Your search keyword '"Roederer, I. U."' showing total 3 results

1. The r-process in metal poor stars and black hole formation.

Author

Boyd, R. N., Famiano, M. A., Meyer, B. S., Motizuki, Y., Kajino, T., and Roederer, I. U.

Subjects

NUCLEOSYNTHESIS, METAL-poor stars, BLACK holes, STAR formation, COSMIC abundances, ATOMIC mass, GRAVITATIONAL collapse

Abstract

Nucleosynthesis of heavy nuclei in metal-poor stars is generally ascribed to the r-process, as the abundance pattern in many such stars agrees with the inferred Solar r-process abundances. Nonetheless, a significant number of these stars do not share this r-process template. We suggest that many such stars have begun an r-process, but it was prevented from running to completion in more massive stars by collapse to black holes, creating a "truncated r-process", or "tr-process". The observed fraction of tr-process stars is found to be consistent with expectations from the initial mass function (IMF), and we suggest that an apparent sharp truncation observed at around mass 160 could result from a combination of collapses to black holes and the difficulty of observing the higher mass rare earths. We test the tr-process hypothesis with calculations that are terminated before all r-process trajectories have been ejected. These produce qualitative agreement with observation when both black hole collapse and observational realities are taken into account. [ABSTRACT FROM AUTHOR]

Published

2012

2. ELEMENTAL ABUNDANCE DIFFERENCES IN THE 16 CYGNI BINARY SYSTEM: A SIGNATURE OF G, GIANT PLANET FORMATION?

Author

RAMÍREZ, I., MELÉNDEZ, J., CORNEJO, D., ROEDERER, I. U., and FISH, J. R.

Subjects

COSMIC abundances, P Cygni stars, BINARY systems (Astronomy), ASTRONOMICAL observations, GALAXY formation

Abstract

The atmospheric parameters of the components of the 16 Cygni binary system, in which the secondary has a gas giant planet detected, are measured accurately using high-quality observational data. Abundances relative to solar are obtained for 25 elements with a mean error of σ([X/H]) = 0.023 dex. The fact that 16 Cyg A has about four times more lithium than 16 Cyg B is normal considering the slightly different masses of the stars. The abundance patterns of 16 Cyg A and B, relative to iron, are typical of that observed in most of the so-called solar twin stars, with the exception of the heavy elements (Z > 30), which can, however, be explained by Galactic chemical evolution. Differential (A-B) abundances are measured with even higher precision (cr(A[X/H]) = 0.018 dex, on average). We find that 16 Cyg A is more metal-rich than 16 Cyg B by Δ[M/H] = +0.041 ± 0.007 dex. On an element-to-element basis, no correlation between the A-B abundance differences and dust condensation temperature (TC) is detected. Based on these results, we conclude that if the process of planet formation around 16 Cyg B is responsible for the observed abundance pattern, the formation of gas giants produces a constant downward shift in the photospheric abundance of metals, without a TC correlation. The latter would be produced by the for≈ῑmation of terrestrial planets instead, as suggested by other recent works on precise elemental abundances. Nevertheless, a scenario consistent with these observations requires the convective envelopes of ≃1 Mʘ stars to reach their present-day sizes about three times quicker than predicted by standard stellar evolution models. [ABSTRACT FROM AUTHOR]

Published

2011

3. ELEMENTAL ABUNDANCES OF SOLAR SIBLING CANDIDATES.

Author

Ramírez, I., Bajkova, A. T., Bobylev, V. V., Roederer, I. U., Lambert, D. L., Endl, M., Cochran, W. D., MacQueen, P. J., and Wittenmyer, R. A.

Subjects

COSMIC abundances, SOLAR research, RADIAL velocity of stars, COSMOCHEMISTRY, ORBITAL mechanics

Abstract

Dynamical information along with survey data on metallicity and in some cases age have been used recently by some authors to search for candidates of stars that were born in the cluster where the Sun formed. We have acquired high-resolution, high signal-to-noise ratio spectra for 30 of these objects to determine, using detailed elemental abundance analysis, if they could be true solar siblings. Only two of the candidates are found to have solar chemical composition. Updated modeling of the stars' past orbits in a realistic Galactic potential reveals that one of them, HD 162826, satisfies both chemical and dynamical conditions for being a sibling of the Sun. Measurements of rare-element abundances for this star further confirm its solar composition, with the only possible exception of Sm. Analysis of long-term high-precision radial velocity data rules out the presence of hot Jupiters and confirms that this star is not in a binary system. We find that chemical tagging does not necessarily benefit from studying as many elements as possible but instead from identifying and carefully measuring the abundances of those elements that show large star-to-star scatter at a given metallicity. Future searches employing data products from ongoing massive astrometric and spectroscopic surveys can be optimized by acknowledging this fact. [ABSTRACT FROM AUTHOR]

Published

2014