Wolf-Rayet stars in the Magellanic clouds. VI. Spectroscopic orbits of WC binaries and implications for W-R evolution

Spectroscopic orbits are obtained for the first time for the three brightest WC + O binary systems in the LMC. An improved orbit is obtained for the bright WO + O system in the SMC. In one of the LMC systems the observed O companion is stationary; the remaining three systems show antiphased orbits o...

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Detalles Bibliográficos
Publicado: 1990
Materias:
Galaxies: Magellanic Clouds
Stars: binaries
Stars: evolution
Stars: Wolf-Rayet
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_0004637X_v348_n1_p232_Moffat
http://hdl.handle.net/20.500.12110/paper_0004637X_v348_n1_p232_Moffat
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paper:paper_0004637X_v348_n1_p232_Moffat
record_format dspace
spelling paper:paper_0004637X_v348_n1_p232_Moffat2023-06-08T14:28:28Z Wolf-Rayet stars in the Magellanic clouds. VI. Spectroscopic orbits of WC binaries and implications for W-R evolution Galaxies: Magellanic Clouds Stars: binaries Stars: evolution Stars: Wolf-Rayet Spectroscopic orbits are obtained for the first time for the three brightest WC + O binary systems in the LMC. An improved orbit is obtained for the bright WO + O system in the SMC. In one of the LMC systems the observed O companion is stationary; the remaining three systems show antiphased orbits of both components. Two of the LMC binary systems have very short periods (1.9 and 3.0 d), similar to the lower limit for periods of known WN + O and O + O binary systems in general. This means that orbital angular momentum must have been lost from the system in addition to that associated with the extreme mass loss of the present WC components, but not necessarily via mass transfer. On the basis of the double-line orbits for 10 known WC + O binaries in the Galaxy and the Magellanic Clouds, there emerges a continuous decrease of mass ratio M(WC)/M(O) with WC subtype, from 0.5 for WC8 to 0.2 for WC4, WO. Assuming that the initial mass ratio was ≳1, this implies that WC stars can evolve from WN stars and from cooler to hotter subtypes within the WC sequence, with mean mass-loss rate ∼4 × 10-5 M⊙ yr-1. It is noted that in WC + O binaries it is the mass ratio, not the mass, which probably best reflects the degree of evolution of the WC component to hotter subtypes, regardless of the initial mass. 1990 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_0004637X_v348_n1_p232_Moffat http://hdl.handle.net/20.500.12110/paper_0004637X_v348_n1_p232_Moffat
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Galaxies: Magellanic Clouds
Stars: binaries
Stars: evolution
Stars: Wolf-Rayet
spellingShingle Galaxies: Magellanic Clouds
Stars: binaries
Stars: evolution
Stars: Wolf-Rayet
Wolf-Rayet stars in the Magellanic clouds. VI. Spectroscopic orbits of WC binaries and implications for W-R evolution
topic_facet Galaxies: Magellanic Clouds
Stars: binaries
Stars: evolution
Stars: Wolf-Rayet
description Spectroscopic orbits are obtained for the first time for the three brightest WC + O binary systems in the LMC. An improved orbit is obtained for the bright WO + O system in the SMC. In one of the LMC systems the observed O companion is stationary; the remaining three systems show antiphased orbits of both components. Two of the LMC binary systems have very short periods (1.9 and 3.0 d), similar to the lower limit for periods of known WN + O and O + O binary systems in general. This means that orbital angular momentum must have been lost from the system in addition to that associated with the extreme mass loss of the present WC components, but not necessarily via mass transfer. On the basis of the double-line orbits for 10 known WC + O binaries in the Galaxy and the Magellanic Clouds, there emerges a continuous decrease of mass ratio M(WC)/M(O) with WC subtype, from 0.5 for WC8 to 0.2 for WC4, WO. Assuming that the initial mass ratio was ≳1, this implies that WC stars can evolve from WN stars and from cooler to hotter subtypes within the WC sequence, with mean mass-loss rate ∼4 × 10-5 M⊙ yr-1. It is noted that in WC + O binaries it is the mass ratio, not the mass, which probably best reflects the degree of evolution of the WC component to hotter subtypes, regardless of the initial mass.
title Wolf-Rayet stars in the Magellanic clouds. VI. Spectroscopic orbits of WC binaries and implications for W-R evolution
title_short Wolf-Rayet stars in the Magellanic clouds. VI. Spectroscopic orbits of WC binaries and implications for W-R evolution
title_full Wolf-Rayet stars in the Magellanic clouds. VI. Spectroscopic orbits of WC binaries and implications for W-R evolution
title_fullStr Wolf-Rayet stars in the Magellanic clouds. VI. Spectroscopic orbits of WC binaries and implications for W-R evolution
title_full_unstemmed Wolf-Rayet stars in the Magellanic clouds. VI. Spectroscopic orbits of WC binaries and implications for W-R evolution
title_sort wolf-rayet stars in the magellanic clouds. vi. spectroscopic orbits of wc binaries and implications for w-r evolution
publishDate 1990
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_0004637X_v348_n1_p232_Moffat
http://hdl.handle.net/20.500.12110/paper_0004637X_v348_n1_p232_Moffat
_version_ 1768544711367196672

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