Feedback from Winds and Supernovae in Massive Stellar Clusters - II. X-Ray Emission

TL;DR

This study uses 3D hydrodynamical simulations to analyze X-ray emission from a massive stellar cluster, revealing how winds, supernovae, and molecular cloud interactions influence X-ray luminosity and spectra over time.

Contribution

It provides a detailed simulation-based analysis of X-ray emission evolution in a massive stellar cluster, incorporating feedback from winds and supernovae with realistic cloud interactions.

Findings

X-ray luminosity drops significantly during wind confinement phases.

Supernova explosions cause sharp increases in X-ray emission lasting ~4600 years.

Leakage of hot gas reduces X-ray luminosity compared to spherical models.

Abstract

The X-ray emission from a simulated massive stellar cluster is investigated. The emission is calculated from a 3D hydrodynamical model which incorporates the mechanical feedback from the stellar winds of 3 O-stars embedded in a giant molecular cloud clump containing 3240 M$_{\odot}$ of molecular material within a 4 pc radius. A simple prescription for the evolution of the stars is used, with the first supernova explosion at t=4.4 Myrs. We find that the presence of the GMC clump causes short-lived attenuation effects on the X-ray emission of the cluster. However, once most of the material has been ablated away by the winds the remaining dense clumps do not have a noticable effect on the attenuation compared with the assumed interstellar medium column. We determine the evolution of the cluster X-ray luminosity, L$_X$, and spectra, and generate synthetic images. The intrinsic X-ray luminosity drops from nearly 10$^{34}$ ergs s$^{-1}$ while the winds are `bottled up', to a near constant value of 1.7$\times 10^{32}\rm ergs s^{-1}$ between t=1-4 Myrs. L$_X$ reduces slightly during each star's red supergiant stage due to the depressurization of the hot gas. However, L$_X$ increases to $\approx 10^{34}\rm\,ergs s^{-1}$ during each star's Wolf-Rayet stage. The X-ray luminosity is enhanced by 2-3 orders of magnitude to $\sim 10^{37}\rm ergs s^{-1}$ for at least 4600 yrs after each supernova, at which time the blast wave leaves the grid and the X-ray luminosity drops. The X-ray luminosity of our simulation is generally considerably fainter than predicted from spherically-symmetric bubble models, due to the leakage of hot gas material through gaps in the outer shell. This process reduces the pressure within our simulation and thus the X-ray emission. However, the X-ray luminosities and temperatures which we obtain are comparable to similarly powerful massive young clusters.