LOW MACH NUMBER MODELING of CONVECTION in HELIUM SHELLS on SUB-CHANDRASEKHAR WHITE DWARFS. II. BULK PROPERTIES of SIMPLE MODELS

A. M. Jacobs; M. Zingale; A. Nonaka; A. S. Almgren; J. B. Bell

doi:10.3847/0004-637X/827/1/84

LOW MACH NUMBER MODELING of CONVECTION in HELIUM SHELLS on SUB-CHANDRASEKHAR WHITE DWARFS. II. BULK PROPERTIES of SIMPLE MODELS

A. M. Jacobs
, M. Zingale
, A. Nonaka
, A. S. Almgren
, J. B. Bell

Physics and Astronomy

Stony Brook University
Lawrence Berkeley National Laboratory

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

17 Scopus citations

Abstract

The dynamics of helium shell convection driven by nuclear burning establish the conditions for runaway in the sub-Chandrasekhar-mass, double-detonation model for SNe Ia, as well as for a variety of other explosive phenomena. We explore these convection dynamics for a range of white dwarf core and helium shell masses in three dimensions using the low Mach number hydrodynamics code MAESTRO. We present calculations of the bulk properties of this evolution, including time-series evolution of global diagnostics, lateral averages of the 3D state, and the global 3D state. We find a variety of outcomes, including quasi-equilibrium, localized runaway, and convective runaway. Our results suggest that the double-detonation progenitor model is promising and that 3D dynamic convection plays a key role.

Original language	English
Article number	84
Journal	Astrophysical Journal
Volume	827
Issue number	1
DOIs	https://doi.org/10.3847/0004-637X/827/1/84
State	Published - Aug 10 2016

Keywords

convection
hydrodynamics
methods: numerical
nuclear reactions, nucleosynthesis, abundances
supernovae: general
white dwarfs

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10.3847/0004-637X/827/1/84

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title = "LOW MACH NUMBER MODELING of CONVECTION in HELIUM SHELLS on SUB-CHANDRASEKHAR WHITE DWARFS. II. BULK PROPERTIES of SIMPLE MODELS",

abstract = "The dynamics of helium shell convection driven by nuclear burning establish the conditions for runaway in the sub-Chandrasekhar-mass, double-detonation model for SNe Ia, as well as for a variety of other explosive phenomena. We explore these convection dynamics for a range of white dwarf core and helium shell masses in three dimensions using the low Mach number hydrodynamics code MAESTRO. We present calculations of the bulk properties of this evolution, including time-series evolution of global diagnostics, lateral averages of the 3D state, and the global 3D state. We find a variety of outcomes, including quasi-equilibrium, localized runaway, and convective runaway. Our results suggest that the double-detonation progenitor model is promising and that 3D dynamic convection plays a key role.",

keywords = "convection, hydrodynamics, methods: numerical, nuclear reactions, nucleosynthesis, abundances, supernovae: general, white dwarfs",

author = "Jacobs, \{A. M.\} and M. Zingale and A. Nonaka and Almgren, \{A. S.\} and Bell, \{J. B.\}",

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doi = "10.3847/0004-637X/827/1/84",

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AU - Jacobs, A. M.

AU - Zingale, M.

AU - Nonaka, A.

AU - Almgren, A. S.

AU - Bell, J. B.

PY - 2016/8/10

Y1 - 2016/8/10

N2 - The dynamics of helium shell convection driven by nuclear burning establish the conditions for runaway in the sub-Chandrasekhar-mass, double-detonation model for SNe Ia, as well as for a variety of other explosive phenomena. We explore these convection dynamics for a range of white dwarf core and helium shell masses in three dimensions using the low Mach number hydrodynamics code MAESTRO. We present calculations of the bulk properties of this evolution, including time-series evolution of global diagnostics, lateral averages of the 3D state, and the global 3D state. We find a variety of outcomes, including quasi-equilibrium, localized runaway, and convective runaway. Our results suggest that the double-detonation progenitor model is promising and that 3D dynamic convection plays a key role.

AB - The dynamics of helium shell convection driven by nuclear burning establish the conditions for runaway in the sub-Chandrasekhar-mass, double-detonation model for SNe Ia, as well as for a variety of other explosive phenomena. We explore these convection dynamics for a range of white dwarf core and helium shell masses in three dimensions using the low Mach number hydrodynamics code MAESTRO. We present calculations of the bulk properties of this evolution, including time-series evolution of global diagnostics, lateral averages of the 3D state, and the global 3D state. We find a variety of outcomes, including quasi-equilibrium, localized runaway, and convective runaway. Our results suggest that the double-detonation progenitor model is promising and that 3D dynamic convection plays a key role.

KW - convection

KW - hydrodynamics

KW - methods: numerical

KW - nuclear reactions, nucleosynthesis, abundances

KW - supernovae: general

KW - white dwarfs

UR - https://www.scopus.com/pages/publications/84982163103

U2 - 10.3847/0004-637X/827/1/84

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ER -

LOW MACH NUMBER MODELING of CONVECTION in HELIUM SHELLS on SUB-CHANDRASEKHAR WHITE DWARFS. II. BULK PROPERTIES of SIMPLE MODELS

Abstract

Keywords

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