TY - JOUR

T1 - Nucleosynthesis during a Thermonuclear Supernova Explosion

AU - Panov, I. V.

AU - Glazyrin, S. I.

AU - Röpke, F. K.

AU - Blinnikov, S. I.

N1 - Publisher Copyright: © 2018, Pleiades Publishing, Inc.

PY - 2018/5/1

Y1 - 2018/5/1

N2 - Supernovae are such bright objects that they can be observed even at high redshifts. Some types of such events, for example, type Ia (thermonuclear), have peculiarities of the light curve, which allows them to be used for cosmological applications. The light curve is determined by the details of the explosion dynamics and nucleosynthesis: in particular, it depends on the amount of iron-peak elements produced during the explosion. We discuss the burning processes in such objects and the peculiarities of turbulence simulations in them, which is needed for a proper hydrodynamic description of the explosion process. A direct nucleosynthesis calculation is performed for the temperature and density profiles derived in the available 3D hydrodynamic explosion simulations. We show that in the supernova progenitor model considered the calculated abundances of elements from carbon to iron-peak elements are in good agreement both with the observations and with the calculations of other authors. At the same time, no r-elements are produced even at the maximum neutron excess for this model (Ye ~ 0.47) due to the slow evolution of the density and temperature.

AB - Supernovae are such bright objects that they can be observed even at high redshifts. Some types of such events, for example, type Ia (thermonuclear), have peculiarities of the light curve, which allows them to be used for cosmological applications. The light curve is determined by the details of the explosion dynamics and nucleosynthesis: in particular, it depends on the amount of iron-peak elements produced during the explosion. We discuss the burning processes in such objects and the peculiarities of turbulence simulations in them, which is needed for a proper hydrodynamic description of the explosion process. A direct nucleosynthesis calculation is performed for the temperature and density profiles derived in the available 3D hydrodynamic explosion simulations. We show that in the supernova progenitor model considered the calculated abundances of elements from carbon to iron-peak elements are in good agreement both with the observations and with the calculations of other authors. At the same time, no r-elements are produced even at the maximum neutron excess for this model (Ye ~ 0.47) due to the slow evolution of the density and temperature.

KW - beta decay

KW - nuclear astrophysics

KW - nuclear reactions

KW - nucleosynthesis

KW - supernovae and supernova remnants

KW - SHELL

KW - SUBGRID SCALE-MODEL

KW - FLUID DYNAMICAL SIMULATIONS

KW - IA SUPERNOVAE

KW - FRONT PROPAGATION

KW - ELEMENTS

KW - ASTROPHYSICS

KW - reactions

KW - nuclear

KW - CHANDRASEKHAR-MASS MODELS

KW - DELAYED-DETONATION MODELS

UR - http://www.scopus.com/inward/record.url?scp=85047497836&partnerID=8YFLogxK

U2 - 10.1134/S1063773718050031

DO - 10.1134/S1063773718050031

M3 - Article

AN - SCOPUS:85047497836

VL - 44

SP - 309

EP - 314

JO - Astronomy Letters

JF - Astronomy Letters

SN - 1063-7737

IS - 5

ER -