Protostellar Outflows at the EarliesT Stages (POETS) V. The launching mechanism of protostellar winds via water masers
Journal
Date Issued
2024
Author(s)
Abstract
Understanding the launching mechanism of winds and jets remains one of the
fundamental challenges in astrophysics. The Protostellar Outflows at the
EarliesT Stages (POETS) survey has recently mapped the 3D velocity field of the
protostellar winds in a sample (37) of luminous young stellar objects (YSOs) at
scales of 10-100 au via very long baseline interferometry (VLBI) observations
of the 22 GHz water masers. In most of the targets, the distribution of the 3D
maser velocities can be explained in terms of a magnetohydrodynamic (MHD) disk
wind (DW). We have performed Very Long Baseline Array observations of the 22
GHz water masers in IRAS 21078+5211, the most promising MHD DW candidate from
the POETS survey, to determine the 3D velocities of the gas flowing along
several wind streamlines previously identified at a linear resolution of ~1 au.
Near the YSO at small separations along ($xl \le 150$ au) and across ($R \le
40$ au) the jet axis, water masers trace three individual DW streamlines. By
exploiting the 3D kinematic information of the masers, we determined the launch
radii of these streamlines with an accuracy of $\sim$1 au, and they lie in the
range of 10-50 au. At increasingly greater distances along the jet (110 au $\le
xl \le 220$ au), the outflowing gas speeds up while it collimates close to the
jet axis. Magneto-centrifugal launching in a radially extended MHD DW appears
to be the only viable process to explain the fast (up to 60 km/s) and
collimated (down to 10 degree) velocities of the wind in correspondence with
launch radii ranging between 10 and 50 au. At larger separations from the jet
axis ($R \ge 100$ au), the water masers trace a slow ($\le$20 km/s), radially
expanding arched shock-front with kinematics inconsistent with
magneto-centrifugal launching. Our resistive-magnetohydrodynamical simulations
indicate that this shock-front could be driven by magnetic pressure.
Volume
690
Start page
A81
Issn Identifier
0004-6361
Rights
open.access
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