Bibcode
Althaus, L. G.; Serenelli, A. M.; Panei, J. A.; Córsico, A. H.; García-Berro, E.; Scóccola, C. G.
Referencia bibliográfica
Astronomy and Astrophysics, Volume 435, Issue 2, May IV 2005, pp.631-648
Fecha de publicación:
5
2005
Revista
Número de citas
221
Número de citas referidas
181
Descripción
We explore the formation and evolution of hydrogen-deficient post-AGB
white dwarfs. To this end, we compute the complete evolution of an
initially 2.7 ~M&sun; star from the zero-age main sequence
through the thermally pulsing and mass-loss phases to the white dwarf
stage. Particular attention is given to the chemical abundance changes
during the whole evolution. A time-dependent scheme for the simultaneous
treatment of abundance changes caused by nuclear reactions, diffusive
overshooting, salt fingers and convection is considered. We employed the
double-diffusive mixing-length theory of convection for fluids with
composition gradients. The study can therefore be considered as a test
of its performance in low-mass stars. Also, time-dependent element
diffusion for multicomponent gases is taken into account during the
white dwarf evolution. The evolutionary stages corresponding to the last
helium thermal pulse on the early white-dwarf cooling branch and the
following born-again episode are carefully explored. Relevant aspects
for PG 1159 stars and DB white dwarf evolution are studied in the
framework of these new evolutionary models that take into account the
history of the white dwarf progenitor. The scope of the calculations is
extended to the domain of the helium-rich, carbon-contaminated DQ white
dwarfs with the aim of exploring the plausibility of the evolutionary
connection PG 1159-DB-DQ. In this regard, the implications for the
double-layered chemical structure in pulsating DB white dwarfs is
investigated. We examine the consequences of mass-loss episodes during
the PG 1159 stage for the chemical stratification of the outer layer of
DB and DQ white dwarfs.