The convective phase preceding type Ia supernovae

M. Zingale; A. Nonaka; A. S. Almgren; J. B. Bell; C. M. Malone; S. E. Woosley

doi:10.1088/0004-637X/740/1/8

The convective phase preceding type Ia supernovae

M. Zingale
, A. Nonaka
, A. S. Almgren
, J. B. Bell
, C. M. Malone
, S. E. Woosley

Physics and Astronomy

Lawrence Berkeley National Laboratory
Stony Brook University
University of California at Santa Cruz

Research output: Contribution to journal › Article › peer-review

40 Scopus citations

Abstract

The convective flow in the moments preceding the explosion of a Type Ia supernova determines where the initial flames that subsequently burn through the star first ignite. We continue our exploration of the final hours of this convection using the low Mach number hydrodynamics code, MAESTRO. We present calculations exploring the effects of slow rotation and show diagnostics that examine the distribution of likely ignition points. In the current calculations, we see a well-defined convection region persist up to the point of ignition, and we see that even a little rotation is enough to break the coherence of the convective flow seen in the radial velocity field. Our results suggest that off-center ignition may be favored, with ignition ranging out to a radius of 100km and a maximum likelihood of ignition at a radius around 50km.

Original language	English
Article number	8
Journal	Astrophysical Journal
Volume	740
Issue number	1
DOIs	https://doi.org/10.1088/0004-637X/740/1/8
State	Published - Oct 10 2011

Keywords

abundances
Convection
general
hydrodynamics
methods
nuclear reactions
nucleosynthesis
numerical
supernovae
white dwarfs

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10.1088/0004-637X/740/1/8

Cite this

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title = "The convective phase preceding type Ia supernovae",

abstract = "The convective flow in the moments preceding the explosion of a Type Ia supernova determines where the initial flames that subsequently burn through the star first ignite. We continue our exploration of the final hours of this convection using the low Mach number hydrodynamics code, MAESTRO. We present calculations exploring the effects of slow rotation and show diagnostics that examine the distribution of likely ignition points. In the current calculations, we see a well-defined convection region persist up to the point of ignition, and we see that even a little rotation is enough to break the coherence of the convective flow seen in the radial velocity field. Our results suggest that off-center ignition may be favored, with ignition ranging out to a radius of 100km and a maximum likelihood of ignition at a radius around 50km.",

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AU - Zingale, M.

AU - Nonaka, A.

AU - Almgren, A. S.

AU - Bell, J. B.

AU - Malone, C. M.

AU - Woosley, S. E.

PY - 2011/10/10

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AB - The convective flow in the moments preceding the explosion of a Type Ia supernova determines where the initial flames that subsequently burn through the star first ignite. We continue our exploration of the final hours of this convection using the low Mach number hydrodynamics code, MAESTRO. We present calculations exploring the effects of slow rotation and show diagnostics that examine the distribution of likely ignition points. In the current calculations, we see a well-defined convection region persist up to the point of ignition, and we see that even a little rotation is enough to break the coherence of the convective flow seen in the radial velocity field. Our results suggest that off-center ignition may be favored, with ignition ranging out to a radius of 100km and a maximum likelihood of ignition at a radius around 50km.

KW - abundances

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KW - general

KW - hydrodynamics

KW - methods

KW - nuclear reactions

KW - nucleosynthesis

KW - numerical

KW - supernovae

KW - white dwarfs

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The convective phase preceding type Ia supernovae

Abstract

Keywords

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