A three-dimensional picture of the delayed-detonation model of type Ia supernovae

Free access article

Issue		A&A Volume 478, Number 3, February II 2008


Page(s)		843 - 853
Section		Stellar structure and evolution
DOI		http://dx.doi.org/10.1051/0004-6361:20078424

A&A 478, 843-853 (2008)
DOI: 10.1051/0004-6361:20078424

A three-dimensional picture of the delayed-detonation model of type Ia supernovae

E. Bravo^{1, 2} and D. García-Senz^{1, 2}

¹ Departament de Física i Enginyeria Nuclear, UPC, Jordi Girona 3, Mòdul B5, 08034 Barcelona, Spain
e-mail: eduardo.bravo@upc.edu
² Institut D'Estudis Espacials de Catalunya, Gran Capità 2-4, 08034 Barcelona, Spain
e-mail: domingo.garcia@upc.edu

(Received 6 August 2007 / Accepted 7 November 2007)

Abstract
Aims.Deflagration models poorly explain the observed diversity of SNIa. Current multidimensional simulations of SNIa predict a significant amount of, so far unobserved, carbon and oxygen moving at low velocities. It has been proposed that these drawbacks can be resolved if there is a sudden jump to a detonation (delayed detonation), but these kinds of models have been explored mainly in one dimension. Here we present new three-dimensional delayed detonation models in which the deflagraton-to-detonation transition (DDT) takes place in conditions like those favored by one-dimensional models.
Methods.We have used a smoothed-particle-hydrodynamics code adapted to follow all the dynamical phases of the explosion, with algorithms devised to handle subsonic as well as supersonic combustion fronts. The starting point was a centrally ignited C-O white dwarf of 1.38 ${M}_{\odot}$ . When the average density on the flame surface reached ~2-3 $\times$ 10⁷ g cm^-3 a detonation was launched.
Results.The detonation wave processed more than 0.3 ${M}_{\odot}$ of carbon and oxygen, emptying the central regions of the ejecta of unburned fuel and raising its kinetic energy close to the fiducial 10⁵¹ erg expected from a healthy type Ia supernova. The final amount of ⁵⁶Ni synthesized also was in the correct range. However, the mass of carbon and oxygen ejected is still too high.
Conclusions.The three-dimensional delayed detonation models explored here show an improvement over pure deflagration models, but they still fail to coincide with basic observational constraints. However, there are many aspects of the model that are still poorly known (geometry of flame ignition, mechanism of DDT, properties of detonation waves traversing a mixture of fuel and ashes). Therefore, it will be worth pursuing its exploration to see if a good SNIa model based on the three-dimensional delayed detonation scenario can be obtained.

Key words: hydrodynamics -- nuclear reactions, nucleosynthesis, abundances -- shock waves -- stars: evolution -- white dwarfs -- supernovae: general

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