Title |
Beyond Gaia DR3: Tracing the [α/M] - [M/H] bimodality from the inner to the outer Milky Way disc with Gaia-RVS and convolutional neural networks* / |
Authors |
Guiglion, G ; Nepal, S ; Chiappini, C ; Khoperskov, S ; Traven, G ; Queiroz, A. B.A ; Steinmetz, M ; Valentini, M ; Fournier, Y ; Vallenari, A ; Youakim, K ; Bergemann, M ; Mészáros, S ; Lucatello, S ; Sordo, R ; Fabbro, S ; Minchev, I ; Tautvaišienė, Gražina ; Mikolaitis, Šarūnas ; Montalbán, J |
DOI |
10.1051/0004-6361/202347122 |
Full Text |
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Is Part of |
Astronomy and astrophysics.. Les Ulis : EDP Sciences. 2024, vol. 682, p. [1-26].. ISSN 0004-6361. eISSN 1432-0746 |
Keywords [eng] |
Galaxy: stellar content ; methods: data analysis ; stars: abundances ; techniques: spectroscopic |
Abstract [eng] |
Context. In June 2022, Gaia DR3 provided the astronomy community with about one million spectra from the Radial Velocity Spectrometer (RVS) covering the CaII triplet region. In the next Gaia data releases, we anticipate the number of RVS spectra to successively increase from several 10 million spectra to eventually more than 200 million spectra. Thus, stellar spectra are projected to be produced on an ‘industrial scale’, with numbers well above those for current and anticipated ground-based surveys. However, one-third of the published spectra have 15 ≤ S /N ≤ 25 per pixel such that they pose problems for classical spectral analysis pipelines, and therefore, alternative ways to tap into these large datasets need to be devised. Aims. We aim to leverage the versatility and capabilities of machine learning techniques for supercharged stellar parametrisation by combining Gaia-RVS spectra with the full set of Gaia products and high-resolution, high-quality ground-based spectroscopic reference datasets. Methods. We developed a hybrid convolutional neural network (CNN) that combines the Gaia DR3 RVS spectra, photometry (G, G_BP, G_RP), parallaxes, and XP coefficients to derive atmospheric parameters (Teff, log(g) as well as overall [M/H]) and chemical abundances ([Fe/H] and [α/M]). We trained the CNN with a high-quality training sample based on APOGEE DR17 labels. Results. With this CNN, we derived homogeneous atmospheric parameters and abundances for 886 080 RVS stars that show remarkable precision and accuracy compared to external datasets (such as GALAH and asteroseismology). The CNN is robust against noise in the RVS data, and we derive very precise labels down to S/N =15. We managed to characterise the [α/M] - [M/H] bimodality from the inner regions to the outer parts of the Milky Way, which has never been done using RVS spectra or similar datasets. Conclusions. This work is the first to combine machine learning with such diverse datasets and paves the way for large-scale machine learning analysis of Gaia-RVS spectra from future data releases. Large, high-quality datasets can be optimally combined thanks to the CNN, thereby realising the full power of spectroscopy, astrometry, and photometry. |
Published |
Les Ulis : EDP Sciences |
Type |
Journal article |
Language |
English |
Publication date |
2024 |
CC license |
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