Investigating episodic mass loss in evolved massive stars

de Wit, S.; Bonanos, A. Z.; Antoniadis, K.; Zapartas, E.; Ruiz, A.; Britavskiy, N.; Christodoulou, E.; De, K.; Maravelias, G.; Munoz-Sanchez, G.; Tsopela, A.

doi:10.1051/0004-6361/202449607

A&A

2024

DOI: 10.1051/0004-6361/202449607

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Investigating episodic mass loss in evolved massive stars

S. de Wit,

A. Z. Bonanos,

K. Antoniadis

et al.

Abstract: Mass loss during the red supergiant (RSG) phase plays a crucial role in the evolution of an intermediate-mass star; however, the underlying mechanism remains unknown. We aim to increase the sample of well-characterized RSGs at subsolar metallicity by deriving the physical properties of 127 RSGs in nine nearby southern galaxies. For each RSG, we provide spectral types and used marcs atmospheric models to measure stellar properties from their optical spectra, such as the effective temperature, extinction, and ra… Show more

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Cited by 2 publications

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Establishing a mass-loss rate relation for red supergiants in the Large Magellanic Cloud

Antoniadis,

Bonanos,

de Wit

et al. 2024

A&A

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The high mass-loss rates of red supergiants (RSGs) drastically affect their evolution and final fate, but their mass-loss mechanism remains poorly understood. Various empirical prescriptions scaled with luminosity have been derived in the literature, yielding results with a dispersion of two to three orders of magnitude. We determine an accurate mass-loss rate relation with luminosity and other parameters using a large, clean sample of RSGs. In this way, we shed light into the underlying physical mechanism and explain the discrepancy between previous works. We assembled a sample of 2,219 RSG candidates in the Large Magellanic Cloud, with ultraviolet to mid-infrared photometry in up to 49 filters. We determined the luminosity of each RSG by integrating the spectral energy distribution and the mass-loss rate using the radiative transfer code DUSTY Our derived RSG mass-loss rates range from approximately $10^ odot $ yr$^ $ to $10^ odot $ yr$^ $, mainly depending on the luminosity. The average mass-loss rate is $9.3 odot $ yr$^ $ for $ (L/L_ odot) >4$, corresponding to a dust-production rate of $ odot $ yr$^ $. We established a mass-loss rate relation as a function of luminosity and effective temperature. Furthermore, we found a turning point in the relation of mass-loss rate versus luminosity at approximately $ (L/L_ odot) = 4.4$, indicating enhanced rates beyond this limit. We show that this enhancement correlates with photometric variability. We compared our results with prescriptions from the literature, finding an agreement with works assuming steady-state winds. Additionally, we examined the effect of different assumptions on our models and found that radiatively driven winds result in mass-loss rates higher by two to three orders of magnitude, which is unrealistically high for RSGs. For grain sizes $<0.1 \ the predicted mass-loss rates are higher by a factor of 25-30 than larger grain sizes. Finally, we found that 21<!PCT!> of our sample constitute current binary candidates. This has a minor effect on our mass-loss relation.

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Establishing a mass-loss rate relation for red supergiants in the Large Magellanic Cloud

Antoniadis,

Bonanos,

de Wit

et al. 2024

A&A

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Episodic mass loss in the very luminous red supergiant [W60] B90 in the Large Magellanic Cloud

Munoz-Sanchez,

de Wit,

Bonanos

et al. 2024

A&A

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Despite mounting evidence that extreme red supergiants (RSGs) undergo episodic mass-loss events, their role in RSG evolution remains uncertain. Critical questions remain unanswered, such as whether or not these events can strip the star, and their timescale and frequency. This study delves into W60 B90, one of the most luminous and extreme RSGs in the Large Magellanic Cloud (LMC), with our aim being to search for evidence of episodic mass loss. Our discovery of a bar-like nebular structure at 1 pc, which is reminiscent of the bar around Betelgeuse, raised the question of whether W60 B90 also has a bow shock, motivating the present study. We collected and analyzed proper motion data from Gaia as well as new multi-epoch spectroscopic and imaging data, and archival time-series photometry in the optical and mid-infrared (MIR). We used marcs models to derive the physical properties of the star from the spectra. We find W60 B90 to be a walkaway star, with a supersonic peculiar velocity in the direction of the bar. We detect shocked emission between the bar and the star, based on the S ii /Halpha > 0.4 criterion, providing strong evidence for a bow shock. The 30 yr optical light curve reveals semi-regular variability, showing three similar dimming events with $ V\! 1$ mag, a recurrence of sim 12 yr, and a rise time of 400 days. We find the MIR light curve to vary by 0.51 mag and 0.37 mag in the WISE1 and WISE2 bands, respectively, and by 0.42 mag and 0.25 mag during the last dimming event. During this event, optical spectroscopy reveals spectral variability (M3 I to M4 I), a correlation between the and the brightness, increased extinction, and, after the minimum, spectral features incompatible with the models. We also find a difference of $>$300 K between the measured from the TiO bands in the optical and the atomic lines from our $J$-band spectroscopy. W60 B90 is a more massive analog of Betelgeuse in the LMC and therefore the first single extragalactic RSG with a suspected bow shock. Its high luminosity of $ )=5.32$ dex, mass-loss rate, and MIR variability compared to other RSGs in the LMC indicate that it is in an unstable evolutionary state, undergoing episodes of mass loss. Investigating other luminous and extreme RSGs in low-metallicity environments using both archival photometry and spectroscopy is crucial to understanding the mechanism driving episodic mass loss in extreme RSGs in light of the Humphreys-Davidson limit and the ``RSG problem''.

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Investigating episodic mass loss in evolved massive stars

Cited by 2 publications

References 141 publications

Establishing a mass-loss rate relation for red supergiants in the Large Magellanic Cloud

Establishing a mass-loss rate relation for red supergiants in the Large Magellanic Cloud

Episodic mass loss in the very luminous red supergiant [W60] B90 in the Large Magellanic Cloud

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