The Gaia-ESO Survey: Preparing the ground for 4MOST and WEAVE galactic surveys Chemical evolution of lithium with machine learning

被引：10

作者：

Nepal, S. ^{[1
,2
]}

Guiglion, G. ^{[1
,3
]}

de Jong, R. S. ^{[1
]}

Valentini, M. ^{[1
]}

Chiappini, C. ^{[1
]}

Steinmetz, M. ^{[1
]}

Ambrosch, M. ^{[4
]}

Pancino, E. ^{[5
]}

Jeffries, R. D. ^{[6
]}

Bensby, T. ^{[7
]}

Romano, D. ^{[8
]}

Smiljanic, R. ^{[9
]}

Dantas, M. L. L. ^{[9
]}

Gilmore, G. ^{[10
]}

Randich, S. ^{[5
]}

Bayo, A. ^{[11
]}

Bergemann, M. ^{[3
,12
]}

Franciosini, E. ^{[5
]}

Jimenez-Esteban, F. ^{[13
]}

Jofre, P. ^{[14
]}

Morbidelli, L. ^{[5
]}

Sacco, G. G. ^{[5
]}

Tautvaisiene, G. ^{[4
]}

Zaggia, S. ^{[15
]}

机构：

[1] Leibniz Inst Astrophys Potsdam AIP, Sternwarte 16, D-14482 Potsdam, Germany

[2] Univ Potsdam, Inst Phys & Astron, Karl Liebknecht Str 24-25, D-14476 Potsdam, Germany

[3] Max Planck Inst Astron, Konnigstuhl 17, D-69117 Heidelberg, Germany

[4] Vilnius Univ, Inst Theoret Phys & Astron, Sauletekio Ave 3, LT-10257 Vilnius, Lithuania

[5] INAF, Osservatorio Astrofisico Arcetri, Largo Enr Fermi 5, I-50125 Florence, Italy

[6] Keele Univ, Astrophys Grp, Keele ST5 5BG, England

[7] Dept Astron & Theoret Phys, Lund Observ, POB 43, S-22100 Lund, Sweden

[8] INAF Osservat Astrofis & Sci Spazio, Via Gobetti 93-3, I-40129 Bologna, Italy

[9] Polish Acad Sci, Nicolaus Copernicus Astron Ctr, ul Bartycka 18, PL-00716 Warsaw, Poland

[10] Univ Cambridge, Inst Astron, Madingley Rd, Cambridge CB3 0HA, England

[11] European Southern Observ, Karl Schwarzschild-Str 2, D-85748 Garching, Germany

[12] Univ Copenhagen, Niels Bohr Inst, Niels Bohr Int Acad, Blegdamsvej 17, DK-2100 Copenhagen, Denmark

[13] ESAC Campus, Ctr Astrobiol CSIC INTA, Dept Astrofis, Camino Bajo Castillo S-N, Madrid 28692, Spain

[14] Univ Diego Portales UDP, Fac Ingn & Ciencias, Nucl Astron, Ave Ejercito Libertador 441, Santiago, Chile

[15] INAF Osservat Astron Padova, Vicolo Osservat 5, I-35122 Padua, Italy

来源：

ASTRONOMY & ASTROPHYSICS | 2023年 / 671卷

基金：

欧洲研究理事会; 瑞典研究理事会;

关键词：

techniques: spectroscopic; methods: data analysis; surveys; stars: fundamental parameters; stars: abundances; Galaxy: stellar content; PRE-MAIN-SEQUENCE; STELLAR SPECTRA; LI EVOLUTION; GALAH SURVEY; RED GIANTS; STARS; ABUNDANCES; SPECTROSCOPY; DWARF; MILKY;

D O I：

10.1051/0004-6361/202244765

中图分类号：

P1 [天文学];

学科分类号：

0704 ;

摘要：

Context. With its origin coming from several sources (Big Bang, stars, cosmic rays) and given its strong depletion during its stellar lifetime, the lithium element is of great interest as its chemical evolution in the Milky Way is not well understood at present. To help constrain stellar and galactic chemical evolution models, numerous and precise lithium abundances are necessary for a large range of evolutionary stages, metallicities, and Galactic volume. Aims. In the age of stellar parametrization on industrial scales, spectroscopic surveys such as APOGEE, GALAH, RAVE, and LAMOST have used data-driven methods to rapidly and precisely infer stellar labels (atmospheric parameters and abundances). To prepare the ground for future spectroscopic surveys such as 4MOST and WEAVE, we aim to apply machine learning techniques to lithium measurements and analyses. Methods. We trained a convolution neural network (CNN), coupling Gaia-ESO Survey iDR6 stellar labels (T-eff, log(g), [Fe/H], and A(Li)) and GIRAFFE HR15N spectra, to infer the atmospheric parameters and lithium abundances for similar to 40 000 stars. The CNN architecture and accompanying notebooks are available online via GitHub. Results. We show that the CNN properly learns the physics of the stellar labels, from relevant spectral features through a broad range of evolutionary stages and stellar parameters. The lithium feature at 6707.8 angstrom is successfully singled out by our CNN, among the thousands of lines in the GIRAFFE HR15N setup. Rare objects such as lithium-rich giants are found in our sample. This level of performance is achieved thanks to a meticulously built, high-quality, and homogeneous training sample. Conclusions. The CNN approach is very well adapted for the next generations of spectroscopic surveys aimed at studying (among other elements) lithium, such as the 4MIDABLE-LR/HR (4MOST Milky Way disk and bulge low- and high-resolution) surveys. In this context, the caveats of machine-learning applications should be appropriately investigated, along with the realistic label uncertainties and upper limits for abundances.

