Your search keyword '"metal-poor stars"' showing total 6 results

1. Extremely metal-poor stars from the cosmic dawn in the bulge of the Milky Way.

Author

Howes, L. M., Casey, A. R., Asplund, M., Keller, S. C., Yong, D., Nataf, D. M., Poleski, R., Lind, K., Kobayashi, C., Owen, C. I., Ness, M., Bessell, M. S., Da Costa, G. S., Schmidt, B. P., Tisserand, P., Udalski, A., Szymański, M. K., Soszyński, I., Pietrzyński, G., and Ulaczyk, K.

Subjects

*METAL-poor stars, *HELIUM, *BIG bang theory, *GALACTIC center, *HALOS (Meteorology)

Abstract

The first stars are predicted to have formed within 200 million years after the Big Bang, initiating the cosmic dawn. A true first star has not yet been discovered, although stars with tiny amounts of elements heavier than helium ('metals') have been found in the outer regions ('halo') of the Milky Way. The first stars and their immediate successors should, however, preferentially be found today in the central regions ('bulges') of galaxies, because they formed in the largest over-densities that grew gravitationally with time. The Milky Way bulge underwent a rapid chemical enrichment during the first 1-2 billion years, leading to a dearth of early, metal-poor stars. Here we report observations of extremely metal-poor stars in the Milky Way bulge, including one star with an iron abundance about 10,000 times lower than the solar value without noticeable carbon enhancement. We confirm that most of the metal-poor bulge stars are on tight orbits around the Galactic Centre, rather than being halo stars passing through the bulge, as expected for stars formed at redshifts greater than 15. Their chemical compositions are in general similar to typical halo stars of the same metallicity although intriguing differences exist, including lower abundances of carbon. [ABSTRACT FROM AUTHOR]

Published

2015

2. Extremely metal-poor gas at a redshift of 7.

Author

Simcoe, Robert A., Sullivan, Peter W., Cooksey, Kathy L., Kao, Melodie M., Matejek, Michael S., and Burgasser, Adam J.

Subjects

*METAL-poor stars, *REDSHIFT, *ASTROPHYSICS, *MILKY Way, *QUASARS

Abstract

In typical astrophysical environments, the abundance of heavy elements ranges from 0.001 to 2 times the solar value. Lower abundances have been seen in selected stars in the Milky Way's halo and in two quasar absorption systems at redshift z = 3 (ref. 4). These are widely interpreted as relics from the early Universe, when all gas possessed a primordial chemistry. Before now there have been no direct abundance measurements from the first billion years after the Big Bang, when the earliest stars began synthesizing elements. Here we report observations of hydrogen and heavy-element absorption in a spectrum of a quasar at z = ?7.04, when the Universe was just 772?million years old (5.6 per cent of its present age). We detect a large column of neutral hydrogen but no corresponding metals (defined as elements heavier than helium), limiting the chemical abundance to less than 1/10,000 times the solar level if the gas is in a gravitationally bound proto-galaxy, or to less than 1/1,000 times the solar value if it is diffuse and unbound. If the absorption is truly intergalactic, it would imply that the Universe was neither ionized by starlight nor chemically enriched in this neighbourhood at z???7. If it is gravitationally bound, the inferred abundance is too low to promote efficient cooling, and the system would be a viable site to form the predicted but as yet unobserved massive population III stars. [ABSTRACT FROM AUTHOR]

Published

2012

3. Linking dwarf galaxies to halo building blocks with the most metal-poor star in Sculptor.

Author

Frebel, Anna, Kirby, Evan N., and Simon, Joshua D.

