Of the thousands of newly discovered open clusters (OCs) thanks to the exquisite precision of the Gaia mission data, only a small fraction has been observed with high-resolution spectroscopy. Particularly, the population of OCs in the inner disc at relatively high altitudes (Z) from the Galactic plane remains poorly studied. Few such high-|Z| inner-disc OCs have been detected, and most are sparse groupings of stars that still await confirmation as real OCs. We performed a detailed spectroscopic analysis of the high-|Z| inner-disc OC UBC 1052, an old cluster located at a cylindrical Galactocentric radius ̊gc = 6. 1 kpc, where it is one of a few OCs situated at a considerable altitude (Z = 340 pc). We used FLAMES/VLT to acquire high signal-to-noise ratio UVES spectra of four red clump (RC) members (G of simeq0. 06 dex). We also acquired GIRAFFE spectra for other candidate member stars and derived their radial velocities. mag), from which we derived high-precision radial velocities and local thermodynamic equilibrium chemical abundances for 23 elements. A strict line-by-line differential analysis was carried out using a reference RC star and a solar analogue in the OC M 67, allowing us to derive very precise abundances for each star (a median precision in X/H We determine that UBC 1052 has an age of 2. 25 = +0. 05 ± 0. 01 dex, and with Gyr, a distance of 3. 11 ± 0. 07 kpc, an extinction of AV =1. 23 mag, and a mean radial velocity of overlineř =34. 0 ± 0. 6 ̨ms. We find that the four RC stars have fully compatible chemical abundances, thus confirming UBC 1052 as a real OC. It has Fe/H X/H dispersions among the four stars <0. 03 dex for 20 elements, we give conservative limits for chemical inhomogeneities at simeq0. 05 dex for these species. UBC 1052 stands out as the oldest and highest-|Z| inner-disc OC studied at high resolution to date, being located in the poorly sampled inner Galactic region where old OCs and OCs with large maximum excursions from the plane are scarce. Its relatively low Fe/H at its ̊gc suggests it is a rare candidate for an inward-migrated OC in the inner disc. Its detailed abundance pattern (e. g. Ba/Zr and Nd/Y) shows some interesting features that appear to be unique in the current census of OCs studied at high resolution, making it an interesting object for potential strong chemical-tagging searches for already dispersed member stars.
Donada et al. (Fri,) studied this question.