| Issue |
Astron. Astrophys. Suppl. Ser.
Volume 129, Number 2, April II 1998
|
|
|---|---|---|
| Page(s) | 237 - 266 | |
| DOI | https://doi.org/10.1051/aas:1998400 | |
| Published online | 15 April 1998 | |
Abundances in metal-rich stars*
Detailed abundance analysis of 47 G and K dwarf stars with > 0.10 dex
1
Royal Greenwich Observatory, Madingley Road, Cambridge CB3 0EZ, UK
2
Astronomiska observatoriet, Box 515, S-751 20 Uppsala, Sweden
Corresponding author: Send offprint request to: S. Feltzing sofia@ast.cam.ac.uk
Received:
25
June
1997
Accepted:
26
September
1997
We have derived elemental abundances of O, Na, Mg, Al, Si, Ca, Ti, Cr,
Mn, Fe, Co, Ni as well as for a number of s-elements for 47 G and K
dwarf, with [Me/H]
dex. The selection of stars was based on their
kinematics as well as on their 
photometry. One sample of
stars on rather eccentric orbits traces the chemical evolution
interior to the solar orbit and another, on circular orbits, the
evolution around the solar orbit. A few Extreme Population I stars
were included in the latter sample.
The stars have -0.1 dex ![$< {\rm [Fe/H]} < 0.42$](/articles/aas/abs/1998/08/h0567/h0567_tex_eq3.png)
dex. The
spectroscopic [Fe/H] correlate well with the [Me/H] derived from
photometry. We find that the elemental abundances of
Mg, Al, Si, Ca, Ti, Cr and Ni all follow [Fe/H]. Our data put further
constraints on models of galactic chemical evolution, in particular of
Cr, Mn and Co which have not previously been studied for dwarf stars
with ![${\rm [Me/H]} >0.1$](/articles/aas/abs/1998/08/h0567/h0567_tex_eq5.png)
dex. The increase in [Na/Fe] and [Al/Fe] as
a function of [Fe/H] found previously by Edvardsson et al. (1993a) has
been confirmed for [Na/Fe]. This upturning relation, and the scatter
around it, are shown not to be due to a mixture of populations with
different mean distances to the galactic centre. We do not confirm the
same trend for aluminium, which is somewhat surprising since both
these elements are thought to be produced in the same environments in
the pre-supernova stars. Nor have we been able to trace any tendency
for relative abundances of O, Si, and Ti relative to Fe to vary with
the stellar velocities, i.e. the stars present mean distance to the
galactic centre. These results imply that there is no significant
difference in the chemical evolution of the different stellar
populations for stars with [Me/H] dex. We find that [O/Fe]
continue to decline with increasing [Fe/H] and that oxygen and
europium correlate well. However [Si/Fe] and [Ca/Fe] seem to stay
constant. A real ("cosmic”) scatter in [Ti/Fe] at given [Fe/H] is
suggested as well as a decreasing abundance of the s-elements relative
to iron for the most metal-rich dwarf stars. We discuss our results
in the context of recent models of galactic chemical evolution.
In our sample we have included a few very metal rich stars, sometimes
called SMR (super metal rich) stars. We find these stars to be among
the most iron-rich in our sample but far from as metal-rich as
indicated by their photometric metallicities. SMR stars on highly
eccentric orbits, alleged to trace the evolution of the chemical
evolution in the galactic Bulge, have previously been found
overabundant in O, Mg and Si. We have included three such stars from
the study by Barbuy & Grenon (1990). We find them to be less metal
rich and the other elemental abundances remain puzzling.
Detailed spectroscopic abundance analyses of K dwarf stars are
rare. Our study includes 5 K dwarf stars and has revealed what appears
to be a striking example of overionization. The overionization is
especially prominent for Ca, Cr and Fe. The origin of this apparent
overionization is not clear and we discuss different explanations in
some detail.
Key words: Galaxy: abundances / evolution / stars: abundances / late-type / fundamental parameters
© European Southern Observatory (ESO), 1998