457 research outputs found
Finding cool subdwarfs using a V-J reduced proper-motion diagram: Stellar parameters for 91 candidates
We present the results of a search for cool subdwarfs for which our
candidates were drawn from a V-J reduced proper-motion diagram constructed by
Salim & Gould (2002). Kinematic (U, V, and W) and self-consistent stellar
parameters (Teff, log g, [Fe/H], and V_t) are derived for 91 candidate
subdwarfs based on high resolution spectra. The observed stars span 3900K <
Teff < 6200K and -2.63 < [Fe/H] < 0.25 including only 3 giants (log g < 4.0).
Of the sample, 77 stars have MgH lines present in their spectra. With more than
56% of our candidate subdwarfs having [Fe/H] < -1.5, we show that the V-J
reduced proper-motion diagram readily identifies metal-poor stars.Comment: PASP (in press
Abundance Analysis of Planetary Host Stars I. Differential Iron Abundances
We present atmospheric parameters and iron abundances derived from
high-resolution spectra for three samples of dwarf stars: stars which are known
to host close-in giant planets (CGP), stars for which radial velocity data
exclude the presence of a close-in giant planetary companion (no-CGP), as well
as a random sample of dwarfs with a spectral type and magnitude distribution
similar to that of the planetary host stars (control). All stars have been
observed with the same instrument and have been analyzed using the same model
atmospheres, atomic data and equivalent width modeling program. Abundances have
been derived differentially to the Sun, using a solar spectrum obtained with
Callisto as the reflector with the same instrumentation. We find that the iron
abundances of CGP dwarfs are on average by 0.22 dex greater than that of no-CGP
dwarfs. The iron abundance distributions of both the CGP and no-CGP dwarfs are
different than that of the control dwarfs, while the combined iron abundances
have a distribution which is very similar to that of the control dwarfs. All
four samples (CGP, no-CGP, combined, control) have different effective
temperature distributions. We show that metal enrichment occurs only for CGP
dwarfs with temperatures just below solar and approximately 300 K higher than
solar, whereas the abundance difference is insignificant at Teff around 6000 K.Comment: 52 pages (aastex 11pt, preprint style), including 17 figures and 13
tables; accepted for publication in AJ (scheduled for the October 2003 issue
Chemical abundances for 11 bulge stars from high-resolution, near-IR spectra
It is debated whether the Milky Way bulge has the characteristics of a
classical bulge sooner than those of a pseudobulge. Detailed abundance studies
of bulge stars is a key to investigate the origin, history, and classification
of the bulge. The aim is to add to the discussion on the origin of the bulge
and to study detailed abundances determined from near-IR spectra for bulge
giants already investigated with optical spectra, the latter also providing the
stellar parameters which are very significant for the results of the present
study. Especially, the important CNO elements are better determined in the
near-IR. High-resolution, near-infrared spectra in the H band are recorded
using the CRIRES spectrometer on the Very Large Telescope. The CNO abundances
can all be determined from the numerous molecular lines in the wavelength range
observed. Abundances of the alpha elements are also determined from the near-IR
spectra. [O/Fe], [Si/Fe] and [S/Fe] are enhanced up to metallicities of at
least [Fe/H]=-0.3, after which they decline. This suggests that the Milky Way
bulge experienced a rapid and early star-formation history like that of a
classical bulge. However, a similarity between the bulge trend and the trend of
the local thick disk seems present. Such a similarity could suggest that the
bulge has a pseudobulge origin. Our [C/Fe] trend does not show any increase
with [Fe/H] which could have been expected if W-R stars have contributed
substantially to the C abundances. No "cosmic scatter" can be traced around our
observed abundance trends; the scatter found is expected, given the
observational uncertainties.Comment: Accepted for publication in A&
HE0107-5240, A Chemically Ancient Star.I. A Detailed Abundance Analysis
We report a detailed abundance analysis for HE0107-5240, a halo giant with
[Fe/H]_NLTE=-5.3. This star was discovered in the course of follow-up
medium-resolution spectroscopy of extremely metal-poor candidates selected from
the digitized Hamburg/ESO objective-prism survey. On the basis of
high-resolution VLT/UVES spectra, we derive abundances for 8 elements (C, N,
Na, Mg, Ca, Ti, Fe, and Ni), and upper limits for another 12 elements. A
plane-parallel LTE model atmosphere has been specifically tailored for the
chemical composition of {\he}. Scenarios for the origin of the abundance
pattern observed in the star are discussed. We argue that HE0107-5240 is most
likely not a post-AGB star, and that the extremely low abundances of the
iron-peak, and other elements, are not due to selective dust depletion. The
abundance pattern of HE0107-5240 can be explained by pre-enrichment from a
zero-metallicity type-II supernova of 20-25M_Sun, plus either self-enrichment
with C and N, or production of these elements in the AGB phase of a formerly
more massive companion, which is now a white dwarf. However, significant radial
velocity variations have not been detected within the 52 days covered by our
moderate-and high-resolution spectra. Alternatively, the abundance pattern can
be explained by enrichment of the gas cloud from which HE0107-5240 formed by a
25M_Sun first-generation star exploding as a subluminous SNII, as proposed by
Umeda & Nomoto (2003). We discuss consequences of the existence of HE0107-5240
for low-mass star formation in extremely metal-poor environments, and for
currently ongoing and future searches for the most metal-poor stars in the
Galaxy.Comment: 60 pages, 16 figures. Accepted for publication in Ap
Abundances in bulge stars from high-resolution, near-IR spectra I. The CNO elements observed during the science verification of CRIRES at VLT
The formation and evolution of the Milky Way bulge is not yet well understood
