Extremely Energetic Outflow and Decelerated Expansion in W49N

TL;DR

This study reveals an extremely energetic outflow and decelerated expansion in W49N, a starburst region, providing new insights into high-mass star formation and molecular outflow dynamics in the Milky Way.

Contribution

First detection of high-velocity molecular outflow in W49N, with analysis of decelerated expansion and outflow precession in this star-forming region.

Findings

Detected the most energetic molecular outflow in W49N.

Identified decelerated expansion of cold gas layers.

Suggested outflow precession explains maser distribution.

Abstract

W49N is a mini-starburst in the Milky Way and thus an ideal laboratory for high-mass star formation studies. Due to its large distance (11.1$_{-0.7}^{+0.9}$ kpc), the kinematics inside and between the dense molecular clumps in W49N are far from well understood. The SMA observations resolved the continuum emission into two clumps. The molecular line observation of SO$_{2}$ (28$_{4,24}$-28$_{3,25}$) suggests that the two clumps have a velocity difference of $\sim$7 km~s$^{-1}$. The eastern clump is very close to two radio sources "G1" and "G2", and the western clump coincides with a radio source "B". The HCN (3-2) line reveals an extremely energetic outflow, which is among the most energetic molecular outflows in the Milky Way. This is the first report of high-velocity molecular outflow detection in W49N. The outflow jet might be in precession, which could account for the distribution, velocity and rotation of water maser spots. Three absorption systems are identified in HCO$^{+}$ (3-2) spectra. The absorption features are blueshifted with respect to the emission of SO$_{2}$ (28$_{4,24}$-28$_{3,25}$) lines, indicating that a cold layer is expanding in front of the warm gas. Further analysis indicates that the expansion is decelerated from the geometric expansion centers.