SiO collimated outflows driven by high-mass YSOs in G24.78+0.08

TL;DR

This study uses high-resolution SiO emission observations to image collimated outflows driven by high-mass young stellar objects in G24.78+0.08, revealing jets associated with early evolutionary stages and supporting a low-mass star formation scenario.

Contribution

First high-resolution imaging of SiO outflows in G24.78+0.08, linking jets to early-stage high-mass star formation and hot core activity.

Findings

Detected two collimated SiO outflows driven by massive cores.

No SiO outflows observed from more evolved ultracompact or hypercompact HII regions.

High-density gas with well-constrained SiO column densities.

Abstract

We imaged the molecular outflows towards the cluster of high-mass young stellar objects G24.78+0.08 at high-angular resolution using SiO emission, which is considered the classical tracer of protostellar jets. We performed SiO observations with the VLA interferometer in the J = 1-0 v=0 transition and with the SMA array in the 5-4 transition. A complementary IRAM 30-m single-dish survey in the (2-1), (3-2), (5-4), and (6-5) SiO lines was also carried out. Two collimated SiO high-velocity outflows driven by the A2 and C millimeter continuum massive cores have been imaged. On the other hand, we detected no SiO outflow driven by the young stellar objects in more evolved evolutionary phases that are associated with ultracompact (B) or hypercompact (A1) HII regions. The LVG analysis reveals high-density gas (10^3-10^4 cm-3), with well constrained SiO column densities (0.5-1 10^15 cm-2). The driving source of the A2 outflow is associated with typical hot core tracers such as methyl formate, vinyl cyanide, cyanoacetilene, and acetone. The driving source of the main SiO outflow in G24 has an estimated luminosity of a few 10^4 Lsun (typical of a late O-type star) and is embedded in the 1.3 mm continuum core A2, which in turn is located at the centre of a hot core that rotates on a plane perpendicular to the outflow main axis. The present SiO images support a scenario similar to the low-mass case for massive star formation, where jets that are clearly traced by SiO emission, create outflows of swept-up ambient gas usually traced by CO.