Data Release 23 and spectroscopic surveys4, the stellar remnants of such mergers have been identified5,6,7. The chronological dating of such events is crucial to uncover the formation and evolution of the Galaxy at high redshift, but it has so far been challenging due to difficulties in obtaining precise ages for these oldest stars. Here we combine asteroseismology—the study of stellar oscillations—with kinematics and chemical abundances to estimate precise stellar ages (~11%) for a sample of stars observed by the Kepler space mission8. Crucially, this sample includes not only some of the oldest stars that were formed inside the Galaxy but also stars formed externally and subsequently accreted onto the Milky Way. Leveraging this resolution in age, we provide compelling evidence in favour of models in which the Galaxy had already formed a substantial population of its stars (which now reside mainly in its thick disk) before the infall of the satellite galaxy Gaia-Enceladus/Sausage5,6 around 10 billion years ago.",

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author = "Josefina Montalb{\'a}n and Mackereth, {John Ted} and Andrea Miglio and Fiorenzo Vincenzo and Cristina Chiappini and Ga{\"e}l Buldgen and Beno{\^i}t Mosser and Arlette Noels and Richard Scuflaire and Mathieu Vrard and Emma Willett and Davies, {Guy R.} and Oliver Hall and Nielsen, {Martin Bo} and Saniya Khan and Rendle, {Ben M.} and Rossem, {Walter E. van} and Ferguson, {Jason W.} and Chaplin, {William J.}",

note = "Updated with the final version accepted for publication as a Letter in Nature Astronomy (29 pages, 10 figures, 2 tables, including main article and methods section). Improved presentation of results, which have not changed from the previous version",

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Montalbán, J, Mackereth, JT, Miglio, A, Vincenzo, F, Chiappini, C, Buldgen, G, Mosser, B, Noels, A, Scuflaire, R, Vrard, M, Willett, E, Davies, GR, Hall, O, Nielsen, MB, Khan, S, Rendle, BM, Rossem, WEV, Ferguson, JW & Chaplin, WJ 2021, 'Chronologically dating the early assembly of the Milky Way', Nature Astronomy, vol. 5, no. 7, pp. 640-647. https://doi.org/10.1038/s41550-021-01347-7

TY - JOUR

T1 - Chronologically dating the early assembly of the Milky Way

AU - Montalbán, Josefina

AU - Mackereth, John Ted

AU - Miglio, Andrea

AU - Vincenzo, Fiorenzo

AU - Chiappini, Cristina

AU - Buldgen, Gaël

AU - Mosser, Benoît

AU - Noels, Arlette

AU - Scuflaire, Richard

AU - Vrard, Mathieu

AU - Willett, Emma

AU - Davies, Guy R.

AU - Hall, Oliver

AU - Nielsen, Martin Bo

AU - Khan, Saniya

AU - Rendle, Ben M.

AU - Rossem, Walter E. van

AU - Ferguson, Jason W.

AU - Chaplin, William J.

N1 - Updated with the final version accepted for publication as a Letter in Nature Astronomy (29 pages, 10 figures, 2 tables, including main article and methods section). Improved presentation of results, which have not changed from the previous version

PY - 2021/5/17

Y1 - 2021/5/17

N2 - The standard cosmological model predicts that galaxies are built through hierarchical assembly on cosmological timescales1,2. The Milky Way, like other disk galaxies, underwent violent mergers and accretion of small satellite galaxies in its early history. Owing to Gaia Data Release 23 and spectroscopic surveys4, the stellar remnants of such mergers have been identified5,6,7. The chronological dating of such events is crucial to uncover the formation and evolution of the Galaxy at high redshift, but it has so far been challenging due to difficulties in obtaining precise ages for these oldest stars. Here we combine asteroseismology—the study of stellar oscillations—with kinematics and chemical abundances to estimate precise stellar ages (~11%) for a sample of stars observed by the Kepler space mission8. Crucially, this sample includes not only some of the oldest stars that were formed inside the Galaxy but also stars formed externally and subsequently accreted onto the Milky Way. Leveraging this resolution in age, we provide compelling evidence in favour of models in which the Galaxy had already formed a substantial population of its stars (which now reside mainly in its thick disk) before the infall of the satellite galaxy Gaia-Enceladus/Sausage5,6 around 10 billion years ago.

AB - The standard cosmological model predicts that galaxies are built through hierarchical assembly on cosmological timescales1,2. The Milky Way, like other disk galaxies, underwent violent mergers and accretion of small satellite galaxies in its early history. Owing to Gaia Data Release 23 and spectroscopic surveys4, the stellar remnants of such mergers have been identified5,6,7. The chronological dating of such events is crucial to uncover the formation and evolution of the Galaxy at high redshift, but it has so far been challenging due to difficulties in obtaining precise ages for these oldest stars. Here we combine asteroseismology—the study of stellar oscillations—with kinematics and chemical abundances to estimate precise stellar ages (~11%) for a sample of stars observed by the Kepler space mission8. Crucially, this sample includes not only some of the oldest stars that were formed inside the Galaxy but also stars formed externally and subsequently accreted onto the Milky Way. Leveraging this resolution in age, we provide compelling evidence in favour of models in which the Galaxy had already formed a substantial population of its stars (which now reside mainly in its thick disk) before the infall of the satellite galaxy Gaia-Enceladus/Sausage5,6 around 10 billion years ago.

KW - astro-ph.GA

KW - astro-ph.SR

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U2 - 10.1038/s41550-021-01347-7

DO - 10.1038/s41550-021-01347-7

M3 - Letter

SN - 2397-3366

VL - 5

SP - 640

EP - 647

JO - Nature Astronomy

JF - Nature Astronomy

IS - 7

ER -

Chronologically dating the early assembly of the Milky Way

Abstract

Bibliographical note

Keywords

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