FINAL EVOLUTION AND DELAYED EXPLOSIONS OF SPINNING WHITE DWARFS IN SINGLE DEGENERATE MODELS FOR TYPE Ia SUPERNOVAE

ABSTRACT We study the occurrence of delayed SNe Ia in the single degenerate scenario. We assume that a massive carbon-oxygen (CO) white dwarf (WD) accretes matter coming from a companion star, making it spin at the critical rate. We assume uniform rotation due to magnetic field coupling. The carbon...

Full description

Saved in:
Bibliographic Details
Published in:Astrophysical journal. Letters 2015-08, Vol.809 (1), p.1-5
Main Authors: Benvenuto, Omar G., Panei, Jorge A., Nomoto, Ken'ichi, Kitamura, Hikaru, Hachisu, Izumi
Format: Article
Language:English
Subjects:
Angular momentum
binaries: close
Carbon
Companion stars
Delay
Explosions
Ignition
nuclear reactions, nucleosynthesis, abundances
stars: rotation
supernovae: general
Texts
White dwarf stars
white dwarfs
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:ABSTRACT We study the occurrence of delayed SNe Ia in the single degenerate scenario. We assume that a massive carbon-oxygen (CO) white dwarf (WD) accretes matter coming from a companion star, making it spin at the critical rate. We assume uniform rotation due to magnetic field coupling. The carbon ignition mass for non-rotating WDs is , while for the case of uniformly rotating WDs it is a few percent larger ( ). When accretion rate decreases, the WD begins to lose angular momentum, shrinks, and spins up; however, it does not overflow its critical rotation rate, avoiding mass shedding. Thus, angular momentum losses can lead the CO WD interior to compression and carbon ignition, which would induce an SN Ia. The delay, largely due to the angular momentum losses timescale, may be large enough to allow the companion star to evolve to a He WD, becoming undetectable at the moment of explosion. This scenario supports the occurrence of delayed SNe Ia if the final CO WD mass is . We also find that if the delay is longer than ∼3 Gyr, the WD would become too cold to explode, rather undergoing collapse.
ISSN:2041-8205
2041-8213
DOI:10.1088/2041-8205/809/1/L6