and its classification is ambiguous. Constraints can, however, be obtained by
studying the abundances of key elements in bulge stars. The aim of this study
is to determine the chemical evolution of CNO, and a few other elements in
stars in the Galactic bulge, and to discuss the sensitivities of the derived
abundances from molecular lines. High-resolution, near-IR spectra in the H band
were recorded using VLT/CRIRES. Due to the high and variable visual extinction
in the line-of-sight towards the bulge, an analysis in the near-IR is
preferred. The CNO abundances can all be determined simultaneously from the
numerous molecular lines in the wavelength range observed. The three giant
stars in Baade's window presented here are the first bulge stars observed with
CRIRES. We have especially determined the CNO abundances, with uncertainties of
less than 0.20 dex, from CO, CN, and OH lines. Since the systematic
uncertainties in the derived CNO abundances due to uncertainties in the stellar
fundamental parameters, notably Teff, are significant, a detailed discussion of
the sensitivities of the derived abundances is included. We find good agreement
between near-IR and optically determined O, Ti, Fe, and Si abundances. Two of
our stars show a solar [C+N/Fe], suggesting that these giants have experienced
the first dredge-up and that the oxygen abundance should reflect the original
abundance of the giants. The two giants fit into the picture, in which there is
no significant difference between the O abundance in bulge and thick-disk
stars. Our determination of the S abundances is the first for bulge stars. The
high [S/Fe] values for all the stars indicate a high star-formation rate in an
early phase of the bulge evolution.Comment: Accepted by A&
Elemental abundance differences in the 16 Cygni binary system: a signature of gas giant planet formation?
The atmospheric parameters of the components of the 16Cygni 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 0.023 dex. The fact that 16CygA
has about four times more lithium than 16CygB is normal considering the
slightly different masses of the stars. The abundance patterns of 16CygA 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 (0.018 dex, on average). We
find that 16CygA is more metal-rich than 16CygB by 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 16CygB is responsible
for the observed abundance pattern, the formation of gas giants produces a
constant downwards shift in the photospheric abundance of metals, without a Tc
correlation. The latter would be produced by the formation 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 Msun stars to reach their present-day
sizes about three times quicker than predicted by standard stellar evolution
models.Comment: ApJ, in pres
Chemical Inhomogeneities in the Milky Way Stellar Halo
We have compiled a sample of 699 stars from the recent literature with
detailed chemical abundance information (spanning -4.2 < [Fe/H] < +0.3), and we
compute their space velocities and Galactic orbital parameters. We identify
members of the inner and outer stellar halo populations in our sample based
only on their kinematic properties and then compare the abundance ratios of
these populations as a function of [Fe/H]. In the metallicity range where the
two populations overlap (-2.5 < [Fe/H] < -1.5), the mean [Mg/Fe] of the outer
halo is lower than the inner halo by ~0.1 dex. For [Ni/Fe] and [Ba/Fe], the
star-to-star abundance scatter of the inner halo is consistently smaller than
in the outer halo. The [Na/Fe], [Y/Fe], [Ca/Fe], and [Ti/Fe] ratios of both
populations show similar means and levels of scatter. Our inner halo population
is chemically homogeneous, suggesting that a significant fraction of the Milky
Way stellar halo originated from a well-mixed ISM. In contrast, our outer halo
population is chemically diverse, suggesting that another significant fraction
of the Milky Way stellar halo formed in remote regions where chemical
enrichment was dominated by local supernova events. We find no abundance trends
with maximum radial distance from the Galactic center or maximum vertical
distance from the Galactic disk. We also find no common kinematic signature for
groups of metal-poor stars with peculiar abundance patters, such as the
alpha-poor stars or stars showing unique neutron-capture enrichment patterns.
Several stars and dSph systems with unique abundance patterns spend the
majority of their time in the distant regions of the Milky Way stellar halo,
suggesting that the true outer halo of the Galaxy may have little resemblance
to the local stellar halo.Comment: Accepted for publication in AJ. Full tables available upon reques
The Stellar Populations of M33's Outer Regions IV: Inflow History and Chemical Evolution
We have modelled the observed color-magnitude diagram (CMD) at one location
in M33's outskirts under the framework of a simple chemical evolution scenario
which adopts instantaneous and delayed recycling for the nucleosynthetic
products of Type II and Ia supernovae. In this scenario, interstellar gas forms
stars at a rate modulated by the Kennicutt-Schmidt relation and gas outflow
occurs at a rate proportional to the star formation rate (SFR). With this
approach, we put broad constraints on the role of gas flows during this
region's evolution and compare its [alpha/Fe] vs. [Fe/H] relation with that of
other Local Group systems. We find that models with gas inflow are
significantly better than the closed box model at reproducing the observed
distribution of stars in the CMD. The best models have a majority of gas inflow
taking place in the last 7 Gyr, and relatively little in the last 3 Gyr. These
models predict most stars in this region to have [alpha/Fe] ratios lower than
the bulk of the Milky Way's halo. The predictions for the present-day SFR, gas
mass, and oxygen abundance compare favorably to independent empirical
estimates. Our results paint a picture in which M33's outer disc formed from
the protracted inflow of gas over several Gyr with at least half of the total
inflow occurring since z ~ 1.Comment: 22 pages, 12 figures, accepted to MNRA
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