引用

页数：22

共 15 条

[1] The Gaia-ESO Survey: Chemical evolution of Mg and Al in the Milky Way with machine learning
Ambrosch, M.
Guiglion, G.
Mikolaitis, S.
Chiappini, C.
Tautvaisiene, G.
Nepal, S.
Gilmore, G.
Randich, S.
Bensby, T.
Bayo, A.
Bergemann, M.
Morbidelli, L.
Pancino, E.
Sacco, G. G.
Smiljanic, R.
Zaggia, S.
Jofre, P.
Jimenez-Esteban, F. M.
ASTRONOMY & ASTROPHYSICS, 2023, 672
[2] The Gaia-ESO Survey: Galactic evolution of lithium from iDR6
Romano, D.
Magrini, L.
Randich, S.
Casali, G.
Bonifacio, P.
Jeffries, R. D.
Matteucci, F.
Franciosini, E.
Spina, L.
Guiglion, G.
Chiappini, C.
Mucciarelli, A.
Ventura, P.
Grisoni, V
Bellazzini, M.
Bensby, T.
Bragaglia, A.
de Laverny, P.
Korn, A. J.
Martell, S. L.
Tautvaisiene, G.
Carraro, G.
Gonneau, A.
Jofre, P.
Pancino, E.
Smiljanic, R.
Vallenari, A.
Fu, X.
Albarran, M. L. Gutierrez
Jimenez-Esteban, F. M.
Montes, D.
Damiani, F.
Bergemann, M.
Worley, C.
ASTRONOMY & ASTROPHYSICS, 2021, 653
[3] The Gaia-ESO Survey: Galactic evolution of lithium at high metallicity
Randich, S.
Pasquini, L.
Franciosini, E.
Magrini, L.
Jackson, R. J.
Jeffries, R. D.
d'Orazi, V
Romano, D.
Sanna, N.
Tautvaisiene, G.
Tsantaki, M.
Wright, N. J.
Gilmore, G.
Bensby, T.
Bragaglia, A.
Pancino, E.
Smiljanic, R.
Bayo, A.
Carraro, G.
Gonneau, A.
Hourihane, A.
Morbidelli, L.
Worley, C. C.
ASTRONOMY & ASTROPHYSICS, 2020, 640
[4] The Gaia-ESO Survey: Galactic evolution of sulphur and zinc
Duffau, S.
Caffau, E.
Sbordone, L.
Bonifacio, P.
Andrievsky, S.
Korotin, S.
Babusiaux, C.
Salvadori, S.
Monaco, L.
Francois, P.
Skuladottir, A.
Bragaglia, A.
Donati, P.
Spina, L.
Gallagher, A. J.
Ludwig, H. -G.
Christlieb, N.
Hansen, C. J.
Mott, A.
Steffen, M.
Zaggia, S.
Blanco-Cuaresma, S.
Calura, F.
Friel, E.
Jimenez-Esteban, F. M.
Koch, A.
Magrini, L.
Pancino, E.
Tang, B.
Tautvaisiene, G.
Vallenari, A.
Hawkins, K.
Gilmore, G.
Randich, S.
Feltzing, S.
Bensby, T.
Flaccomio, E.
Smiljanic, R.
Bayo, A.
Carraro, G.
Casey, A. R.
Costado, M. T.
Damiani, F.
Franciosini, E.
Hourihane, A.
Jofre, P.
Lardo, C.
Lewis, J.
Morbidelli, L.
Sousa, S. G.
ASTRONOMY & ASTROPHYSICS, 2017, 604
[5] The Gaia-ESO Survey: Sodium and aluminium abundances in giants and dwarfs Implications for stellar and Galactic chemical evolution
Smiljanic, R.
Romano, D.
Bragaglia, A.
Donati, P.
Magrini, L.
Friel, E.
Jacobson, H.
Randich, S.
Ventura, P.
Lind, K.
Bergemann, M.
Nordlander, T.
Morel, T.
Pancino, E.
Tautvaisiene, G.
Adibekyan, V.
Tosi, M.
Vallenari, A.
Gilmore, G.
Bensby, T.
Francois, P.
Koposov, S.
Lanzafame, A. C.
Recio-Blanco, A.
Bayo, A.
Carraro, G.
Casey, A. R.
Costado, M. T.
Franciosini, E.
Heiter, U.
Hill, V.
Hourihane, A.
Jofre, P.
Lardo, C.
de Laverny, P.
Lewis, J.
Monaco, L.
Morbidelli, L.
Sacco, G. G.
Sbordone, L.
Sousa, S. G.
Worley, C. C.
