Magnetic Braking and Protostellar Disk Formation: The Ideal MHD Limit

TL;DR

This study uses 2D simulations to show that weak magnetic fields, much weaker than previously thought, can significantly influence protostellar disk formation through magnetic braking, especially when amplified during collapse.

Contribution

It demonstrates that magnetic fields with high lambda values (~100) can disrupt disk formation, highlighting the importance of magnetic amplification and episodic accretion in star formation.

Findings

Weak magnetic fields (~lambda~100) can disrupt disks via magnetic braking.

Magnetic field amplification occurs during collapse, affecting disk formation.

Episodic mass accretion is caused by magnetic reconnection.

Abstract

Magnetic fields are usually considered dynamically important in star formation when the dimensionless mass-to-flux ratio is close to, or less than, unity (lambda<~1). We show that, in disk formation, the requirement is far less stringent. This conclusion is drawn from a set of 2D (axisymmetric) simulations of the collapse of rotating, magnetized, singular isothermal cores. We find that a weak field corresponding to 1ambda~100 can begin to disrupt the rotationally supported disk through magnetic braking, by creating regions of rapid, supersonic collapse in the disk. These regions are separated by one or more centrifugal barriers, where the rapid infall is temporarily halted. The number of centrifugal barriers increases with lambda. When lambda>~100, they merge together to form a more or less contiguous, rotationally supported disk. Even though the magnetic field in such a case is extremely weak on the scale of dense cores, it is amplified by collapse and differential rotation, to the extent that its pressure dominates the thermal pressure in both the disk and its surrounding region. For relatively strongly magnetized cores with lambda<~10, the disk formation is suppressed completely, as found previously. A new feature is that the mass accretion is highly episodic, due to reconnection of the accumulated magnetic field lines. For rotationally supported disks to appear during the protostellar mass accretion phase of star formation in dense cores with realistic field strengths, the powerful magnetic brake must be weakened, perhaps through nonideal MHD effects and/or protostellar winds. We discuss the possibility of observing a generic product of the magnetic braking, an extended circumstellar region that is supported by a combination of toroidal magnetic field and rotation - a "magnetogyrosphere".