Your search keyword '"Siviero, Alessandro"' showing total 2 results

1. METAL-POOR LITHIUM-RICH GIANTS IN THE RADIAL VELOCITY EXPERIMENT SURVEY.

Author

Ruchti, Gregory R., Fulbright, Jon P., Wyse, Rosemary F. G., Gilmore, Gerard F., Grebel, Eva K., Bienaymé, Olivier, Bland-Hawthorn, Joss, Freeman, Ken C., Gibson, Brad K., Munari, Ulisse, Navarro, Julio F., Parker, Quentin A., Reid, Warren, Seabroke, George M., Siebert, Arnaud, Siviero, Alessandro, Steinmetz, Matthias, Watson, Fred G., Williams, Mary, and Zwitter, Tomaz

Subjects

LITHIUM, METAL-poor stars, RADIAL velocity of stars, GLOBULAR clusters, STELLAR populations

Abstract

We report the discovery of eight lithium-rich field giants found in a high-resolution spectroscopic sample of over 700 metal-poor stars ([Fe/H] < -0.5) selected from the Radial Velocity Experiment survey. The majority of the Li-rich giants in our sample are very metal-poor ([Fe/H] ≲ -1.9), and have a Li abundance (in the form of 7Li), A(Li) = log(n(Li)/n(H)) + 12, between 2.30 and 3.63, well above the typical upper red giant branch (RGB) limit, A(Li) < 0.5, while two stars, with A(Li) ~ 1.7-1.8, show similar lithium abundances to normal giants at the same gravity. We further included two metal-poor, Li-rich globular cluster giants in our sample, namely the previously discovered M3-IV101 and newly discovered (in this work) M68-A96. This comprises the largest sample of metal-poor Li-rich giants to date. We performed a detailed abundance analysis of all stars, finding that the majority of our sample stars have elemental abundances similar to that of Li-normal halo giants. Although the evolutionary phase of each Li-rich giant cannot be definitively determined, the Li-rich phase is likely connected to extra mixing at the RGB bump or early asymptotic giant branch that triggers cool bottom processing in which the bottom of the outer convective envelope is connected to the H-burning shell in the star. The surface of a star becomes Li-enhanced as 7Be (which burns to 7Li) is transported to the stellar surface via the Cameron-Fowler mechanism. We discuss and discriminate among several models for the extra mixing that can cause Li production, given the detailed abundances of the Li-rich giants in our sample. [ABSTRACT FROM AUTHOR]

Published

2011

2. OBSERVATIONAL PROPERTIES OF THE METAL-POOR THICK DISK OF THE MILKY WAY AND INSIGHTS INTO ITS ORIGINS.

Author

RUCHTI, GREGORY R., FULBRIGHT, JON P., WYSE, ROSEMARY F. G., GILMORE, GERARD F., BIENAYMÉ, OLIVIER, BLAND-HAWTHORN, JOSS, GIBSON, BRAD K., GREBEL, EVA K., HELMI, AMINA, MUNARI, ULISSE, NAVARRO, JULIO F., PARKER, QUENTIN A., REID, WARREN, SEABROKE, GEORGE M., SIEBERT, ARNAUD, SIVIERO, ALESSANDRO, STEINMETZ, MATTHIAS, WATSON, FRED G., WILLIAMS, MARY, and ZWITTER, TOMAZ

Subjects

METAL-poor stars, COSMIC abundances, STARS, MILKY Way, GALAXIES

Abstract

We have undertaken the study of the elemental abundances and kinematic properties of a metal-poor sample of candidate thick-disk stars selected from the Radial Velocity Experiment spectroscopic survey of bright stars to differentiate among the present scenarios of the formation of the thick disk. In this paper, we report on a sample of 214 red giant branch, 31 red clump/horizontal branch, and 74 main-sequence/sub-giant branch metal-poor stars, which serves to augment our previous sample of only giant stars. We find that the thick disk [α/Fe] ratios are enhanced and have little variation (<0.1 dex), in agreement with our previous study. The augmented sample further allows, for the first time, investigation of the gradients in the metal-poor thick disk. For stars with [Fe/H] < - 1.2, the thick disk shows very small gradients, <0.03 ± 0.02 dex kpc-1, in α-enhancement, while we find a +0.01 ± 0.04 dex kpc-1 radial gradient and a -0.09 ± 0.05 dex kpc-1 vertical gradient in iron abundance. In addition, we show that the peak of the distribution of orbital eccentricities for our sample agrees better with models in which the stars that comprise the thick disk were formed primarily in the Galaxy, with direct accretion of stars contributing little. Our results thus disfavor direct accretion of stars from dwarf galaxies into the thick disk as a major contributor to the thick-disk population, but cannot discriminate between alternative models for the thick disk, such as those that invoke high-redshift (gas-rich) mergers, heating of a pre-existing thin stellar disk by a minor merger, or efficient radial migration of stars. [ABSTRACT FROM AUTHOR]

Published

2011