Zaggia, S.
ASTRONOMY & ASTROPHYSICS, 2016, 589
[6] The Gaia-ESO Survey: the most metal-poor stars in the Galactic bulge
Howes, L. M.
Asplund, M.
Casey, A. R.
Keller, S. C.
Yong, D.
Gilmore, G.
Lind, K.
Worley, C.
Bessell, M. S.
Casagrande, L.
Marino, A. F.
Nataf, D. M.
Owen, C. I.
Da Costa, G. S.
Schmidt, B. P.
Tisserand, P.
Randich, S.
Feltzing, S.
Vallenari, A.
Allende Prieto, C.
Bensby, T.
Flaccomio, E.
Korn, A. J.
Pancino, E.
Recio-Blanco, A.
Smiljanic, R.
Bergemann, M.
Costado, M. T.
Damiani, F.
Heiter, U.
Hill, V.
Hourihane, A.
Jofre, P.
Lardo, C.
de laverny, P.
Magrini, L.
Maiorca, E.
Masseron, T.
Morbidelli, L.
Sacco, G. G.
Minniti, D.
Zoccali, M.
MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY, 2014, 445 (04) : 4241 - 4246
[7] The Gaia-ESO survey: Age-chemical-clock relations spatially resolved in the Galactic disc
Viscasillas Vazquez, Carlos
Magrini, L.
Casali, G.
Tautvaisiene, G.
Spina, L.
van der Swaelmen, M.
Randich, S.
Bensby, T.
Bragaglia, A.
Friel, E.
Feltzing, S.
Sacco, G. G.
Turchi, A.
Jimenez-Esteban, F.
D'Orazi, V.
Delgado-Mena, E.
Mikolaitis, S.
Drazdauskas, A.
Minkeviciute, R.
Stonkute, E.
Bagdonas, V.
Montes, D.
Guiglion, G.
Baratella, M.
Tabernero, H. M.
Gilmore, G.
Alfaro, E.
Francois, P.
Korn, A.
Smiljanic, R.
Bergemann, M.
Franciosini, E.
Gonneau, A.
Hourihane, A.
Worley, C. C.
Zaggia, S.
ASTRONOMY & ASTROPHYSICS, 2022, 660
[8] The Gaia-ESO Survey: Lithium enrichment histories of the Galactic thick and thin disc
Fu, X.
Romano, D.
Bragaglia, A.
Mucciarelli, A.
Lind, K.
Delgado Mena, E.
Sousa, S. G.
Randich, S.
Bressan, A.
Sbordone, L.
Martell, S.
Korn, A. J.
Abia, C.
Smiljanic, R.
Jofre, P.
Pancino, E.
Tautvaisiene, G.
Tang, B.
Magrini, L.
Lanzafame, A. C.
Carraro, G.
Bensby, T.
Damiani, F.
Alfaro, E. J.
Flaccomio, E.
Morbidelli, L.
Zaggia, S.
Lardo, C.
Monaco, L.
Frasca, A.
Donati, P.
Drazdauskas, A.
Chorniy, Y.
Bayo, A.
Kordopatis, G.
ASTRONOMY & ASTROPHYSICS, 2018, 610
[9] Modelling chemical clocks Theoretical evidences of the space and time evolution of [s/α] in the Galactic disc with Gaia-ESO survey
Molero, M.
Magrini, L.
Palla, M.
Cescutti, G.
Viscasillas Vazquez, C.
Casali, G.
Spitoni, E.
Matteucci, F.
Randich, S.
ASTRONOMY & ASTROPHYSICS, 2025, 694
[10] The Gaia-ESO Survey: New constraints on the Galactic disc velocity dispersion and its chemical dependencies
Guiglion, G.
Recio-Blanco, A.
de Laverny, P.
Kordopatis, G.
Hill, V.
Mikolaitis, S.
Minchev, I.
Chiappini, C.
Wyse, R. F. G.
Gilmore, G.
Randich, S.
Feltzing, S.
Bensby, T.
Flaccomio, E.
Koposov, S. E.
Pancino, E.
Bayo, A.
Costado, M. T.
Franciosini, E.
Hourihane, A.
Jofre, P.
Lardo, C.
Lewis, J.
Lind, K.
Magrini, L.
Morbidelli, L.
Sacco, G. G.
Ruchti, G.
Worley, C. C.
Zaggia, S.
ASTRONOMY & ASTROPHYSICS, 2015, 583

← 1 2 →