J. Tomkin scite author profile

Photospheric abundances are presented for 27 elements from carbon to europium in 181 F and G dwarfs from a differential local thermodynamic equilibrium (LTE) analysis of high-resolution and high signal-to-noise ratio spectra. Stellar effective temperatures (T eff ) were adopted from an infrared flux method calibration of Strömgren photometry. Stellar surface gravities (g) were calculated from Hipparcos parallaxes and stellar evolutionary tracks. Adopted T eff and g values are in good agreement with spectroscopic estimates. Stellar ages were determined from evolutionary tracks. Stellar space motions (U , V , W ) and a Galactic potential were used to estimate Galactic orbital parameters. These show that the vast majority of the stars belong to the Galactic thin disc.Relative abundances expressed as [X/Fe] generally confirm previously published results. We give results for CEu. The α elements -O, Mg, Si, Ca and Ti -show [α/Fe] to increase slightly with decreasing [Fe/H]. Heavy elements with dominant contributions at solar metallicity from the s-process show [s/Fe] to decrease slightly with decreasing [Fe/H]. Scatter in [X/Fe] at a fixed [Fe/H] is entirely attributable to the small measurement errors, after excluding the few thick disc stars and the s-process-enriched CH subgiants. Tight limits are set on 'cosmic' scatter. If a weak trend with [Fe/H] is taken into account, the composition of a thin disc star expressed as [X/Fe] is independent of the star's age and birthplace for elements contributed in different proportions by massive stars (Type II supernovae), exploding white dwarfs (Type Ia supernovae) and asymptotic red giant branch stars.By combining our sample with various published studies, comparisons between thin and thick disc stars are made. In this composite sample, thick disc stars are primarily identified by their V LSR in the range −40 to −100 km s −1 . These are very old stars with origins in the inner Galaxy and metallicities [Fe/H] −0.4. At the same [Fe/H], the sampled thin disc stars have V LSR ∼ 0 km s −1 , and are generally younger with a birthplace at about the Sun's Galactocentric distance. In the range −0.35 [Fe/H] −0.70, well represented by present thin and thick disc samples, [X/Fe] of the thick disc stars is greater than that of thin disc stars for Mg, Al, Si, Ca, Ti and Eu. [X/Fe] is very similar for the thin and thick disc for -notably -Na and iron-group elements. Barium ([Ba/Fe]) may be underabundant in thick relative to thin disc stars. These results extend previous ideas about composition differences between the thin and thick disc.

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The carbon-to-oxygen ratio in halo dwarfs

Tomkin¹,

Lemke²,

Lambert³

et al. 1992

144

153

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Rubidium in Metal‐deficient Disk and Halo Stars

Tomkin¹,

Lambert²

1999

ApJ

107

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We report the Ðrst extensive study of stellar Rb abundances. High-resolution spectra have been used to determine, or set upper limits on, the abundances of this heavy element and the associated elements Y, Zr, and Ba in 44 dwarfs and giants with metallicities spanning the range 29 stars), respectively. The di †erent behavior of Rb on the one hand and Y, Zr, and Ba on the other can be attributed in part to the fact that in the Sun and in these stars Rb has a large r-process component while Y, Zr, and Ba are mostly s-process elements with only small r-process components. In addition, the Rb s-process abundance is dependent on the neutron density at the s-processing site. Published observations of Rb in s-process enriched red giants indicate a higher neutron density in the metal-poor giants. These observations imply a higher s-process abundance for Rb in metal-poor stars. The calculated combination of the Rb r-process abundance, as estimated for the stellar Eu abundances, and the s-process abundance, as estimated for red giants, accounts satisfactorily for the observed run of [Rb/Fe]

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Carbon, nitrogen, and oxygen abundances in main-sequence stars. II 20 F and G stars

Clegg¹,

Lambert²,

Tomkin³

1981

ApJ

168

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The r-Process Element Europium in Galactic Disk F and G Dwarf Stars

Woolf¹,

Tomkin²,

Lambert³

1995

ApJ

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J. Tomkin

The chemical compositions of Galactic disc F and G dwarfs

The carbon-to-oxygen ratio in halo dwarfs

Rubidium in Metal‐deficient Disk and Halo Stars

Carbon, nitrogen, and oxygen abundances in main-sequence stars. II 20 F and G stars

The r-Process Element Europium in Galactic Disk F and G Dwarf Stars

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