L. Mashonkina et al., Barium abundances in cool dwarf stars as a constraint to s- and r-process nucleosynthesis, ASTRON ASTR, 343(2), 1999, pp. 519-530
We revise barium abundances in 11 cool stars with metallicities ranging fro
m -2.65 to 0.05. The results are based on differential NLTE model atmospher
e analyses of spectra that have a typical S/N of 200 and a resolution of 40
000 or 60000. To minimize systematic errors of theoretical modeling and to
be sure that elemental surface abundances are not contaminated by thermonuc
lear reaction products from the stellar interior the sample is confined to
main-sequence and turnoff stars with only two subgiants added. Stellar fund
amental parameters are derived from either (V-K) colours or Balmer line pro
files for the effective temperature, from HIPPARCOS parallaxes for the surf
ace gravity and from the LTE analyses of the Fe II line profiles for metal
abundance and microturbulence values. The statistical equilibrium of Ba TI
is investigated with a model atom containing 41 levels of Ba II plus the gr
ound state of Ba III. NLTE effects depend on the metallicity of a star: the
y increase the equivalent widths compared with LTE for [Fe/H] > -2, and the
y show the opposite behaviour at lower metallicities. Empirical evidence fo
r the necessity to include H atom collisions in the statistical equilibrium
of Ba II is found from comparison of Ba abundances in the metal-poor stars
derived from the different spectral lines. The formula of Drawin with a sc
aling factor of 1/3 gives quite sufficient results. [Ba/Fe] abundance ratio
s are approximately solar above [Fe/H] similar to -2.2 where they decrease
rapidly by 0.5-0.6 dex. The direct method based on the hyperfine structure
(HFS) of the resonance line of the odd isotopes is suggested to estimate th
e contribution of the s- and r-process to Ba synthesis. Its application req
uires the knowledge of the total Ba abundance that can be deduced from the
subordinate lines free of HFS. Thus, we cannot estimate the ratio of the s-
and r-processes for the two most metal-deficient stars of our sample. Our
conclusion is that the s-process dominated Ba production, at least, for the
metal-poor stars with [Fe/H] > -2.2.