We report the results of a series of AMR radiation-hydrodynamic simulations of the collapse of massive star forming clouds using the ORION code. These simulations are the first to include the feedback effects protostellar outflows, as well as protostellar radiative heating and radiation pressure exerted on the infalling, dusty gas. We find that that outflows evacuate polar cavities of reduced optical depth through the ambient core. These enhance the radiative flux in the poleward direction so that it is 1.7 to 15 times larger than that in the midplane. As a result the radiative heating and outward radiation force exerted on the protostellar disk and infalling cloud gas in the equatorial direction are greatly diminished. The simultaneously r...
International audienceContext. Radiative transfer plays a major role in the process of star formatio...
The fragmentation of star-forming interstellar clouds, and the resulting stellar initial mass functi...
The collapse of star-forming molecular clouds depends critically on radiation feedback from embedded...
We report the results of a series of AMR radiation-hydrodynamic simulations of the collapse of massi...
Aims. We present the first simulations of the formation and feedback of massive stars which account ...
We investigate the radiation pressure feedback in the formation of massive stars in 1, 2, and 3D rad...
We consider the effects of an outflow on radiation escaping from the infalling envelope around a mas...
Stellar feedback in the form of radiation pressure and magnetically driven collimated outflows may l...
We present radiation hydrodynamic simulations of the collapse of massive pre-stellar cores. We treat...
International audienceContext. Star formation begins with the gravitational collapse of a d...
Context. Star formation begins with the gravitational collapse of a dense core inside a mo...
The fragmentation of star-forming interstellar clouds, and the resulting stellar initial mass functi...
We present radiation hydrodynamics simulations of the collapse of massive pre-stellar cores. We trea...
We simulate the early stages of the evolution of turbulent, virialized, high-mass protostellar cores...
International audienceContext. Radiative transfer plays a major role in the process of star formatio...
The fragmentation of star-forming interstellar clouds, and the resulting stellar initial mass functi...
The collapse of star-forming molecular clouds depends critically on radiation feedback from embedded...
We report the results of a series of AMR radiation-hydrodynamic simulations of the collapse of massi...
Aims. We present the first simulations of the formation and feedback of massive stars which account ...
We investigate the radiation pressure feedback in the formation of massive stars in 1, 2, and 3D rad...
We consider the effects of an outflow on radiation escaping from the infalling envelope around a mas...
Stellar feedback in the form of radiation pressure and magnetically driven collimated outflows may l...
We present radiation hydrodynamic simulations of the collapse of massive pre-stellar cores. We treat...
International audienceContext. Star formation begins with the gravitational collapse of a d...
Context. Star formation begins with the gravitational collapse of a dense core inside a mo...
The fragmentation of star-forming interstellar clouds, and the resulting stellar initial mass functi...
We present radiation hydrodynamics simulations of the collapse of massive pre-stellar cores. We trea...
We simulate the early stages of the evolution of turbulent, virialized, high-mass protostellar cores...
International audienceContext. Radiative transfer plays a major role in the process of star formatio...
The fragmentation of star-forming interstellar clouds, and the resulting stellar initial mass functi...
The collapse of star-forming molecular clouds depends critically on radiation feedback from embedded...