Millimeter interferometry of W3 IRS5: A Trapezium in the making

TL;DR

This study uses millimeter interferometry to analyze the young massive star-forming region W3 IRS5, revealing a multiple protostar system with complex outflows and dynamics, providing insights into high-mass star formation processes.

Contribution

First high-resolution millimeter observations of W3 IRS5 revealing a Trapezium-like multiple system and its dynamic environment, advancing understanding of massive star formation.

Findings

Detected five continuum sources, including one new source.

Identified multiple molecular outflows and signs of rotating, bound system.

Evidence of converging flows supporting gravoturbulent star formation theories.

Abstract

Although most young massive stars appear to be part of multiple systems, it is poorly understood how this multiplicity influences the formation of massive stars. The high-mass star-forming region W3 IRS5 is a prime example of a young massive cluster where the cluster center is resolved into multiple subsources at cm and infrared wavelengths, a potential proto-Trapezium system. The region W3 IRS5 was mapped with the PdBI at 1.4mm and 3.4mm in the AB configurations, observing shock-tracing SiO and SO_2 emission. In the continuum we detect five sources, one of them for the first time, while counterparts were detected in the NIR, MIR or at radio wavelengths for the remaining four sources. Three of the detected sources are within the inner 2100AU, where the protostellar number density exceeds 10^6 protostars pc^-3 assuming spherical symmetry. Lower limits for the circumstellar masses of the detected sources were calculated, although they were strongly affected by the spatial filtering of the interferometer. However, the projected separations of the sources ranging between ~750 and ~4700AU indicate a multiple, Trapezium-like system. We detected five molecular outflows in SiO, two of them nearly in the line of sight direction, which allowed us to see the collapsing protostars in the NIR through the cavities carved by the outflows. The SO_2 velocity structure indicates a rotating, bound system, and we find tentative signatures of converging flows as predicted by the gravoturbulent star formation and converging flow theories. The obtained data strongly indicate that the clustered environment has a major influence on the formation of high-mass stars; however, our data do not clearly allow us to distinguish whether the ongoing star-forming process follows a monolithic collapse or a competitive accretion mechanism.