The Structure and Kinematics of Three Class 0 Protostellar Jets from JWST

TL;DR

This study uses JWST observations to analyze the detailed structure and motion of jets from three deeply embedded protostars, revealing their morphology, velocities, and asymmetries, advancing understanding of early star formation processes.

Contribution

First detailed JWST-based analysis of protostellar jets, showing their morphology, velocities, and asymmetries at unprecedented resolution.

Findings

Jets show wiggling motion and asymmetries between lobes.

Jet widths increase non-monotonically with distance.

Velocities range from 147 to 184 km/s.

Abstract

We present observations of jets within 2000 au of three deeply embedded protostars using 2.9-27 micron observations with JWST. These observations show the morphologies and kinematics of the collimated jets from three protostars, the low-mass Class 0 protostars B335 and HOPS 153, and the intermediate-mass protostar HOPS 370. These jets are traced by shock-ionized fine-structure line emission observed with the JWST NIRSpec and MIRI IFUs. We find that [Fe II] emission traces the full extent of the inner 1000 to 2000 au of the jets, depending on distance to the protostar, while other ions mostly trace isolated shocked knots. The jets show evidence of wiggling motion in the plane of the sky as well as asymmetries between blue and red-shifted lobes. The widths of the jets increase non-monotonically with distance from the central protostar, with opening angles ranging from 2.1 degrees to < 10.1 degrees for the three protostars in the sample. The jets have total velocities ranging from 147 to 184 km/s after correcting for disk inclination. For B335, an 8-month gap between NIRSpec and MIRI MRS observations enabled measurement of the tangential velocity of a shocked knot; in combination with the radial velocity, this shows that the jet has a different inclination than the outflow cavity. We find multiple knots before and during a recent outburst in B335, although the knots were more frequent during the burst. The asymmetries between blue- and red-shifted lobes strongly suggest complex interactions between the circumstellar disks and magnetic fields.