David A. Chamulak scite author profile

We present a theoretical framework for formal study of systematic effects in Supernovae Type Ia (SN Ia) that utilizes two-dimensional simulations to implement a form of the deflagration-detonation transition (DDT) explosion scenario. The framework is developed from a randomized initial condition that leads to a sample of simulated SN Ia whose 56 Ni masses have a similar average and range to those observed, and have many other modestly realistic features such the velocity extent of intermediate mass elements. The intended purpose is to enable statistically well-defined studies of both physical and theoretical parameters of the SN Ia explosion simulation. We present here a thorough description of the outcome of the SN Ia explosions produced by our current simulations.A first application of this framework is utilized to study the dependence of the SN Ia on the 22 Ne content, which is known to be directly influenced by the progenitor stellar population's metallicity. Our study is very specifically tailored to measure how the 22 Ne content influences the competition between the rise of plumes of burned material and the expansion of the star before these plumes reach DDT conditions. This influence arises from the dependence of the energy release, progenitor structure and laminar flame speed on 22 Ne content. For this study, we explore these three effects for a fixed carbon content and DDT density. By setting the density at which nucleosynthesis takes place during the detonation phase of the explosion, the competition between plume rise and stellar expansion controls the amount of material in nuclear statistical equilibrium (NSE) and therefore 56 Ni produced. Of particular interest is how this influence of 22 Ne content compares to the direct modification of the 56 Ni mass via the inherent neutron excess as discussed by Timmes, Brown & Truran (2003). Although the outcome following from any particular ignition condition can change dramatically with 22 Ne content, with a sample of 20 ignition conditions we find that the systematic change in the expansion of the star prior to detonation is not large enough to compete with the dependence discussed by Timmes, . In fact, our results show no statistically significant dependence of the pre-detonation expansion on 22 Ne content, pointing to the morphology of the ignition condition as being the dominant dynamical driver of the 56 Ni yield of the explosion. However, variations in the DDT density, which were specifically excluded here, are also expected to be important and to depend systematically on 22 Ne content.

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The Reduction of the Electron Abundance during the Pre‐explosion Simmering in White Dwarf Supernovae

Chamulak

Brown

Timmes

et al. 2008

ApJ

127

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Prior to the explosion of a carbon-oxygen white dwarf in a Type Ia supernova there is a long ''simmering,'' during which the 12 C þ 12 C reaction gradually heats the white dwarf on a long ($10 3 yr) timescale. Piro & Bildsten showed that weak reactions during this simmering set a maximum electron abundance Y e at the time of the explosion. We investigate the nuclear reactions during this simmering with a series of self-heating, at constant pressure, reaction network calculations. Unlike in AGB stars, p captures onto 22 Ne and heavier trace nuclei do not play a significant role. The 12 C abundance is sufficiently high that the neutrons preferentially capture onto 12 C, rather than iron group nuclei. As an aid to hydrodynamical simulations of the simmering phase, we present fits to the rates of heating, electron capture, change in mean atomic mass, and consumption of 12 C in terms of the screened thermally averaged cross section for 12 C þ 12 C. Our evaluation of the net heating rate includes contributions from electron captures into the 3.68 MeV excited state of 13 C. This results in a slightly larger energy release, per 12 C consumed, than that found by Piro & Bildsten, but less than that released for a burn to only 20 Ne and 23 Na. We compare our one-zone results to more accurate integrations over the white dwarf structure to estimate the amount of 12 C that must be consumed to raise the white dwarf temperature, and hence to determine the net reduction of Y e during simmering.

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EVALUATING SYSTEMATIC DEPENDENCIES OF TYPE Ia SUPERNOVAE: THE INFLUENCE OF DEFLAGRATION TO DETONATION DENSITY

Jackson¹,

Calder²,

Townsley³

et al. 2010

ApJ

108

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The Laminar Flame Speedup by ²² Ne Enrichment in White Dwarf Supernovae

Chamulak

Brown

Timmes

2007

ApJ

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Carbon-oxygen white dwarfs contain 22 Ne formed from α-captures onto 14 N during core He burning in the progenitor star. In a white dwarf (type Ia) supernova, the 22 Ne abundance determines, in part, the neutronto-proton ratio and hence the abundance of radioactive 56 Ni that powers the lightcurve. The 22 Ne abundance also changes the burning rate and hence the laminar flame speed. We tabulate the flame speedup for different initial 12 C and 22 Ne abundances and for a range of densities. This increase in the laminar flame speed-about 30% for a 22 Ne mass fraction of 6%-affects the deflagration just after ignition near the center of the white dwarf, where the laminar speed of the flame dominates over the buoyant rise, and in regions of lower density ∼ 10 7 g cm −3 where a transition to distributed burning is conjectured to occur. The increase in flame speed will decrease the density of any transition to distributed burning.

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David A. Chamulak

EVALUATING SYSTEMATIC DEPENDENCIES OF TYPE Ia SUPERNOVAE: THE INFLUENCE OF PROGENITOR²²Ne CONTENT ON DYNAMICS

The Reduction of the Electron Abundance during the Pre‐explosion Simmering in White Dwarf Supernovae

EVALUATING SYSTEMATIC DEPENDENCIES OF TYPE Ia SUPERNOVAE: THE INFLUENCE OF DEFLAGRATION TO DETONATION DENSITY

The Laminar Flame Speedup by ²² Ne Enrichment in White Dwarf Supernovae

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David A. Chamulak

EVALUATING SYSTEMATIC DEPENDENCIES OF TYPE Ia SUPERNOVAE: THE INFLUENCE OF PROGENITOR22Ne CONTENT ON DYNAMICS

The Reduction of the Electron Abundance during the Pre‐explosion Simmering in White Dwarf Supernovae

EVALUATING SYSTEMATIC DEPENDENCIES OF TYPE Ia SUPERNOVAE: THE INFLUENCE OF DEFLAGRATION TO DETONATION DENSITY

The Laminar Flame Speedup by 22 Ne Enrichment in White Dwarf Supernovae

Contact Info

Product

Resources

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EVALUATING SYSTEMATIC DEPENDENCIES OF TYPE Ia SUPERNOVAE: THE INFLUENCE OF PROGENITOR²²Ne CONTENT ON DYNAMICS

The Laminar Flame Speedup by ²² Ne Enrichment in White Dwarf Supernovae