The structure and evolution of the Galactic high-α disc I. Chemical and age orbital cartography
Abstract
We present a comprehensive chemical and age orbital cartography of the Galactic high-α disc using subgiant stars with precise ages, element abundances, and full phase-space information from the LAMOST--Gaia data set. Specifically, we map how average [Fe/H], [α/Fe], and age vary across present-day kinematic and orbital coordinates. We analyse the data in full and across mono-abundance populations to measure element abundance-orbital and age-orbital gradients across orbital actions and angular-momenta. Our results show that the high-α disc exhibits clear and coherent gradients in [Fe/H], [α/Fe], and age with orbits; these gradients are much stronger and sharper in orbital space than in present-day kinematics, showing that orbital diagnostics recover the intrinsic disc structure of old disc populations more effectively than instantaneous kinematic coordinates. We find that older high-α populations display qualitatively similar element abundance--orbital and age--orbital trends to stars in the low-α disc, although the high-α gradients are generally shallower. The presence of these ordered correlations indicates that the old high-α disc is structured, and preserved a strong fossil record of its early assembly despite the Milky Way's subsequent accretion history. This result implies that later mergers did not fully erase the chemical-orbital and age-orbital structure imprinted during the high-α disc's earliest formation epoch. All together, these findings indicate that the Galactic high-α disc formed mainly through inside-out and upside-down growth.
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