Zooming into the Collimation Zone in a Massive Protostellar Jet

TL;DR

This study presents the highest resolution observations of a massive protostellar jet, revealing a complex structure with both wide-angle wind and collimated jet components, providing insights into star formation mechanisms across different masses.

Contribution

It offers the first detailed imaging of the innermost regions of a massive protostellar jet, highlighting the presence of both wide-angle wind and collimated jet components.

Findings

Resolved the innermost 100 au of a massive protostellar jet.

Discovered a dual-component outflow: wide-angle wind and collimated jet.

Implications for star formation models across different stellar masses.

Abstract

Protostellar jets have a fundamental role at the earliest evolution of protostars of all masses. In the case of low-mass (<8 Msun) protostars, strong observational evidence exists that the launching and collimation is due to the X- and/or disk-wind mechanisms. In these models, it is the protostar/disk system that creates all the necessary conditions to launch and collimate the jets near the protostar via strong magnetic fields. The origin of jets from more massive protostars has been investigated much less, in part because of the difficulty of resolving the collimation zone in these more distant objects. Here we present the highest angular resolution observations of a jet powered by a massive protostar, the Cep A HW2 radio jet. We imaged the radio emission at projected distances of only ~20 au from the protostar, resolving the innermost 100 au of a massive protostellar jet for the first time. The morphology of the radio jet emission in this massive object is very different than what is usually observed in jets from low-mass protostars. We found that the outflowing material in HW2 has two components: a wide-angle wind launched from the protostar/disk system, and a highly collimated jet starting at 20-30 au from the protostar. We discuss two possible scenarios: an extension of the classical disk-wind to a massive protostar, or external collimation of a wide-angle wind. These results have important consequences for our understanding of how stars of different masses are formed.