516 research outputs found
A model for the Globular Cluster extreme anomalies
In spite of the efforts made in the latest years, still there is no
comprehensive explanation for the chemical anomalies of globular cluster stars.
Among these, the most striking is oxygen depletion, which reaches values down
to [O/Fe]~-0.4 in most clusters, but in M13 it goes down to less than [O/Fe]~ -
1. In this work we suggest that the anomalies are due to the super position of
two different events: 1) PRIMORDIAL SELF-ENRICHMENT: this is asked to explain
the oxygen depletion down to a minimum value [O/Fe]~ -0.4; 2) EXTRA MIXING IN A
FRACTION OF THE STARS ALREADY BORN WITH ANOMALOUS COMPOSITION: these objects,
starting with already low [O/Fe], will reduce the oxygen abundance down to the
most extreme values. Contrary to other models that invoke extra mixing to
explain the chemical anomalies, we suggest that it is active only if there is a
fraction of the stars in which the primordial composition is not only oxygen
depleted, but also extremely helium rich (Y~ 0.4), as found in a few GCs from
their main sequence multiplicity. We propose that the rotational evolution (and
an associated extra mixing) of extremely helium rich stars may be affected by
the fact that they develop a very small or non existent molecular weight
barrier during the evolution. We show that extra mixing in these stars, having
initial chemistry that has already been CNO processed, affects mainly the
oxygen abundance, and to a much smaller extent if affects the sodium abundance.
The model also predicts a large fluorine depletion concomitant with the oxygen
depletion, and a further enhancement of the surface helium abundance, which
reaches values close to Y=0.5 in the computed models. We stress that, in this
tentative explanation, those stars that are primordially O--depleted, but ARE
NOT extremely helium rich do not suffer deep extra mixing.Comment: 12 pages, 8 figures and 5 tables, accepted for publication in MNRA
Modelling the closest double degenerate system RXJ0806.3+1527 and its decreasing period
In the hypothesis that the 5.4m binary RXJ0806.3+1527 consists of a low mass
helium white dwarf (donor) transferring mass towards its more massive white
dwarf companion (primary), we consider as possible donors white dwarfs which
are the result of common envelope evolution occurring when the helium core mass
of the progenitor giant was still very small (~ 0.2Msun), so that they are
surrounded by a quite massive hydrogen envelope (~1/100Msun or larger), and
live for a very long time supported by proton--proton burning. Mass transfer
from such low mass white dwarfs very probably starts during the hydrogen
burning stage, and the donor structure will remain dominated by the burning
shell until it loses all the hydrogen envelope and begins transferring helium.
We model mass transfer from these low mass white dwarfs, and show that the
radius of the donor decreases while they shed the hydrogen envelope. This
radius behavior, which is due to the fact that the white dwarf is not fully
degenerate, has two important consequences on the evolution of the binary: 1)
the orbital period decreases, with a timescale consistent with the period
decrease of the binary RXJ0806.3+1527; 2) the mass transfer rate is a factor of
about 10 smaller than from a fully degenerate white dwarf, easing the problem
connected with the small X-ray luminosity of this object. The possibility that
such evolution describes the system RXJ0806.3+1527 is also consistent with the
possible presence of hydrogen in the optical spectrum of the star, whose
confirmation would become a test of the model.Comment: 13 pages, 4 figures, accepted for publication on ApJ, main journa
New light on the old problem of lithium pre--MS depletion: models with 2D RHD convection
The Teff location of Pre-Main Sequence (PMS) evolutionary tracks depends on the treatment of over-adiabaticity. We present here the PMS evolutionary tracks computed by using the mixing length theory of convection (MLT) in which the alpha_MLT=l/H_p parameter calibration is based on 2D--hydrodynamical models (Ludwig et al. 1999). These MLT--\alpha^2D stellar models and tracks are very similar to those computed with non--grey ATLAS9 atmospheric boundary conditions and Full Spectrum of Turbulence (FST) convection model both in the atmosphere and in the interior. The comparison of the new tracks with the location on the HR diagram of pre--MS binariesis not completely satisfactory, as some binary components are located at too low \teff. Besides, the pre--MS lithium depletion in the MLT--\alpha^2D tracks is still much larger than that expected from the observations of lithium in young open clusters. This result is similar to that of FST models. Thus, in spite of the fact that 2D RHD models should provide a better convection description than any local model, their introduction is not sufficient to reconcile theory and observations. Lithium depletion in young clusters points towards a convection efficiency which, in pre--MS, should be smaller than in the MS. The pre--MS lithium depletion decreases significantly in FST models if we reduce the solar metallicity down to the value suggested by Asplund et al.(2004), but the corresponding solar model does not reproduce the depth of the convective zone as determined by helioseismology
Embedded Clusters and the IMF
Despite valiant efforts over nearly five decades, attempts to determine the
IMF over a complete mass range for galactic field stars and in open clusters
have proved difficult. Infrared imaging observations of extremely young
embedded clusters coupled with Monte Carlo modeling of their luminosity
functions are improving this situation and providing important new
contributions to our fundamental knowledge of the IMF and its universality in
both space and time.Comment: 6 pages, 2 figures to appear in "The IMF@50", Kluwer Academic Press,
eds. C. Corbelli, F. Palla, & Hans Zinnecke
Efficiency of convection and pre-mainsequence lithium depletion
We show by detailed model computation how much the Pre-Main Sequence (PMS)
Lithium depletion depends on the treatment of over-adiabaticity, by taking
advantage of the results of new models by Montalb\'an et al., which apply
different treatments of convection to non-grey PMS models. In order to
reproduce both the PMS lithium depletion (inferred from the lithium depletion
patterns in young open clusters), and the location of PMS tracks in the HR
diagram (inferred from the study of young PMS stars), convection both in the
atmosphere and in a good fraction of the stellar envelope must be highly
inefficient: e.g., in the Mixing Length Theory approximation, it must have a
very low alpha=l/H_p. Unfortunately, the radii of these models are at variance
with the solar radius, possibly indicating t hat there is some additional
physical input, generally not taken into account in the stellar models, which
affects the efficiency of convection in PMS stars, but probably not in the main
sequence stars nor in evolved red giants. We stress the importance of
determining precisely masses and lithium abundance in PMS binaries such as the
important spectroscopic and eclipsing binary RXJ0529.4+0041.Comment: accepted for publication in A&A main journa
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