Ionised gas kinematics in bipolar H II regions

TL;DR

This study investigates ionised gas kinematics in a young bipolar H II region to understand early stellar feedback, revealing velocity gradients that may indicate rotation driven by initial cloud angular momentum, consistent with simulations.

Contribution

It provides the first detailed kinematic analysis of ionised gas in a bipolar H II region, linking observed velocity gradients to initial cloud angular momentum and early feedback processes.

Findings

Observed a large velocity gradient perpendicular to the outflow.

Velocity gradient matches predictions from young H II region simulations.

Suggests rotation of ionised gas due to initial cloud angular momentum.

Abstract

Stellar feedback plays a fundamental role in shaping the evolution of galaxies. Here we explore the use of ionised gas kinematics in young, bipolar H II regions as a probe of early feedback in these star-forming environments. We have undertaken a multiwavelength study of a young, bipolar H II region in the Galactic disc, G$316.81-0.06$, which lies at the centre of a massive ($\sim10^3$ M$_{\odot}$) infrared-dark cloud filament. It is still accreting molecular gas as well as driving a $\sim 0.2$ pc ionised gas outflow perpendicular to the filament. Intriguingly, we observe a large velocity gradient ($47.81 \pm 3.21$ km s$^{-1}$ pc$^{-1}$) across the ionised gas in a direction perpendicular to the outflow. This kinematic signature of the ionised gas shows a reasonable correspondence with the simulations of young H II regions. Based on a qualitative comparison between our observations and these simulations, we put forward a possible explanation for the velocity gradients observed in G$316.81-0.06$. If the velocity gradient perpendicular to the outflow is caused by rotation of the ionised gas, then we infer that this rotation is a direct result of the initial net angular momentum in the natal molecular cloud. If this explanation is correct, this kinematic signature should be common in other young (bipolar) H II regions. We suggest that further quantitative analysis of the ionised gas kinematics of young H II regions, combined with additional simulations, should improve our understanding of feedback at these early stages.