A Model for Adiabatic Mass-loss

AbstractWe describe our work on the development and application of a stellar structure code to compute model sequences representing donor stars in interacting binaries subject to rapid (adiabatic) mass-loss. The donor star is assumed to remain in hydrostatic equilibrium, but no heat flow is allowed. These sequences can be used to define bifurcation sequences in close binary evolution, and to circumscribe possible survivors of common envelope evolution.

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Type IIb supernovae by the grazing envelope evolution

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stz3224 ◽

2019 ◽

Cited By ~ 2

Author(s):

Binyamin V Naiman ◽

Efrat Sabach ◽

Avishai Gilkis ◽

Noam Soker

Keyword(s):

Mass Loss ◽

Binary Systems ◽

The Other ◽

Primary Star ◽

Single Star ◽

Common Envelope ◽

Secondary Star ◽

The Core ◽

Free Parameters ◽

Binary Evolution

Abstract We simulate the evolution of binary systems with a massive primary star of 15M⊙ where we introduce an enhanced mass loss due to jets that the secondary star might launch, and find that in many cases the enhanced mass loss brings the binary system to experience the grazing envelope evolution (GEE) and form a progenitor of Type IIb supernova (SN IIb). The jets, the Roche lobe overflow (RLOF), and a final stellar wind remove most of the hydrogen-rich envelope, leaving a blue-compact SN IIb progenitor. In many cases without this jet-driven mass loss the system enters a common envelope evolution (CEE) and does not form a SN IIb progenitor. We use the stellar evolutionary code MESA binary and mimic the jet-driven mass loss with a simple prescription and some free parameters. Our results show that the jet-driven mass loss, that some systems have during the GEE, increases the parameter space for stellar binary systems to form SN IIb progenitors. We estimate that the binary evolution channel with GEE contributes about a quarter of all SNe IIb, about equal to the contribution of each of the other three channels, binary evolution without a GEE, fatal CEE (where the secondary star merges with the core of the giant primary star), and the single star channel.

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The impact of close binary evolution on the properties of the WR-bump emission lines of Wolf-Rayet galaxies

Symposium - International Astronomical Union ◽

10.1017/s007418090021293x ◽

2003 ◽

Vol 212 ◽

pp. 576-577

Author(s):

Joris Van Bever ◽

Dany Vanbeveren

Keyword(s):

Mass Transfer ◽

Neutron Stars ◽

Supernova Explosion ◽

Emission Lines ◽

Close Binary ◽

Population Synthesis ◽

Common Envelope ◽

Solar Metallicity ◽

Binary Evolution ◽

The Impact

We present the results of a study on the behaviour of the blue and red WR emission bumps (around 4650Å and 5808Å) and of the nebular contribution to He ii λ4686 in evolving young starburst regions (such as Wolf-Rayet galaxies), containing a non-negligible binary population. Calculations were made for solar metallicity and 1/20 solar. The population synthesis program uses an extended library of stellar evolutionary tracks of single stars and binaries, computed using the most recent stellar wind mass loss rates during RSG, LBV and WR stages. In the case of binaries, we account in detail for the effects of Roche lobe overflow, mass transfer and mass accretion, common envelope evolution, the spiral-in process, asymmetric kicks to neutron stars as a result of their supernova explosion, etc. This research is part of a more extensive project to explore every possible impact of massive binaries on stellar populations.

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The Evolution of Massive Close Binary Systems : Estimates of the Parameters Governing Mass and Angular Momentum Loss

Symposium - International Astronomical Union ◽

10.1017/s007418090006469x ◽

1980 ◽

Vol 88 ◽

pp. 115-121

Author(s):

D. Vanbeveren ◽

C. De Loore

Keyword(s):

Angular Momentum ◽

Mass Loss ◽

Binary Systems ◽

Mass Loss Rate ◽

Roche Lobe ◽

Close Binary ◽

Close Binaries ◽

Stellar Winds ◽

Binary Evolution ◽

Image Position

It becomes more and more evident that for close binary evolution during Roche lobe overflow as well mass transfer as mass loss occurs. When a mass element ΔM is expelled from the primary during this phase, a fraction β is transferred to the secondary; the remaining part leaves the system. Moreover, angular momentum leaves the system, and also this fraction has to be specified; this fraction is related to a parameter α (Vanbeveren et al., 1979). For the computation of the evolution of massive close binaries also mass loss due to stellar wind of both components, prior to the Roche lobe overflow has to be taken into account. The mass loss rate Ṁ due to radiation driven stellar winds can be expressed as

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ADIABATIC MASS LOSS AND THE OUTCOME OF THE COMMON ENVELOPE PHASE OF BINARY EVOLUTION

The Astrophysical Journal ◽

10.1088/2041-8205/719/1/l28 ◽

2010 ◽

Vol 719 (1) ◽

pp. L28-L31 ◽

Cited By ~ 27

Author(s):

Christopher J. Deloye ◽

Ronald E. Taam

Keyword(s):

Mass Loss ◽

Common Envelope ◽

The Common ◽

Binary Evolution

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Spin rates and spin evolution of O components in WR+O binaries

Astronomy and Astrophysics ◽

10.1051/0004-6361/201732212 ◽

2018 ◽

Vol 615 ◽

pp. A65 ◽

Cited By ~ 7

Author(s):

