Leandro G. Althaus, Enrique García-Berro, Jordi Isern, Alejandro H. Córsico, Marcelo M. Miller Bertolami
Cool white dwarfs are reliable and independent stellar chronometers. The most
common white dwarfs have carbon-oxygen dense cores. Consequently, the cooling
ages of very cool white dwarfs sensitively depend on the adopted phase diagram
of the carbon-oxygen binary mixture. A new phase diagram of dense carbon-oxygen
mixtures appropriate for white dwarf interiors has been recently obtained using
direct molecular dynamics simulations. In this paper, we explore the
consequences of this phase diagram in the evolution of cool white dwarfs. To do
this we employ a detailed stellar evolutionary code and accurate initial white
dwarf configurations, derived from the full evolution of progenitor stars. We
use two different phase diagrams, that of Horowitz et al. (2010), which
presents an azeotrope, and the phase diagram of Segretain & Chabrier (1993),
which is of the spindle form. We computed the evolution of 0.593 and 0.878M_sun
white dwarf models during the crystallization phase, and we found that the
energy released by carbon-oxygen phase separation is smaller when the new phase
diagram of Horowitz et al. (2010) is used. This translates into time delays
that are on average a factor about 2 smaller than those obtained when the phase
diagram of Segretain & Chabrier (1993) is employed. Our results have important
implications for white dwarf cosmochronology, because the cooling ages of very
old white dwarfs are different for the two phase diagrams. This may have a
noticeable impact on the age determinations of very old globular clusters, for
which the white dwarf color-magnitude diagram provides an independent way of
estimating their age.
View original:
http://arxiv.org/abs/1110.5665
No comments:
Post a Comment