The geneva-copenhagen survey of the solar neighbourhood II: New uvby calibrations and rediscussion of stellar ages, the G dwarf problem, age-metallicity diagram, and heating mechanisms of the disk

• Published in: Astronomy and astrophysics (Berlin) Vol. 475; no. 2; pp. 519 - 537
• Main Authors: HOLMBERG, J, NORDSTRÖM, B, ANDERSEN, J
• Format: Journal Article
• Language: English
• Published: Les Ulis EDP Sciences 01.11.2007
• Subjects: Astronomy; Earth, ocean, space; Exact sciences and technology; Box models; Galaxy: kinematics and dynamics; G stars; Galaxy: evolution; Orbits; Galactic disks; Angular diameter; Galaxy: disk; Dynamics; Solar neighborhood; F stars; Age; Photometry; Galaxy evolution; Spectroscopy; Isochrone; Stellar content; Galactic evolution; Velocity space; Digital simulation; Disk galaxies; Selection effect; Abundance; Age metallicity relation; Stellar kinematics; Milky Way; Galaxy: stellar content; Metallicity; stars: fundamental parameters; Corrections; Galaxy: solar neighbourhood
• ISSN: 0004-6361; 1432-0746
• DOI: 10.1051/0004-6361:20077221

Context. Ages, metallicities, space velocities, and Galactic orbits of stars in the Solar neighbourhood are fundamental observational constraints on models of galactic disk evolution. Understanding and minimising systematic errors and sample selection biases in the data is crucial for their interpretation. Aims. We aim to consolidate the calibrations of uvby\beta photometry into T_{\rm eff}, [Fe/H], distance, and age for F and G stars and rediscuss the results of the Geneva-Copenhagen Survey (Nordstroem et al. 2004; GCS) in terms of the evolution of the disk. Methods. We use recent V-K photometry, angular diameters, high-resolution spectroscopy, Hipparcos parallaxes, and extensive numerical simulations to re-examine and verify the temperature, metallicity, distance, and reddening calibrations for the uvby\beta system. We also highlight the selection effects inherent in the apparent-magnitude limited GCS sample. Results. We substantially improve the T_{\rm eff} and [Fe/H] calibrations for early F stars, where spectroscopic temperatures have large systematic errors. A slight offset of the GCS photometry and the non-standard helium abundance of the Hyades invalidate its use for checking metallicity or age scales; however, the distances, reddenings, metallicities, and age scale for GCS field stars require minor corrections only. Our recomputed ages are in excellent agreement with the independent determinations by Takeda et al. (2007), indicating that isochrone ages can now be reliably determined. Conclusions. The revised G-dwarf metallicity distribution remains incompatible with closed-box models, and the age-metallicity relation for the thin disk remains almost flat, with large and real scatter at all ages ( \sigma_{\rm intrinsic} = 0.20 dex). Dynamical heating of the thin disk continues throughout its life; specific in-plane dynamical effects dominate the evolution of the U and V velocities, while the W velocities remain random at all ages. When assigning thick and thin-disk membership for stars from kinematic criteria, parameters for the oldest stars should be used to characterise the thin disk.