J. Jose1,2
Abstract.
Classical nova outbursts are thermonuclear stellar explosions
driven by charged-particle reactions. Extensive numerical simulations of nova explosions have
shown that the accreted envelopes attain peak temperatures ranging between 0.1 and 0.4 GK, for about
several hundred seconds, and therefore, their ejecta is expected to show signatures of
nuclear processing. Indeed, it has been claimed that novae play some role in the
enrichment of the interstellar medium in a number of intermediate-mass elements. This
includes 17O, 15N, and 13C, significantly overproduced with respect to solar
abundances, and a lower contribution to a number of species with A<40, such as 7i, 19F, or
26. In this paper, we review the modeling of classical nova outbursts, from
spherically-symmetric (1D) hydrodynamic models to recent multidimensional simulations.
The predicted nucleosynthesis accompanying nova outbursts is briefly compared with the abundances
determined in meteoritic presolar grains of putative nova origin. The impact of current nuclear uncertainties
on the final yields is also outlined.
Keywords: accretion, accretion disks -- convection -- hydrodynamics -- nuclear
reactions, nucleosynthesis, abundances -- stars: novae, cataclysmic variables -- white dwarfs
1Dept. Fisica i Enginyeria Nuclear, EUETIB, Universitat Politecnica de Catalunya, E-08036 Barcelona
2Institut d'Estudis Espacials de Catalunya, E-08034 Barcelona, Spain