Class
Article
College
College of Science
Department
English Department
Faculty Mentor
Charles Torre
Presentation Type
Oral Presentation
Abstract
A type Ia supernova can result from the double detonation of a white dwarf star below the Chandrasekhar mass limit. Using the hydrodynamics code Castro, we simulate this detonation by perturbing a carbon/oxygen white dwarf with an accumulated shell of helium, with a small amount of nitrogen-14. In this work, we investigate the robustness of the model. Adjusting the location of the perturbation affects whether detonation occurs. Changing the composition of the helium shell affects the speed at which it burns. The size of the reaction network used affects whether the star's core burns immediately or from a shock wave from the shell. This last result is particularly notable, as it indicates that using reaction networks which leave out heavier elements may be an oversimplification, producing results with significant disparities from more thorough simulations.
Location
Logan, UT
Start Date
4-8-2022 12:00 AM
Included in
Detonation of a White Dwarf Star: Simulations of the Sub-Chandrasekhar Type 1a Supernovae
Logan, UT
A type Ia supernova can result from the double detonation of a white dwarf star below the Chandrasekhar mass limit. Using the hydrodynamics code Castro, we simulate this detonation by perturbing a carbon/oxygen white dwarf with an accumulated shell of helium, with a small amount of nitrogen-14. In this work, we investigate the robustness of the model. Adjusting the location of the perturbation affects whether detonation occurs. Changing the composition of the helium shell affects the speed at which it burns. The size of the reaction network used affects whether the star's core burns immediately or from a shock wave from the shell. This last result is particularly notable, as it indicates that using reaction networks which leave out heavier elements may be an oversimplification, producing results with significant disparities from more thorough simulations.