2005A&A...435..967Y


C.D.S. - SIMBAD4 rel 1.7 - 2021.03.01CET21:44:24

2005A&A...435..967Y - Astronomy and Astrophysics, volume 435, 967-985 (2005/6-1)

On the evolution of rapidly rotating massive white dwarfs towards supernovae or collapses.

YOON S.-C. and LANGER N.

Abstract (from CDS):

A recent study indicated that the inner cores of rapidly accreting ({dot}(M)>10–7M/yr) CO white dwarfs may rotate differentially, with a shear rate near the threshold value for the onset of the dynamical shear instability. Such differentially rotating white dwarfs have critical masses for thermonuclear explosion or electron-capture induced collapse that significantly exceed the canonical Chandrasekhar limit. Here, we construct two-dimensional differentially rotating white dwarf models with rotation laws resembling those of the one-dimensional models of the previous work. We derive analytic relations between the white dwarf mass, its angular momentum, and its rotational-, gravitational- and binding energy. We show that these relations are applicable for a wide range of angular velocity profiles, including solid body rotation. Taken at a central density of 2x109g/cm3 they specify initial models for the thermonuclear explosion of rotating CO white dwarfs. At ρc=1010g/cm3 and 4x109g/cm3, they give criteria for the electron-capture induced collapse of rotating CO and ONeMg white dwarfs, respectively. We demonstrate that pre-explosion and pre-collapse conditions of both rigidly and differentially rotating white dwarfs are well established by the present work, which may facilitate future multi-dimensional simulations of type Ia supernova explosions and studies of the formation of millisecond pulsars and gamma-ray bursts from collapsing white dwarfs. Our results lead us to suggest various possible evolutionary scenarios for progenitors of type Ia supernovae, leading to a new paradigm of a variable mass of exploding white dwarfs, at values well above the classical Chandrasekhar mass. Based on our 2D-models, we argue that the supernova peak brightness is proportional to the white dwarf mass, which could explain various aspects of the diversity of type Ia supernovae, such as their variation in brightness, the dependence of their mean luminosity on the host galaxy type, and the weak correlation between ejecta velocity and peak brightness.

Abstract Copyright:

Journal keyword(s): stars: rotation - stars: white dwarfs - stars: neutron - stars: supernovae: general - gamma rays: bursts

Simbad objects: 4

goto Full paper

goto View the reference in ADS

Number of rows : 4

N Identifier Otype ICRS (J2000)
RA
ICRS (J2000)
DEC
Mag U Mag B Mag V Mag R Mag I Sp type #ref
1850 - 2021
#notes
1 SN 2001el SN* 03 44 30.60 -44 38 23.4   12.81       SNIa 243 1
2 SN 1999by SN* 09 21 52.07 +51 00 06.6   13.66       SNIap 262 1
3 SN 1991bg SN* 12 25 03.70 +12 52 15.6   14.75 14.3     SNIapec 537 1
4 SN 1991T SN* 12 34 10.20 +02 39 56.4   11.70 11.51     SNIapec 709 1

    Equat.    Gal    SGal    Ecl

To bookmark this query, right click on this link: simbad:objects in 2005A&A...435..967Y and select 'bookmark this link' or equivalent in the popup menu


2021.03.01-21:44:24

© Université de Strasbourg/CNRS

    • Contact