Observational Constraints on the Hd 5980 Wind-Wind Collision

Koenigsberger, Gloria; Morrell, N.; Hillier, D. J.; Schmutz, W.; Gamen, R.; Arias, J. I.; Barbá, R.; Ferrero, G.

doi:10.22201/ia.01851101p.2022.58.02.19

Cited by 5 publications

(7 citation statements)

References 53 publications

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“…Furthermore, because the bloating induced by E  ultimately comes from the orbital energy, the orbit will shrink. As suggested by Koenigsberger & Moreno (2016), this could lead to a runaway process in which the bloating star absorbs a systematically increasing amount of orbital energy. One possible outcome is the ejection of a shell, allowing the star to contract and stabilize.…”

Section: Discussionmentioning

confidence: 95%

“…However, additional binary interaction effects exist that can affect a star's internal structure and thus its HRD location. Koenigsberger & Moreno (2016) suggested that if tidal shear energy dissipation in an asynchronously rotating binary star is fed into the internal layers as heat, this would cause the star to increase its radius. Estrella-Trujillo et al (2023) demonstrated that if the tidal heating is injected into a stellar model, the reaction of the star is indeed to increase its radius, but, in addition, it becomes hotter and more luminous than the corresponding standard model, and its evolutionary path crosses the HRD regions occupied by BSSs.…”

Section: Introductionmentioning

confidence: 99%

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Transitory Tidal Heating and Its Impact on Cluster Isochrones

Arthur,

Koenigsberger,

Brady

et al. 2024

ApJ

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The kinetic energy in tidal flows, when converted into heat, can affect the internal structure of a star and shift its location on a color–magnitude diagram from that of standard models. In this paper we explore the impact of injecting heat into stars with masses near the main-sequence turnoff mass (1.26 M ⊙) of the open cluster M67. The heating rate is obtained from the tidal shear energy dissipation rate, which is calculated from first principles by simultaneously solving the equations that describe orbital motion and the response of a star’s layers to the gravitational, Coriolis, centrifugal, gas pressure, and viscous forces. The stellar structure models are computed with MESA. We focus on the effects of injecting heat in pulses lasting 0.01 Gyr, a time frame consistent with the synchronization timescale in binary systems. We find that the location of the tidally perturbed stars in the M67 color–magnitude diagram is shifted to significantly higher luminosities and effective temperatures than predicted by the standard model isochrone and includes locations corresponding to some of the blue straggler stars. Because tidal heating takes energy from the orbit, causing it to shrink, blue straggler stars could be merger or mass transfer progenitors, as well as products of these processes.

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Section: Discussionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Transitory Tidal Heating and Its Impact on Cluster Isochrones

Arthur,

Koenigsberger,

Brady

et al. 2024

ApJ

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“…Several Magellanic Cloud systems are host to multiple WN+WN stars, including BAT99-116 (Mk 34, Tehrani et al 2019), andBAT99-118 (R144, Shenar et al 2021), so we adopt equal line contributions from each component since mass ratios are close to unity, which should be a reasonable assumption with the potential exception of AB5 (HD 5980, Koenigsberger et al 2014). Since AB5 is known to be spectroscopically variable (Koenigsberger et al 2022), we have selected the HST/STIS dataset from 2016 (phase 0.36) instead of 2014 (phase 0.0) (Hillier et al 2019). R140a is omitted since it involves a mix of WN and WC populations which are difficult to deblend (Castro et al 2018).…”

Section: Magellanic Cloud Wr Starsmentioning

confidence: 99%

“…LMC weak-lined WN6-8 stars extend the Galactic sequence to higher luminosities, including R144 (BAT99-118), which is host to a multiple WN+WN system (Shenar et al 2021) and R145 (BAT99-119) which is also a binary system (Shenar et al 2019). There are too few SMC late-type WN stars to draw robust conclusions, although the high luminosity SMC system AB 5 (HD 5980) is also multiple (Koenigsberger et al 2014(Koenigsberger et al , 2022 Tables 2-3 provide calibrations of He 𝜆4686 line luminosities for WN2-8 (N=140), WN9-11 (N=12), Of/WN (N=8) and WN/C (N=9) stars, respectively, together with other prominent optical emission lines. This highlights features that may be detectable in high S/N observations of WR galaxies, notably the 𝜆4100 complex in WN stars which is largely unaffected by nebular emission, in contrast with H𝛼, H𝛽, He 𝜆5876.…”