D. Vanbeveren ◽

N. Mennekens ◽

M. M. Shara ◽

A. F. J. Moffat

Keyword(s):

Mass Transfer ◽

Rotational Velocity ◽

Mass Transfer Process ◽

Roche Lobe ◽

Close Binary ◽

Transfer Phase ◽

Common Envelope ◽

Binary Evolution ◽

The Veil ◽

Critical Rotation Speed

Context. Despite 50 yr of extensive binary research, we must conclude that the Roche lobe overflow/mass transfer process that governs close binary evolution is still poorly understood. Aims. It is the scope of the present paper to lift the edge of the veil by studying the spin-up and spin-down processes of the O-type components of WR+O binaries. Methods. We critically analyzed the available observational data of rotation speeds of the O-type components in WR+O binaries. By combining a binary evolutionary code and a formalism that describes the effects of tides in massive stars with an envelope in radiative equilibrium, we computed the corresponding rotational velocities during the Roche lobe overflow of the progenitor binaries. Results. In all the WR+O binaries studied, we find that the O-type stars were affected by accretion of matter during Roche lobe overflow (RLOF) of the progenitor. This means that common envelope evolution, which excludes any accretion onto the secondary O star, has not played an important role in explaining WR+O binaries. Moreover, although it is very likely that the O-type star progenitors were spun up by mass transfer, many ended the RLOF (and mass transfer) phase with a rotational velocity that is significantly smaller than the critical rotation speed. This may indicate that during the mass transfer phase there is a spin-down process that is of the same order, although significantly less, than that of the spin-up process. We propose a Spruit–Tayler type dynamo spin-down suggested in the past to explain the rotation speeds of the mass gainers in long-period Algols.

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StatStar, A Stellar Structure Code

An Introduction to Modern Astrophysics ◽

10.1017/9781108380980.041 ◽

2017 ◽

pp. 1301-1303

Keyword(s):

Stellar Structure ◽

Structure Code

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Imaging the elusive H-poor gas in planetary nebulae with large abundance discrepancy factors

Proceedings of the International Astronomical Union ◽

10.1017/s1743921317000849 ◽

2016 ◽

Vol 12 (S323) ◽

pp. 65-69 ◽

Cited By ~ 1

Author(s):

Jorge García-Rojas ◽

Romano L. M. Corradi ◽

Henri M. J. Boffin ◽

Hektor Monteiro ◽

David Jones ◽

...

Keyword(s):

Planetary Nebulae ◽

Tunable Filter ◽

Close Binary ◽

Chemical Abundances ◽

Dual Nature ◽

Gas Phases ◽

Binary Evolution ◽

The Universe ◽

Central Stars

AbstractThe discrepancy between abundances computed using optical recombination lines (ORLs) and collisionally excited lines (CELs) is a major, unresolved problem with significant implications for the determination of chemical abundances throughout the Universe. In planetary nebulae (PNe), the most common explanation for the discrepancy is that two different gas phases coexist: a hot component with standard metallicity, and a much colder plasma enhanced in heavy elements. This dual nature is not predicted by mass loss theories, and direct observational support for it is still weak. In this work, we present our recent findings that demonstrate that the largest abundance discrepancies are associated with close binary central stars. OSIRIS-GTC tunable filter imaging of the faint O ii ORLs and MUSE-VLT deep 2D spectrophotometry confirm that O ii ORL emission is more centrally concentrated than that of [Oiii] CELs and, therefore, that the abundance discrepancy may be closely linked to binary evolution.

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Supernovae from massive stars with extended tenuous envelopes

Astronomy and Astrophysics ◽

10.1051/0004-6361/201732363 ◽

2018 ◽

Vol 612 ◽

pp. A61 ◽

Cited By ~ 9

Author(s):

Luc Dessart ◽

Sung-Chul Yoon ◽

Eli Livne ◽

Roni Waldman

Keyword(s):

Massive Stars ◽

Constant Width ◽

Core Material ◽

Close Binary ◽

Reverse Shock ◽

Halo Structure ◽

Deposited Energy ◽

Dense Shell ◽

Low Mass ◽

Binary Evolution

Massive stars with a core-halo structure are interesting objects for stellar physics and hydrodynamics. Using simulations for stellar evolution, radiation hydrodynamics, and radiative transfer, we study the explosion of stars with an extended and tenuous envelope (i.e. stars in which 95% of the mass is contained within 10% or less of the surface radius). We consider both H-rich supergiant and He-giant progenitors resulting from close-binary evolution and dying with a final mass of 2.8–5 M⊙. An extended envelope causes the supernova (SN) shock to brake and a reverse shock to form, sweeping core material into a dense shell. The shock-deposited energy, which suffers little degradation from expansion, is trapped in ejecta layers of moderate optical depth, thereby enhancing the SN luminosity at early times. With the delayed 56Ni heating, we find that the resulting optical and near-IR light curves all exhibit a double-peak morphology. We show how an extended progenitor can explain the blue and featureless optical spectra of some Type IIb and Ib SNe. The dense shell formed by the reverse shock leads to line profiles with a smaller and near-constant width. This ejecta property can explain the statistically narrower profiles of Type IIb compared to Type Ib SNe, as well as the peculiar Hα profile seen in SN 1993J. At early times, our He-giant star explosion model shows a high luminosity, a blue colour, and featureless spectra reminiscent of the Type Ib SN 2008D, suggesting a low-mass progenitor.

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