Discs, outflows, and feedback in collapsing magnetized cores Journal Articles

abstract

• AbstractThe pre-stellar cores in which low mass stars form are generally well magnetized. Our simulations show that early protostellar discs are massive and experience strong magnetic torques in the form of magnetic braking and protostellar outflows. Simulations of protostellar disk formation suggest that these torques are strong enough to suppress a rotationally supported structure from forming for near critical values of mass-to-flux. We demonstrate through the use of a 3D adaptive mesh refinement code – including cooling, sink particles and magnetic fields – that one produces transient 1000 AU discs while simultaneously generating large outflows which leave the core region, carrying away mass and angular momentum. Early inflow/outflow rates suggest that only a small fraction of the mass is lost in the initial magnetic tower/jet event.

authors

• Duffin, Dennis F
• Pudritz, Ralph Egon

status

• published 

publication date

• May 2010

has subject area

• 0201 Astronomical and Space Sciences (FoR)

published in

• Proceedings of the International Astronomical Union  Journal

keywords

• (magnetohydrodynamics:) MHD
• ACCRETION
• AMBIPOLAR DIFFUSION
• Astronomy & Astrophysics
• BRAKING
• CLOUDS
• DENSE CORE
• DISKS
• FIELDS
• FRAGMENTATION
• Mathematics
• Mathematics, Interdisciplinary Applications
• Physical Sciences
• STAR
• Science & Technology
• TURBULENCE
• accretion
• accretion disks
• methods: numerical
• outflows
• stars: formation
• stars: magnetic fields
• stars: winds

Digital Object Identifier (DOI)

• 10.1017/s1743921311000536

start page

• 291

end page

• 295

volume

• 6

issue

• S270