XMM-Newton view of the N 206 superbubble in the Large Magellanic Cloud

TL;DR

This study uses XMM-Newton X-ray observations and optical data to analyze the physical properties and evolution of the N 206 superbubble in the Large Magellanic Cloud, revealing hot gas characteristics and potential blowout regions.

Contribution

It provides a detailed spectral and morphological analysis of the N 206 superbubble, improving understanding of superbubble evolution and hot gas properties using combined X-ray and optical data.

Findings

Bright X-ray emission confined by Halpha shell

Detection of faint emission indicating a blowout region

Hot shocked gas identified as the emission source

Abstract

We perform an analysis of the X-ray superbubble in the N 206 HII region in the Large Magellanic Cloud using current generation facilities to gain a better understanding of the physical processes at work in the superbubble and to improve our knowledge of superbubble evolution. We used XMM-Newton observations of the N 206 region to produce images and extract spectra of the superbubble diffuse emission. Morphological comparisons with Halpha images from the Magellanic Cloud Emission Line Survey were performed, and spectral analysis of the diffuse X-ray emission was carried out. We derived the physical properties of the hot gas in the superbubble based on the results of the spectral analysis. We also determined the total energy stored in the superbubble and compared this to the expected energy input from the stellar population to assess the superbubble growth rate discrepancy for N 206. We find that the brightest region of diffuse X-ray emission is confined by a Halpha shell, consistent with the superbubble model. In addition, faint emission extending beyond the Halpha shell was found, which we attribute to a blowout region. The spectral analysis of both emission regions points to a hot shocked gas as the likely origin of the emission. We determine the total energy stored in the bubble and the expected energy input by the stellar population. However, due to limited data on the stellar population, the input energy is poorly constrained and, consequently, no definitive indication of a growth rate discrepancy is seen. Using the high-sensitivity X-ray data from XMM-Newton and optical data from the Magellanic Cloud Emission Line Survey has allowed us to better understand the physical properties of the N 206 superbubble and address some key questions of superbubble evolution.