A comparison of accretion and (turbulent) magnetic diffusion time-scales for sheets and filaments demonstrates that dense star-forming clouds generally will – under realistic conditions – become supercritical due to mass accretion on time-scales at least an order of magnitude shorter than ambipolar and/or turbulent diffusion time-scales. Thus, ambipolar or turbulent diffusion – while present – is unlikely to control the formation of cores and stars
Simulations generally show that non-self-gravitating clouds have a lognormal column density (Σ) prob...
Magnetorotational instability (MRI) is the most promising mechanism behind accretion in low-mass pro...
The formation of protostellar disks out of molecular cloud cores is still not fully understood. Unde...
A comparison of accretion and (turbulent) magnetic diffusion time-scales for sheets and filaments de...
We revisit the problem of the star formation timescale and the ages of molecular clouds. The apparen...
In the present-day universe, magnetic fields play such essential roles in star formation as angular ...
In this paper, we provide a more accurate description of the evolution of the magnetic flux redistri...
International audienceWe investigate the formation and evolution of giant molecular clouds (GMCs) by...
The formation of stars is a fundamental unsolved problem in astrophysics. Interstellar molecular clo...
Observations indicate that massive stars in the Galaxy form in regions of very high surface density,...
We revisit the problem of the formation of dense protostellar cores due to ambipolar diffusion withi...
94 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1983.The formulation of a theory of...
Star formation is inefficient. Only a fewper cent of the available gas in molecular clouds forms sta...
We present hydrodynamic simulations of the evolution of self-gravitating dense gas on scales of 1 kp...
We present results from the first radiation non-ideal magnetohydrodynamics (MHD) simulations of low-...
Simulations generally show that non-self-gravitating clouds have a lognormal column density (Σ) prob...
Magnetorotational instability (MRI) is the most promising mechanism behind accretion in low-mass pro...
The formation of protostellar disks out of molecular cloud cores is still not fully understood. Unde...
A comparison of accretion and (turbulent) magnetic diffusion time-scales for sheets and filaments de...
We revisit the problem of the star formation timescale and the ages of molecular clouds. The apparen...
In the present-day universe, magnetic fields play such essential roles in star formation as angular ...
In this paper, we provide a more accurate description of the evolution of the magnetic flux redistri...
International audienceWe investigate the formation and evolution of giant molecular clouds (GMCs) by...
The formation of stars is a fundamental unsolved problem in astrophysics. Interstellar molecular clo...
Observations indicate that massive stars in the Galaxy form in regions of very high surface density,...
We revisit the problem of the formation of dense protostellar cores due to ambipolar diffusion withi...
94 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1983.The formulation of a theory of...
Star formation is inefficient. Only a fewper cent of the available gas in molecular clouds forms sta...
We present hydrodynamic simulations of the evolution of self-gravitating dense gas on scales of 1 kp...
We present results from the first radiation non-ideal magnetohydrodynamics (MHD) simulations of low-...
Simulations generally show that non-self-gravitating clouds have a lognormal column density (Σ) prob...
Magnetorotational instability (MRI) is the most promising mechanism behind accretion in low-mass pro...
The formation of protostellar disks out of molecular cloud cores is still not fully understood. Unde...
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