Clustered Formation of Massive Stars within an Ionized Rotating Disk

TL;DR

This study uses high-resolution ALMA observations and radiative transfer modeling to analyze the formation of a massive star cluster within an ionized rotating disk, revealing the cluster's mass distribution, dynamics, and potential for stellar interactions.

Contribution

It provides detailed modeling of the ionized accretion flow around a forming massive star cluster, highlighting the cluster's mass, structure, and dynamics at unprecedented resolution.

Findings

Cluster mass between 120 and 200 solar masses.

Ionized gas is marginally unbound and converging at sound speed.

Stellar cluster likely contains a few massive stars of 32-60 solar masses.

Abstract

We present ALMA observations with a 800 au resolution and radiative-transfer modelling of the inner part ($r\approx6000$ au) of the ionized accretion flow around a compact star cluster in formation at the center of the luminous ultra-compact (UC) HII region G10.6-0.4. We modeled the flow with an ionized Keplerian disk with and without radial motions in its outer part, or with an external Ulrich envelope. The MCMC fits to the data give total stellar masses $M_\star$ from 120 to $200~M_\odot$, with much smaller ionized-gas masses $M_\mathrm{ion-gas} = 0.2$ to $0.25~M_\odot$. The stellar mass is distributed within the gravitational radius $R_g\approx 1000$ to 1500 au, where the ionized gas is bound. The viewing inclination angle from the face-on orientation is $i = 49$ to $56~\deg$. Radial motions at radii $r > R_g$ converge to $v_{r,0} \approx 8.7$ km/s, or about the speed of sound of ionized gas, indicating that this gas is marginally unbound at most. From additional constraints on the ionizing-photon rate and far-IR luminosity of the region, we conclude that the stellar cluster consists of a few massive stars with $M_\mathrm{star} = 32$ to $60~M_\odot$, or one star in this range of masses accompanied by a population of lower-mass stars. Any active accretion of ionized gas onto the massive (proto)stars is residual. The inferred cluster density is very large, comparable to that reported at similar scales in the Galactic Center. Stellar interactions are likely to occur within the next Myr.