The effect of winds on atmospheric layers of red supergiants

González-Torà, Gemma; Wittkowski, M.; Davies, Ben; Plez, B.; Kravchenko, Kateryna

doi:10.1051/0004-6361/202244503

A&A

2023

DOI: 10.1051/0004-6361/202244503

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The effect of winds on atmospheric layers of red supergiants

Gemma González-Torà

M. Wittkowski

Ben Davies

et al.

Abstract: Context. Red supergiants (RSGs) are evolved massive stars in a stage preceding core-collapse supernova. The physical processes that trigger mass loss in their atmospheres are still not fully understood, and they remain one of the key questions in stellar astrophysics. Based on observations of α Ori, a new semi-empirical method to add a wind to hydrostatic model atmospheres of RSGs was recently developed. This method can reproduce many of the static molecular shell (or 'MOLsphere') spectral features. Aims. We u… Show more

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2024

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Cited by 6 publications

References 72 publications

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Interacting supernovae from wide massive binary systems

Ercolino,

Jin,

Langer

et al. 2024

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The features in the light curves and spectra of many I and II supernovae (SNe) can be understood by assuming an interaction of the SN ejecta with circumstellar matter (CSM) surrounding the progenitor star. This suggests that many massive stars may undergo various degrees of envelope stripping shortly before exploding, and may therefore produce a considerable diversity in their pre-explosion CSM properties. We explore a generic set of about 100 detailed massive binary evolution models in order to characterize the amount of envelope stripping and the expected CSM configurations. Our binary models were computed with the MESA stellar evolution code, considering an initial primary star mass of 12.6mso and secondaries with initial masses of between $ and $ and focus on initial orbital periods above $ We compute these models up to the time of iron core collapse in the primary. Our models exhibit varying degrees of stripping due to mass transfer, resulting in SN progenitor models ranging from fully stripped helium stars to stars that have not been stripped at all. We find that Roche lobe overflow often leads to incomplete stripping of the mass donor, resulting in a large variety of pre-SN envelope masses. In many of our models, the red supergiant (RSG) donor stars undergo core collapse during Roche lobe overflow, with mass transfer and therefore system mass-loss rates of up to $0.01 at that time. The corresponding CSM densities are similar to those inferred for IIn SNe, such as 1998S . In other cases, the mass transfer becomes unstable, leading to a common-envelope phase at such late time that the mass donor explodes before the common envelope is fully ejected or the system has merged. We argue that this may cause significant pre-SN variability, as witnessed for example in 2020tlf . Other models suggest a common-envelope ejection just centuries before core collapse, which may lead to the strongest interactions, as observed in superluminous IIn SNe, such as 1994W and 2006gy Wide massive binaries exhibit properties that may not only explain the diverse envelope stripping inferred in Type Ib, IIb, IIL, and IIP SNe, but also offer a natural framework to understand a broad range of hydrogen-rich interacting SNe. On the other hand, the flash features observed in many IIP SNe, such as 2013fs may indicate that RSG atmospheres are more extended than currently assumed; this could enhance the parameter space for wide binary interaction.

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Interacting supernovae from wide massive binary systems

Ercolino,

Jin,

Langer

et al. 2024

A&A

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The effect of winds on atmospheric layers of red supergiants II. Modelling VLTI/GRAVITY and MATISSE observations of AH Sco, KW Sgr, V602 Car, CK Car, and V460 Car

González-Torà,

Wittkowski,

Davies

et al. 2024

A&A

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Mass loss plays a crucial role in the lives of massive stars, especially as the star leaves the main sequence and evolves to the red supergiant (RSG) phase. Despite its importance, the physical processes that trigger mass-loss events in RSGs are still not well understood. Recently, we showed that adding a semi-empirical wind to atmosphere models can accurately reproduce observed extensions in the atmospheres of RSGs, where the mass-loss events are taking place, particularly in the CO and water lines. By adding a static wind to a MARCS atmospheric model, we computed synthetic observables that match new interferometric data of the RSGs AH Sco, KW Sgr, V602 Car, CK Car, and V460 Car obtained with the VLTI/MATISSE and VLTI/GRAVITY instruments between August 2022 and February 2023. We also used archival VLTI/AMBER data of KW Sgr and VLTI/GRAVITY data of AH Sco. The MATISSE wavelength range includes the SiO molecule at $4.0\ with a spectral resolution of $R The model intensities with respect to the line-of-sight angle (mu ) as well as the spectra and visibilities were computed using the stellar radiative transfer code Turbospectrum . We found the best-fit model, mass-loss rate, and best-fit angular Rosseland diameter for the observations. We simultaneously matched our model to the data, covering a wavelength range of $1.8-5.0\ which corresponds to the $K$, $L,$ and $M$ bands. Our models reproduce the spectro-interferometric data over this wide wavelength range, including extended atmospheric layers of CO, H$_2$O, and SiO. We obtain a range of Rosseland angular diameters between $3.0< Ross <5.5$ mas and a range of mass-loss rates of $-6.5< M /M_ odot yr <-4$ for our five targets. In our best-fit models, the partial pressure of SiO relative to the gas pressure, $P_ SiO /P_ g $, and the SiO 4.0\,mu m line intensity increase between 2 and 3 stellar radii. The relative intensity depends on the luminosity used for our models, since the more luminous models have a higher mass-loss rate. This work further demonstrates that our MARCS+wind model can reproduce the observed physical extension of RSG atmospheres for several spectral diagnostics spanning a broad wavelength range. We reproduce both spectra and visibilities of newly obtained data as well as provide temperature and density stratifications that are consistent with the observations. With the MATISSE data, we newly include the extension of SiO layers as a precursor of silicate dust.

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Investigating episodic mass loss in evolved massive stars

de Wit,

Bonanos,

Antoniadis

et al. 2024

A&A

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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 radial velocity. By fitting the spectral energy distribution, we obtained the stellar luminosity and radius for 92 RSGs, finding that $ 50<!PCT!>$ of them have log$(L/ odot 5.0$ and six RSGs have $R odot $. We also find a correlation between the stellar luminosity and mid-IR excess of 33 dusty variable sources. Three of these dusty RSGs have luminosities exceeding the revised Humphreys-Davidson limit. We then derived a metallicity-dependent $J-K_s$ color versus temperature relation from synthetic photometry and two new empirical $J-K_s$ color versus temperature relations calibrated on literature TiO and $J$-band temperatures. To scale our derived cool TiO temperatures to values that are in agreement with the evolutionary tracks, we derived two linear scaling relations calibrated on $J$-band and $i$-band temperatures. We find that the TiO temperatures are more discrepant as a function of the mass-loss rate, and discuss future prospects of the TiO bands as a mass-loss probe. Finally, we speculate that three hot dusty RSGs may have experienced a recent mass ejection ($12<!PCT!>$ of the K-type sample) and classify them as candidate Levesque-Massey variables.

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The effect of winds on atmospheric layers of red supergiants

Cited by 6 publications

References 72 publications

Interacting supernovae from wide massive binary systems

Interacting supernovae from wide massive binary systems

The effect of winds on atmospheric layers of red supergiants II. Modelling VLTI/GRAVITY and MATISSE observations of AH Sco, KW Sgr, V602 Car, CK Car, and V460 Car

Investigating episodic mass loss in evolved massive stars

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