We study numerically the formation of molecular clouds in large-scale colliding flows including self-gravity. The models emphasize the competition between the effects of gravity on global and local scales in an isolated cloud. Global gravity builds up large-scale filaments, while local gravity, triggered by a combination of strong thermal and dynamical instabilities, causes cores to form. The dynamical instabilities give rise to a local focusing of the colliding flows, facilitating the rapid formation of massive protostellar cores of a few hundred M⊙. The forming clouds do not reach an equilibrium state, although the motions within the clouds appear to be comparable to virial. The self-similar core mass distributions derived from models wit...
We review the properties of turbulent molecular clouds (MCs), focusing on the physical processes tha...
We study the effect of magnetic field on massive dense core formation in colliding unequal molecular...
Context. Massive stars live short but intense lives. While less numerous than low-mass stars, they e...
We study numerically the formation of molecular clouds in large-scale colliding flows including self...
Observational evidence from local star-forming regions mandates that star formation occurs shortly a...
In this thesis we present a unified model for dense core formation and collapse within post-shock de...
We study the formation of giant dense cloud complexes and of stars within them using SPH numerical s...
The observed rapid onset of star formation in molecular clouds requires rapid formation of dense fra...
In this thesis we present a unified model for dense core formation and collapse within post-shock d...
The fragmentation of shocked flows in a thermally bistable medium provides a natural mechanism to fo...
Observations indicate that massive stars in the Galaxy form in regions of very high surface density,...
Context. Low-mass star-forming cores differ from their surrounding molecular cloud in turbulence, sh...
Molecular Cloud Complexes (MCCs) are highly structured and ``turbulent''. Observational evidence sug...
Recent observations of molecular clouds around rich massive star clusters including NGC3603, Westerl...
The fragmentation of shocked flows in a thermally bistable medium provides a natural mechanism to fo...
We review the properties of turbulent molecular clouds (MCs), focusing on the physical processes tha...
We study the effect of magnetic field on massive dense core formation in colliding unequal molecular...
Context. Massive stars live short but intense lives. While less numerous than low-mass stars, they e...
We study numerically the formation of molecular clouds in large-scale colliding flows including self...
Observational evidence from local star-forming regions mandates that star formation occurs shortly a...
In this thesis we present a unified model for dense core formation and collapse within post-shock de...
We study the formation of giant dense cloud complexes and of stars within them using SPH numerical s...
The observed rapid onset of star formation in molecular clouds requires rapid formation of dense fra...
In this thesis we present a unified model for dense core formation and collapse within post-shock d...
The fragmentation of shocked flows in a thermally bistable medium provides a natural mechanism to fo...
Observations indicate that massive stars in the Galaxy form in regions of very high surface density,...
Context. Low-mass star-forming cores differ from their surrounding molecular cloud in turbulence, sh...
Molecular Cloud Complexes (MCCs) are highly structured and ``turbulent''. Observational evidence sug...
Recent observations of molecular clouds around rich massive star clusters including NGC3603, Westerl...
The fragmentation of shocked flows in a thermally bistable medium provides a natural mechanism to fo...
We review the properties of turbulent molecular clouds (MCs), focusing on the physical processes tha...
We study the effect of magnetic field on massive dense core formation in colliding unequal molecular...
Context. Massive stars live short but intense lives. While less numerous than low-mass stars, they e...