We present the first realistic 3D simulations of flame front instabilities during type I X-ray bursts. The unperturbed front is characterized by the balance between the pressure gradient and the Coriolis force of a spinning neutron star (ν = 450 Hz in our case). This balance leads to a fast horizontal velocity field parallel to the flame front. This flow is strongly sheared in the vertical direction. When we perturb the front an instability quickly corrugates the front. We identify this instability as the baroclinic instability. Most importantly, the flame is not disrupted by the instability and there are two major consequences: the overall flame propagation speed is ~10 times faster than in the unperturbed case and distinct flame vortices ...
Flame instability is both important and difficult to understand. Mechanisms of instability are compl...
A Type Ia supernova explosion likely begins as a nuclear runaway near the center of a carbon-oxygen ...
University of Minnesota Ph.D. dissertation. January 2016. Major: Physics. Advisor: Alexander Heger. ...
We continue to investigate two-dimensional laterally propagating flames in type I X-ray bursts using...
We investigate the structure of laterally propagating flames through the highly stratified burning l...
Type I X-ray bursts are produced by thermonuclear runaways that develop on accreting neutron stars. ...
We present the first vertically resolved hydrodynamic simulations of a laterally propagating, deflag...
We present the first vertically resolved hydrodynamic simulations of a laterally propagating, deflag...
We analyze the global hydrodynamic flow in the ocean of an accreting, rapidly rotating, nonmagnetic ...
Flame instabilities play a dominant role in accelerating the burning front to a large fraction of th...
Flame instabilities play a dominant role in accelerating the burning front to a large fraction of t...
Flame instabilities play a dominant role in accelerating the burning front to a large fraction of th...
Flame instabilities play a dominant role in accelerating the burning front to a large fraction of th...
A Type la supernova explosion likely begins as a nuclear runaway near the center of a carbon-oxygen ...
Type I X-ray bursts are thermonuclear explosions on the surfaces of neutron stars that can be used t...
Flame instability is both important and difficult to understand. Mechanisms of instability are compl...
A Type Ia supernova explosion likely begins as a nuclear runaway near the center of a carbon-oxygen ...
University of Minnesota Ph.D. dissertation. January 2016. Major: Physics. Advisor: Alexander Heger. ...
We continue to investigate two-dimensional laterally propagating flames in type I X-ray bursts using...
We investigate the structure of laterally propagating flames through the highly stratified burning l...
Type I X-ray bursts are produced by thermonuclear runaways that develop on accreting neutron stars. ...
We present the first vertically resolved hydrodynamic simulations of a laterally propagating, deflag...
We present the first vertically resolved hydrodynamic simulations of a laterally propagating, deflag...
We analyze the global hydrodynamic flow in the ocean of an accreting, rapidly rotating, nonmagnetic ...
Flame instabilities play a dominant role in accelerating the burning front to a large fraction of th...
Flame instabilities play a dominant role in accelerating the burning front to a large fraction of t...
Flame instabilities play a dominant role in accelerating the burning front to a large fraction of th...
Flame instabilities play a dominant role in accelerating the burning front to a large fraction of th...
A Type la supernova explosion likely begins as a nuclear runaway near the center of a carbon-oxygen ...
Type I X-ray bursts are thermonuclear explosions on the surfaces of neutron stars that can be used t...
Flame instability is both important and difficult to understand. Mechanisms of instability are compl...
A Type Ia supernova explosion likely begins as a nuclear runaway near the center of a carbon-oxygen ...
University of Minnesota Ph.D. dissertation. January 2016. Major: Physics. Advisor: Alexander Heger. ...