A new mechanical stellar wind feedback model for the Rosette Nebula

TL;DR

This paper introduces a new stellar wind feedback model that accurately reproduces the structure and properties of the Rosette Nebula by simulating the interaction of a massive star with a realistic interstellar medium, resolving age estimate discrepancies.

Contribution

The study presents a novel mechanical stellar feedback model incorporating realistic diffuse ISM properties and magnetic fields, successfully matching observed nebula features and ages.

Findings

Simulation reproduces nebula structure and cavity size

Aligns stellar age with nebula properties

Explains age estimate discrepancies using realistic ISM

Abstract

The famous Rosette Nebula has an evacuated central cavity formed from the stellar winds ejected from the 2-6 million-year-old co-distant and co-moving central star cluster NGC 2244. However, with upper age estimates of less than 110,000 years, the central cavity is too young compared to NGC 2244 and existing models do not reproduce its properties. A new proper motion study herein using Gaia data reveals the ejection of the most massive star in the Rosette, HD46223, from NGC 2244 occurred 1.73 (+0.34,-0.25)Myr (1$\sigma$ uncertainty) in the past. Assuming this ejection was at the birth of the most massive stars in NGC 2244, including the dominant centrally positioned HD46150, the age is set for the famous ionised region at more than ten times that derived for the cavity. Here, we are able to reproduce the structure of the Rosette Nebula, through simulation of mechanical stellar feedback from a 40M$_{\odot}$ star in a thin sheet-like molecular cloud. We form the 135,000M$_{\odot}$ cloud from thermally-unstable diffuse interstellar medium under the influence of a realistic background magnetic field with thermal/magnetic pressure equilibrium. Properties derived from a snapshot of the simulation at 1.5Myr, including cavity size, stellar age, magnetic field and resulting inclination to the line of sight, match those derived from observations. An elegant explanation is thus provided for the stark contrast in age estimates based on realistic diffuse ISM properties, molecular cloud formation and stellar wind feedback.