Investigating episodic mass loss in evolved massive stars: III. Spectroscopy of dusty massive stars in three northern galaxies

TL;DR

This study conducts optical spectroscopy of dusty evolved massive stars in three northern galaxies to better understand episodic mass loss, revealing new stellar classifications, properties, and variability patterns linked to mass loss events.

Contribution

It provides the first extensive spectroscopic survey of dusty massive stars in these galaxies, identifying new RSGs and candidates for episodic mass loss, advancing understanding of stellar evolution.

Findings

Discovered new red supergiants and other evolved stars.

Found dusty RSGs are cooler, more luminous, and more variable.

Identified candidates for episodic mass loss events.

Abstract

Mass loss in massive stars is crucial to understanding how these stars evolve and explode. Despite increasing evidence indicating its importance, episodic mass loss remains poorly understood. Here we report the results of an optical spectroscopic survey of evolved massive stars in NGC 6822, IC 10, and IC 1613, conducted by the ASSESS project (Episodic Mass Loss in Evolved Massive Stars: Key to Understanding the Explosive Early Universe), which aimed to investigate the role of episodic mass loss, by targeting stars with infrared excesses indicating a dusty circumstellar environment. We assigned a spectral class to 122 unique sources, the majority of which are dusty. The rate of evolved massive stars was over 60% for the highest-priority targets. We discovered 2 blue supergiants, 1 yellow supergiant, 1 emission-line object, and confirmed 2 supernova remnant candidates, a Wolf-Rayet star, and 2 H II regions. Twenty-eight unique sources were classified as red supergiants, 21 of which are new discoveries. In IC 10, we increased the sample of spectroscopically confirmed RSGs from 1 to 17. We used the MARCS models to obtain their surface properties, most importantly the effective temperature, and spectral energy distribution fitting to obtain the stellar luminosity for 17 of them. The dusty RSGs are cooler, more luminous, more extinguished, and more evolved than the non-dusty ones, in agreement with previous findings. Investigating the optical photometric variability of the RSGs from light curves covering a period over a decade revealed that the dusty RSGs are more variable. We further highlight the very extinguished emission-line object, two RSGs that display a significant change in spectral type between two observed epochs, and four dusty K-type RSGs as candidates for having undergone episodic mass loss.