Subjects

*DWARF galaxies, *GALAXIES, *METAPHYSICAL cosmology, *STELLAR atmospheres, *METAL-poor stars, *COSMIC abundances, *ASTRONOMY, *SPECTRUM analysis, *MILKY Way

Abstract

Current cosmological models indicate that the Milky Way’s stellar halo was assembled from many smaller systems. On the basis of the apparent absence of the most metal-poor stars in present-day dwarf galaxies, recent studies claimed that the true Galactic building blocks must have been vastly different from the surviving dwarfs. The discovery of an extremely iron-poor star (S1020549) in the Sculptor dwarf galaxy based on a medium-resolution spectrum cast some doubt on this conclusion. Verification of the iron-deficiency, however, and measurements of additional elements, such as the α-element Mg, are necessary to demonstrate that the same type of stars produced the metals found in dwarf galaxies and the Galactic halo. Only then can dwarf galaxy stars be conclusively linked to early stellar halo assembly. Here we report high-resolution spectroscopic abundances for 11 elements in S1020549, confirming its iron abundance of less than 1/4,000th that of the Sun, and showing that the overall abundance pattern follows that seen in low-metallicity halo stars, including the α-elements. Such chemical similarity indicates that the systems destroyed to form the halo billions of years ago were not fundamentally different from the progenitors of present-day dwarfs, and suggests that the early chemical enrichment of all galaxies may be nearly identical. [ABSTRACT FROM AUTHOR]

Published

2010

4. Astrophysics: A hint of normality at last?

Author

Norris, John E.

Subjects

*METAL-poor stars, *DWARF stars, *IRON, *ASTROPHYSICS research

Abstract

The article reports on the discovery of SDSSJ102915+172927 in the Sloan Digital Sky Survey by E. Caffau and colleagues, an iron-poor dwarf star which contains an iron abundance of 10-5.0 of the sun. It says that the findings contradict with A. Frebel and colleagues' prediction that the abundance of carbon or oxygen is a vital element in cooling of gas clouds. Moreover, it discusses the oldest stars' chemical diversity which gave rise to a more clear understanding about the universe.

Published

2011

5. Nucleosynthetic signatures of the first stars.

Author

Frebel, Anna, Wako Aoki, Christlieb, Norbert, Hiroyasu Ando, Asplund, Martin, Barklem, Paul S., Beers, Timothy C., Eriksson, Kjell, Fechner, Cora, Fujimoto, Masayuki Y., Satoshi Honda, Toshitaka Kajino, Takeo Minezaki, Ken'ichi Nomoto, Norris, John E., Ryan, Sean G., Masahide Takada-Hidai, Tsangarides, Stelios, and Yuzuru Yoshii

Subjects

*NUCLEOSYNTHESIS, *COSMIC abundances, *METAL-poor stars, *STARS, *CHEMICAL elements, *COSMOCHEMISTRY

Abstract

The chemically most primitive stars provide constraints on the nature of the first stellar objects that formed in the Universe; elements other than hydrogen, helium and traces of lithium present within these objects were generated by nucleosynthesis in the very first stars. The relative abundances of elements in the surviving primitive stars reflect the masses of the first stars, because the pathways of nucleosynthesis are quite sensitive to stellar masses. Several models have been suggested to explain the origin of the abundance pattern of the giant star HE0107-5240, which hitherto exhibited the highest deficiency of heavy elements known. Here we report the discovery of HE1327-2326, a subgiant or main-sequence star with an iron abundance about a factor of two lower than that of HE0107-5240. Both stars show extreme overabundances of carbon and nitrogen with respect to iron, suggesting a similar origin of the abundance patterns. The unexpectedly low Li and high Sr abundances of HE1327-2326, however, challenge existing theoretical understanding: no model predicts the high Sr abundance or provides a Li depletion mechanism consistent with data available for the most metal-poor stars. [ABSTRACT FROM AUTHOR]

Published

2005

6. Cosmology: The lithium problem.

Author

Israelian, Garik

Subjects

*LITHIUM, *MILKY Way, *INTERSTELLAR hydrogen, *HELIUM, *METAL-poor stars, *INTERSTELLAR gases, *ASTRONOMERS

Abstract

The article focuses on the abundance of interstellar lithium beyond the Milky Way. It says that the abundance of lithium is billions of times lower than the hydrogen and helium because lithium is more prone to being destroyed in stars. It states that astronomers think that the primordial abundance of lithium is preserved in the starts of the Galaxy that are old and cool. Moreover , an alternative route for lithium problem is to know the lithium abundance of metal-poor interstellar gas.

Published

2012