Section: Wn Of/wn and Wn/c Starsmentioning

confidence: 99%

Line Luminosities of Galactic and Magellanic Cloud Wolf-Rayet stars

Crowther¹,

Rate²,

Bestenlehner³

2023

Preprint

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We provide line luminosities and spectroscopic templates of prominent optical emission lines of 133 Galactic Wolf-Rayet stars by exploiting Gaia DR3 parallaxes and optical spectrophotometry, and provide comparisons with 112 counterparts in the Magellanic Clouds. Average line luminosities of the broad blue (He 𝜆4686, C 𝜆𝜆4647,51, N 𝜆𝜆4634,41, N 𝜆𝜆4603,20) and yellow (C 𝜆𝜆5801,12) emission features for WN, WN/C, WC and WO stars have application in characterising the Wolf-Rayet populations of star-forming regions of distant, unresolved galaxies. Early-type WN stars reveal lower line luminosities in more metal poor environments, but the situation is less clear for late-type WN stars. LMC WC4-5 line luminosities are higher than their Milky Way counterparts, with line luminosities of Magellanic Cloud WO stars higher than Galactic stars. We highlight other prominent optical emission lines, N 𝜆𝜆3478,85 for WN and WN/C stars, O 𝜆𝜆3403,13 for WC and WO stars and O 𝜆𝜆3811,34 for WO stars. We apply our calibrations to representative metal-poor and metal-rich WR galaxies, IC 4870 and NGC 3049, respectively, with spectral templates also applied based on a realistic mix of subtypes. Finally, the global blue and C 𝜆𝜆5801,12 line luminosities of the Large (Small) Magellanic Clouds are 2.6×10 38 erg s −1 (9×10 36 erg s −1 ) and 8.8×10 37 erg s −1 (4×10 36 erg s −1 ), respectively, with the cumulative WR line luminosity of the Milky Way estimated to be an order of magnitude higher than the LMC.

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“…A single mechanism may be operating over a wide range of energy and mass, different mechanisms may produce the same observables, or several mechanisms may cooperate. Rotation (Langer 1998;Zhao & Fuller 2020;Shi & Fuller 2022), binary interaction (Kenyon & Gallagher 1985;Gallagher 1989;Smith 2011;Owocki et al 2019;Quataert et al 2016;Soker 2001Soker , 2004Soker , 2007Kashi & Soker 2009;Smith et al 2003;Koenigsberger 2004), and stellar mergers (Iben 1999;Portegies Zwart & van den Heuvel 2016;Hirai et al 2021) may also play a crucial role in shaping the LBV phenomenon.…”

Section: Classical and Giant Eruption Lbvsmentioning

confidence: 99%

Observations of outflows of massive stars

Mehner

2021

Proc. IAU

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Mass loss plays a key role in the evolution of massive stars and their environment. High mass-loss events are traced by complex circumstellar ejecta and intricate line profiles across the upper Hertzsprung-Russell diagram for massive stars in different evolutionary stages. The basic physics of radiation-driven stellar wind for hot stars is well understood. However, the driving mechanisms and related instabilities for their enhanced mass-loss episodes and the driving mechanisms for the mass loss of cool stars are still debated. In this review, the mass-loss characteristics and the possible mechanisms will be surveyed for an observational set of prominent massive stellar populations that experience outflows, strong stellar winds, and periods of enhanced and eruptive mass loss; massive young stellar objects, OB-type stars, red supergiants, warm hypergiants, luminous blue variables, and Wolf-Rayet stars.

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Observational Constraints on the Hd 5980 Wind-Wind Collision

Cited by 5 publications

References 53 publications

Transitory Tidal Heating and Its Impact on Cluster Isochrones

Transitory Tidal Heating and Its Impact on Cluster Isochrones

Line Luminosities of Galactic and Magellanic Cloud Wolf-Rayet stars

Observations of outflows of massive stars

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