Add to ORKGThe gas from which stars form is magnetized, and strong magnetic fields can efficiently transport angular momentum. Most theoretical models of this phenomenon find that it should prevent formation of large (> 100 AU), rotationally-supported disks around most protostars, even when non-ideal magnetohydrodynamic (MHD) effects that allow the field and gas to decouple are taken into account. Using recent observations of magnetic field strengths and orientations in protostellar cores, we show that this conclusion is incorrect. The distribution of magnetic field strengths is very broad, and alignments between fields and angular momentum vectors within protostellar cores are essentially random. By combining the field strength and misalignment da...
This is the final published version, also available from Oxford University Press via the DOI in this...
Stars are born in turbulent, magnetized filamentary molecular clouds, typically as members of star c...
Star formation is thought to be triggered by gravitational collapse of the dense cores of molecular ...
The formation of a protostellar disc is a natural outcome during the star formation process. As gas ...
International audienceContext: In the context of star and planet formation, understanding the format...
The formation of a protostellar disc is a natural outcome during the star formation process. As gas ...
Aims. The main goal of the following analysis is to assess the potential role of magnetic fields in ...
We present results of λ1.3 mm dust-polarization observations toward 16 nearby, low-mass protostars, ...
Protoplanetary discs are flattened discs of gas and dust surrounding young stars that are believed t...
Published onlineThis is the final version of the article. Available from Oxford University Press via...
We present results of λ1.3 mm dust-polarization observations toward 16 nearby, low-mass protostars, ...
We present results from the first radiation non-ideal magnetohydrodynamics (MHD) simulations of low-...
Theoretically, misalignment between the magnetic field and rotational axis in a dense core is consid...
Theoretically, misalignment between the magnetic field and rotational axis in a dense core is consid...
This is the final published version, also available from Oxford University Press via the DOI in this...
Stars are born in turbulent, magnetized filamentary molecular clouds, typically as members of star c...
Star formation is thought to be triggered by gravitational collapse of the dense cores of molecular ...
The formation of a protostellar disc is a natural outcome during the star formation process. As gas ...
International audienceContext: In the context of star and planet formation, understanding the format...
The formation of a protostellar disc is a natural outcome during the star formation process. As gas ...
Aims. The main goal of the following analysis is to assess the potential role of magnetic fields in ...
We present results of λ1.3 mm dust-polarization observations toward 16 nearby, low-mass protostars, ...
Protoplanetary discs are flattened discs of gas and dust surrounding young stars that are believed t...
Published onlineThis is the final version of the article. Available from Oxford University Press via...
We present results of λ1.3 mm dust-polarization observations toward 16 nearby, low-mass protostars, ...
We present results from the first radiation non-ideal magnetohydrodynamics (MHD) simulations of low-...
Theoretically, misalignment between the magnetic field and rotational axis in a dense core is consid...
Theoretically, misalignment between the magnetic field and rotational axis in a dense core is consid...
This is the final published version, also available from Oxford University Press via the DOI in this...
Stars are born in turbulent, magnetized filamentary molecular clouds, typically as members of star c...
Star formation is thought to be triggered by gravitational collapse of the dense cores of molecular ...