High-sensitivity millimeter imaging of molecular outflows in nine nearby high-mass star-forming regions

TL;DR

This study uses high-sensitivity millimeter observations of nine nearby high-mass star-forming regions to analyze molecular outflows across multiple lines, revealing relationships between outflow properties and source luminosities.

Contribution

It provides detailed measurements of molecular outflows using six lines, demonstrating the detection of outflows in all sources and analyzing their velocity and dynamical properties.

Findings

100% detection rate of outflows in all sources

Velocity line widths follow a specific hierarchy among molecular lines

Outflow properties correlate with the bolometric luminosities of sources

Abstract

We present a study of molecular outflows using six molecular lines (including 12CO/13CO/C18O/HCO+(J = 1-0) and SiO/CS(J = 2-1)) toward nine nearby high-mass star-forming regions with accurate known distances. This work is based on the high-sensitivity observations obtained with the 14-m millimeter telescope of Purple Mountain Observatory Delingha (PMODLH) observatory. The detection rate of outflows (including 12CO, 13CO, HCO+, and CS) is 100\%. However, the emission of SiO was not detected for all sources. The full line widths ($\Delta V$) at 3$\sigma$ above the baseline of these molecular lines have the relationship $\Delta V_{\rm ^{12}CO} > \Delta V_{\rm HCO^{+}} > \Delta V_{\rm CS} \approx \Delta V_{\rm ^{13}CO} > \Delta V_{\rm ^{18}CO}$. 12CO and HCO+ can be used to trace relatively high-velocity outflows, while 13CO and CS can be employed to trace relatively low-velocity outflows. The dynamical timescales of the 13CO and CS outflows are longer than those of the 12CO and HCO+ outflows. The mechanical luminosities, masses, mass-loss rates and forces of all outflows (including 12CO, 13CO, HCO+, and CS) are correlated with the bolometric luminosities of their central IRAS sources.