Rotating Bullets from A Variable Protostar

TL;DR

This paper reports high-velocity molecular bullets in a protostellar jet, revealing jet rotation and angular momentum transfer, supporting the extended disk-wind model, and highlighting the importance of jet rotation in star formation.

Contribution

First detection of systematic velocity gradients indicating jet rotation in molecular bullets from a variable protostar, supporting the jet rotation hypothesis and the extended disk-wind model.

Findings

Measured rotation velocities of bullets are 11.7-13.7 km/s and 4.7 km/s.

Bullets have specific angular momenta comparable to dense cores.

Jet rotation may resolve the angular momentum problem in star formation.

Abstract

We present SMA CO(2-1) observations toward the protostellar jet driven by SVS13A, a variable protostar in the NGC1333 star-forming region. The SMA CO(2-1) images show an extremely high-velocity jet composed of a series of molecular 'bullets'. Based on the SMA CO observations, we discover clear and large systematic velocity gradients, perpendicular to the jet axis, in the blueshifted and redshifted bullets. After discussing several alternative interpretations, such as twin-jets, jet precession, warped disk, and internal helical shock, we suggest that the systematic velocity gradients observed in the bullets result from the rotation of the SVS13A jet. From the SMA CO images, the measured rotation velocities are 11.7-13.7 km/s for the blueshifted bullet and 4.7+/-0.5 km/s for the redshifted bullet. The estimated specific angular momenta of the two bullets are comparable to those of dense cores, about 10 times larger than those of protostellar envelopes, and about 20 times larger than those of circumstellar disks. If the velocity gradients are due to the rotation of the SVS13A jet, the significant amount of specific angular momenta of the bullets indicates that the rotation of jets/outflows is a key mechanism to resolve the so-called 'angular momentum problem' in the field of star formation. The kinematics of the bullets suggests that the jet launching footprint on the disk has a radius of about 7.2-7.7 au, which appears to support the extended disk-wind model. We note that further observations are needed to comprehensively understand the kinematics of the SVS13A jet, in order to confirm the rotation nature of the bullets.