We present a detailed computational study of the assembly of protostellar disks and massive stars in molecular clouds with supersonic turbulence. We follow the evolution of large scale filamentary structures in a cluster-forming clump down to protostellar length scales by means of very highly resolved, 3D adaptive mesh refined (AMR) simulations, and show how accretion disks and massive stars form in such environments. We find that an initially elongated cloud core which has a slight spin from oblique shocks collapses first to a filament and later develops a turbulent disk close to the center of the filament. The continued large scale flow that shocks with the filament maintains the high density and pressure within it. Material within the co...
Context. Massive stars are generally believed to form in environments characterized by supersonic tu...
Protostellar outflows crisscross the regions of star cluster formation, stirring turbulence and alte...
We review the properties of turbulent molecular clouds (MCs), focusing on the physical processes tha...
Observations indicate that massive stars in the Galaxy form in regions of very high surface density,...
International audienceContext. Massive stars form in magnetized and turbulent environments and are o...
We present hydrodynamic simulations of self-gravitating dense gas in a galactic disk, exploring scal...
We present an investigation of massive star formation that results from the gravitational collapse o...
Attention is given to computer simulations of massive protostar formation which show that in regions...
We investigate massive star formation in turbulent, magnetized, parsec-scale clumps of molecular clo...
Turbulence is thought to be a primary driving force behind the early stages of star formation. In th...
We investigate giant molecular cloud (GMCs) collisions and their ability to induce gravitational ins...
The star formation process involves a wide range of spatial scales, densities and temperatures. Hers...
We present hydrodynamic simulations of self-gravitating dense gas in a galactic disk, exploring scal...
Massive stars regulate the physical and chemical evolution of galaxies. Most stars\ua0within these g...
Context. Massive stars are generally believed to form in environments characterized by supersonic tu...
Protostellar outflows crisscross the regions of star cluster formation, stirring turbulence and alte...
We review the properties of turbulent molecular clouds (MCs), focusing on the physical processes tha...
Observations indicate that massive stars in the Galaxy form in regions of very high surface density,...
International audienceContext. Massive stars form in magnetized and turbulent environments and are o...
We present hydrodynamic simulations of self-gravitating dense gas in a galactic disk, exploring scal...
We present an investigation of massive star formation that results from the gravitational collapse o...
Attention is given to computer simulations of massive protostar formation which show that in regions...
We investigate massive star formation in turbulent, magnetized, parsec-scale clumps of molecular clo...
Turbulence is thought to be a primary driving force behind the early stages of star formation. In th...
We investigate giant molecular cloud (GMCs) collisions and their ability to induce gravitational ins...
The star formation process involves a wide range of spatial scales, densities and temperatures. Hers...
We present hydrodynamic simulations of self-gravitating dense gas in a galactic disk, exploring scal...
Massive stars regulate the physical and chemical evolution of galaxies. Most stars\ua0within these g...
Context. Massive stars are generally believed to form in environments characterized by supersonic tu...
Protostellar outflows crisscross the regions of star cluster formation, stirring turbulence and alte...
We review the properties of turbulent molecular clouds (MCs), focusing on the physical processes tha...