The orbit and stellar masses of the archetype colliding-wind binary WR 140

Thomas, Joshua D.; Richardson, Noel D.; Eldridge, J. J.; Schaefer, Gail H.; Sana, H.; Moffat, A. F. J.; Williams, P. M.; Corcoran, M. F.; Stevens, I. R.; Weigelt, G.; Zainol, Farrah D; Anugu, Narsireddy; Bouquin, Jean-Baptiste Le; Brummelaar, T. ten; Campos, F.; Couperus, Andrew; Davies, Claire L.; Ennis, Jacob; Eversberg, Thomas; Garde, O.; Gardner, Tyler; Fló, J. Guarro; Kraus, Stefan; Labdon, Aaron; Lanthermann, Cyprien; Leadbeater, R.; Lester, T.; Maki, Courtney; McBride, Brendan; Özuyar, Doğuş; Ribeiro, José Pancrácio; Setterholm, Benjamin R.; Stober, Berthold; Wood, Mackenna L.; Zurmühl, Uwe

doi:10.1093/mnras/stab1181

Cited by 30 publications

(45 citation statements)

References 46 publications

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“…1, we compare the time-series observed during the two periastron passages observed by Marchenko et al (2003) and the more recent periastron passage observed by the AAVSO observers. All light curves are plotted using the binary ephemeris from Thomas et al (2021). The 2001 and 2016 periastron passages show variability in deep dips of nearly 0.1 mag in both B and V -bands.…”

Section: Resultsmentioning

confidence: 99%

“…The most famous of these dust-producing systems is WR140 (HD 193793), a binary system containing a WC7 primary and O5.5I-type secondary. It was first discovered to have dust condensation by observation of rapid, periodic brightening in the IR by Williams et al (1978Williams et al ( , 1990Williams et al ( , 2009 and is one of two WC binaries with an established visual and double-lined spectroscopic orbit (Thomas et al 2021), but the only such system with dust emission. This system has been shown to have a 7.93 year period and a high eccentricity of 0.8993 with masses derived to better than 4% accuracy (Thomas et al 2021).…”

Section: Introductionmentioning

confidence: 99%

“…It was first discovered to have dust condensation by observation of rapid, periodic brightening in the IR by Williams et al (1978Williams et al ( , 1990Williams et al ( , 2009 and is one of two WC binaries with an established visual and double-lined spectroscopic orbit (Thomas et al 2021), but the only such system with dust emission. This system has been shown to have a 7.93 year period and a high eccentricity of 0.8993 with masses derived to better than 4% accuracy (Thomas et al 2021). Because of the well-established visual and double-lined orbit, combined with the brightness of the system, WR140's dusty environment has become a fantastic laboratory with which to test dust production models of binary systems and pinpoint the location of the dust production.…”

Section: Introductionmentioning

confidence: 99%

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Optical Photometry of WR140 as the Dust Formed During the 2016 Periastron Passage

Peatt¹,

Richardson²

2022

Preprint

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The colliding wind binary WR140 produces dust in its shocked gas every periastron passage. While the infrared light curve is very repeatable, there are noticeable changes every cycle in the optical time-series photometry. In the phases following periastron, there are optical dips in the light curve that were postulated to be caused by localized clumps in the dust produced in our line of sight. We report on the B and V -band light curves that were recorded by the American Association of Variable Star Observers (AAVSO) after the 2016 periastron event and briefly discuss comparisons to geometric models of the dust production to infer that these features are likely caused by localized dust clumps in the new dust shell.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Optical Photometry of WR140 as the Dust Formed During the 2016 Periastron Passage

Peatt¹,

Richardson²

2022

Preprint

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“…WR 140 = HD 193793 is a double-lined spectroscopic binary with WC7pd and O5.5fc components (Fahed et al 2011). It is well resolved with the CHARA interferometer, which has yielded an exquisite orbit and masses for the component stars (Thomas et al 2021). The O and WR stars of WR 140 were below the resolution limit of 'Alopeke+ Gemini-N when we observed them in June 2020.…”

Section: Wr 140mentioning

confidence: 89%

“…The current state of the art in bright WR binary star resolution is the CHARA interferometer, which is resolving WR companions closer than 1 mas. This has recently resulted in well-resolved orbits for two previously known binaries: WR 137 and WR 138 (Richardson et al 2016), and in addition, solidly determined WR and O star masses for the already-known binaries WR 140 (Thomas et al 2021) and WR 133 (Richardson et al 2021). Unfortunately, CHARA is limited to stars brighter than H ∼ 8.5, and the vast majority of WR stars are fainter than this limit, so it cannot be the 'go-to' instrument in searches for new or faint companions.…”

Section: Ob and Wr Star Binariesmentioning

confidence: 94%

A speckle-imaging search for close and very faint companions to the nearest and brightest Wolf–Rayet stars

Shara

Howell

Furlan

et al. 2021

Monthly Notices of the Royal Astronomical Society

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Gravitationally bound companions to stars enable determinations of their masses, and offer clues to their formation, evolution and dynamical histories. So motivated, we have carried out a speckle imaging survey of eight of the nearest and brightest Wolf-Rayet (WR) stars to directly measure the frequency of their resolvable companions, and to search for much fainter companions than hitherto possible. We found one new, close companion to each of WR 113, WR 115 and WR 120 in the separation range ∼ 0.2” - 1.2”. Our results provide more evidence that similar-brightness, close companions to WR stars are common. More remarkably, they also demonstrate that the predicted, but much fainter and thus elusive companions to WR stars are now within reach of modern speckle cameras on 8m class telescopes by finding the first example. The new companion to WR 113 is just 1.16” distant from it, and is ∼ 8 magnitudes fainter than the WR star. The empirical probability of a chance line-of-sight of the faint companion at the position of WR 113 is < 0.5%, though we cannot yet prove or disprove if the two stars are gravitationally bound. If these three new detections are physical companions we suggest, based on their narrowband magnitudes, colours, reddenings and GAIA distances that the companions to WR113, WR 115 and WR 120 are an F-type dwarf, an early B-type dwarf, and a WNE-type WR star, respectively.

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Photometric and Spectral Studies of the Group of Galactic Wolf-Rayet Stars. I. WN Sequence

Kondratyeva,

Reva,

Denissyuk

et al. 2023

Astrophysics

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The orbit and stellar masses of the archetype colliding-wind binary WR 140

Cited by 30 publications

References 46 publications

Optical Photometry of WR140 as the Dust Formed During the 2016 Periastron Passage

Optical Photometry of WR140 as the Dust Formed During the 2016 Periastron Passage

A speckle-imaging search for close and very faint companions to the nearest and brightest Wolf–Rayet stars

Photometric and Spectral Studies of the Group of Galactic Wolf-Rayet Stars. I. WN Sequence

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