We investigate the structure of laterally propagating flames through the highly stratified burning layer in an X-ray burst. Two-dimensional hydrodynamics simulations of flame propagation are performed through a rotating plane-parallel atmosphere, exploring the structure of the flame. We discuss the approximations needed to capture the length and timescales at play in an X-ray burst and describe the flame acceleration observed. Our studies complement other multidimensional studies of burning in X-ray bursts
Various premixed flame phenomena are studied by means of direct numerical simulations of the complet...
We extend the Michelson – Sivashinsky equation, for arbitrary gas density ratio, to model the dynami...
International audienceAn experimental study of vibrating flames above a cylindrical burner has been ...
We continue to investigate two-dimensional laterally propagating flames in type I X-ray bursts using...
We present the first realistic 3D simulations of flame front instabilities during type I X-ray burst...
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 discuss the challenges of modeling X-ray bursts in multi-dimensions, review the different calcula...
Type I X-ray bursts are thermonuclear explosions on the surfaces of neutron stars that can be used t...
A numerical technique for the simulation of accelerating turbulent premixed flames in large scale ge...
The flame velocities of unconfined gas explosions depend on the cloud size and the distance from the...
We analyze the global hydrodynamic flow in the ocean of an accreting, rapidly rotating, nonmagnetic ...
International audienceFlames propagating in a Hele-Shaw burner are often quasi two-dimensional and c...
High frequency (30 Hz) two-dimensional particle image velocimetry data recorded during a field ...
The combustion of hydrocarbon based fuels is one of the worlds main sources of energy, with applicat...
Various premixed flame phenomena are studied by means of direct numerical simulations of the complet...
We extend the Michelson – Sivashinsky equation, for arbitrary gas density ratio, to model the dynami...
International audienceAn experimental study of vibrating flames above a cylindrical burner has been ...
We continue to investigate two-dimensional laterally propagating flames in type I X-ray bursts using...
We present the first realistic 3D simulations of flame front instabilities during type I X-ray burst...
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 discuss the challenges of modeling X-ray bursts in multi-dimensions, review the different calcula...
Type I X-ray bursts are thermonuclear explosions on the surfaces of neutron stars that can be used t...
A numerical technique for the simulation of accelerating turbulent premixed flames in large scale ge...
The flame velocities of unconfined gas explosions depend on the cloud size and the distance from the...
We analyze the global hydrodynamic flow in the ocean of an accreting, rapidly rotating, nonmagnetic ...
International audienceFlames propagating in a Hele-Shaw burner are often quasi two-dimensional and c...
High frequency (30 Hz) two-dimensional particle image velocimetry data recorded during a field ...
The combustion of hydrocarbon based fuels is one of the worlds main sources of energy, with applicat...
Various premixed flame phenomena are studied by means of direct numerical simulations of the complet...
We extend the Michelson – Sivashinsky equation, for arbitrary gas density ratio, to model the dynami...
International audienceAn experimental study of vibrating flames above a cylindrical burner has been ...