Astronomy and Astrophysics, volume 566A, 150-150 (2014/6-1)
A multiple system of high-mass YSOs surrounded by disks in NGC 7538 IRS 1. Gas dynamics on scales of 10-700 AU from CH3OH maser and NH3 thermal lines.
MOSCADELLI L. and GODDI C.
Abstract (from CDS):
It has been claimed that NGC75381 is a high-mass young stellar object (YSO) with 30M☉, surrounded by a rotating Keplerian disk, probed by a linear distribution of methanol masers. The YSO is also powering a strong compact Hii region or ionized wind, and is driving at least one molecular outflow. The axis orientations of the different structures (ionized gas, outflow, and disk) are, however, misaligned, which has led to the different competing models proposed to explain individual structures. We investigate the 3D kinematics and dynamics of circumstellar gas with very high linear resolution, from tens to 1500AU, with the ultimate goal of building a comprehensive dynamical model for what is considered the best high-mass accretion disk candidate around an O-type young star in the northern hemisphere. We used high-angular resolution observations of 6.7 GHz CH3OH masers with the EVN, NH3 inversion lines with the JVLA B-Array, and radio continuum with the VLA A-Array. In particular, we employed four different observing epochs of EVN data at 6.7GHz, spanning almost eight years, which enabled us to measure line-of-sight (l.o.s.) accelerations and proper motions of CH3OH masers, besides l.o.s. velocities and positions (as done in previous works). In addition, we imaged highly excited NH3 inversion lines, from (6,6) to (13,13), which enabled us to probe the hottest molecular gas very close to the exciting source(s). We confirm previous results that five 6.7 GHz maser clusters (labeled from ``A'' to ``E'') are distributed over a region extended N-S across ≃1500AU, and are associated with three components of the radio continuum emission. We propose that these maser clusters identify three individual high-mass YSOs in NGC75381, named IRS1a (associated with clusters ``B'' and ``C''), IRS1b (associated with cluster ``A''), and IRS1c (associated with cluster ``E''). We find that the 6.7 GHz masers distribute along a line, with a regular variation in VLSR with position, along the major axis of the distribution of maser cluster ``A'' and the combined clusters ``B''+ ``C''. A similar VLSR gradient (although shallower) is also detected in the NH3 inversion lines. Interestingly, the variation in VLSR with projected position is not linear but quadratic for both maser clusters. We measure proper motions for 33 maser features, which have an average amplitude (4.8±0.6 km/s) similar to the variation in VLSR across the maser cluster, and are approximately parallel to the clusters' elongation axes. By studying the time variation in the maser spectrum, we also derive l.o.s. accelerations for 30 features, with typical amplitude of ∼10–3-10–2km/s/yr. We modeled the masers in both clusters ``A'' and ``B''+ ``C'' in terms of an edge-on disk in centrifugal equilibrium. Based on our modeling, masers of clusters ``B''+ ``C'' may trace a quasi-Keplerian ∼1M☉, thin disk, orbiting around a high-mass YSO, IRS1a, of up to ≃25M☉. This YSO dominates the bolometric luminosity of the region. The disk traced by the masers of cluster ``A'' is both massive (≲16M☉ inside a radius of ≃500AU) and thick (opening angle ≃45°), and the mass of the central YSO, IRS1b, is constrained to be at most a fewM☉. Towards cluster ``E'', NH3 and 6.7GHz masers trace more quiescent dynamics than for the other clusters. The presence of a radio continuum peak suggests that the YSO associated with the cluster ``E'', IRS1c, may be an ionizing, massive YSO as well. We present compelling evidence that NGC75381 is forming not just one single high-mass YSO, but consists of a multiple system of high-mass YSOs, which are surrounded by accretion disks and are probably driving individual outflows. This new model naturally explains all the different orientations and disk/outflow structures proposed for the region in previous models.