The role of mass transfer and common envelope evolution in the formation of merging binary black holes

Marchant, Pablo; Pappas, K. M. W.; Gallegos-Garcia, Monica; Berry, C. P. L.; Taam, Ronald E.; Kalogera, V.; Podsiadlowski, Philipp

doi:10.1051/0004-6361/202039992

Cited by 107 publications

(129 citation statements)

References 203 publications

(320 reference statements)

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“…The situation is even more complex when considering that our larger suite of models (560 realizations) still only represents a subset of the overall uncertainties in population synthesis studies. For example, even our broader set of models does not account for uncertainties in the stellar evolution tracks (e.g., Laplace et al 2020;Agrawal et al 2020), internal mixing (e.g., Schootemeĳer et al 2019), stellar rotation (e.g., de Mink & Mandel 2016Mapelli et al 2020), the more complex physics of the CE phase (e.g., Klencki et al 2021;Ivanova et al 2020;Marchant et al 2021;Olejak et al 2021), the additional possible remnant mass prescriptions (e.g. Dabrowny et al 2021;, the initial conditions of binary systems (e.g., de Mink & Belczynski 2015;Moe & Di Stefano 2017;Klencki et al 2018), and the possible contributions from other formation channels (e.g., Zevin et al 2021).…”

Section: A Realistic View Of Population Synthesis Modelsmentioning

confidence: 99%

Impact of Massive Binary Star and Cosmic Evolution on Gravitational Wave Observations II: Double Compact Object Rates and Properties

Broekgaarden,

Berger,

Stevenson

et al. 2021

Preprint

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Making the most of the rapidly increasing population of gravitational-wave detections of black hole (BH) and neutron star (NS) mergers requires comparing observations with population synthesis predictions. In this work we investigate the combined impact from the key uncertainties in population synthesis modelling of the isolated binary evolution channel: the physical processes in massive binary-star evolution and the star formation history as a function of metallicity, 𝑍, and redshift 𝑧, S(𝑍, 𝑧). Considering these uncertainties we create 560 different publicly available model realizations and calculate the rate and distribution characteristics of detectable BHBH, BHNS, and NSNS mergers. We find that our stellar evolution and S(𝑍, 𝑧) variations can impact the predicted intrinsic and detectable merger rates by factors 10 2 -10 4 . We find that BHBH rates are dominantly impacted by S(𝑍, 𝑧) variations, NSNS rates by stellar evolution variations and BHNS rates by both. We then consider the combined impact from all uncertainties considered in this work on the detectable mass distribution shapes (chirp mass, individual masses and mass ratio). We find that the BHNS mass distributions are predominantly impacted by massive binary-star evolution changes. For BHBH and NSNS we find that both uncertainties are important. We also find that the shape of the delay time and birth metallicity distributions are typically dominated by the choice of S(𝑍, 𝑧) for BHBH, BHNS and NSNS. We identify several examples of robust features in the mass distributions predicted by all 560 models, such that we expect more than 95 percent of BHBH detections to contain a BH 8 M and have mass ratios 4. Our work demonstrates that it is essential to consider a wide range of allowed models to study double compact object merger rates and properties. Conversely, larger observed samples could allow us to decipher currently unconstrained stages of stellar and binary evolution.

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Section: A Realistic View Of Population Synthesis Modelsmentioning

confidence: 99%

Impact of Massive Binary Star and Cosmic Evolution on Gravitational Wave Observations II: Double Compact Object Rates and Properties

Broekgaarden,

Berger,

Stevenson

et al. 2021

Preprint

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“…We have generated a suite of detailed binary stellar evolution models, examining angular momentum (AM) transport and core rotation rates of massive helium stars in close binary systems. Such binaries could possibly be formed via common envelope evolution (e.g., Belczynski et al 2002), or via stable mass transfer (e.g., Marchant et al 2021), which may be more likely for massive helium stars (Klencki et al 2020). Our models improve upon prior efforts by implementing an updated AM transport prescription based on magnetic torques associated with the Tayler instability (Fuller et al 2019), which has been calibrated with asteroseismic core rotation rates of low-mass red giant stars.…”

Section: Discussionmentioning

confidence: 96%

“…The discrepancy is even worse when one considers that the ejecta mass of our massive models would be far larger than 5 M , meaning that the ejecta velocity would be smaller than 15, 000 km/s and those SNe would not appear broad-lined. Another problem with this scenario is that such massive He stars may be less likely to form via a common envelope event (Klencki et al 2020;Marchant et al 2021;van Son et al 2021), and less likely to explode (O'Connor & Ott 2011;Zapartas et al 2021). This may disfavor magnetars as the power source of most Ic-BL SNe.…”

Section: Magnetar Central Enginesmentioning

confidence: 99%

“…Several recent works (e.g., Pavlovskii et al 2017;Klencki et al 2020;van Son et al 2021;Marchant et al 2021) have argued that many merging BHs may form via orbital decay during stable mass transfer rather than common envelope evolution. Our models are agnostic to the progenitor channel as long as it produces a nearly hydrogen-free progenitor star in a short-period orbit, and as long as the envelope stripping occurs on a very short time scale.…”

Section: Stable Mass Transfermentioning

confidence: 99%

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The spins of compact objects born from helium stars in binary systems

Fuller,

2022

Preprint

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The angular momentum (AM) content of massive stellar cores helps to determine the natal spin rates of neutron stars and black holes. Asteroseismic measurements of low-mass stars have proven that stellar cores rotate slower than predicted by most prior work, so revised models are necessary. In this work, we apply an updated AM transport model based on the Tayler instability to massive helium stars in close binaries, in which tidal spin-up can greatly increase the star's AM. Consistent with prior work, these stars can produce highly spinning black holes upon core-collapse if the orbital period is less than P orb 1 day. For neutron stars, we predict a strong correlation between the pre-explosion mass and the neutron star rotation rate, with millisecond periods (P NS 5 ms) only achievable for massive (M 10 M ) helium stars in tight (P orb 1 day) binaries. Finally, we discuss our models in relation to type Ib/c supernovae, superluminous supernove, gamma-ray bursts, and LIGO measurements of black hole spins. Our models are roughly consistent with the rates and energetics of these phenomena, with the exception of broad-lined Ic supernovae, whose high rates and ejecta energies are difficult to explain.

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“…Furthermore, the boundary between stable and unstable mass transfer when a star fills its Roche lobe around a companion is poorly understood, especially in triples. Here, we adopted a strongly simplified criterion (based on Hurley et al 2002), whereas it is known that such criteria based on population synthesis methods can over-predict the occurrence rate of CE in binaries (e.g., Woods & Ivanova 2011;Ge et al 2015;Marchant et al 2021). Evidently, these uncertainties are even more severe in the triple case.…”

Section: Caveats and Future Improvementsmentioning

confidence: 99%

A statistical view on stable and unstable Roche lobe overflow of a tertiary star onto the inner binary in triple systems

Hamers,

Glanz,

Neunteufel

2021

Preprint

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In compact stellar triple systems, an evolved tertiary star can overflow its Roche lobe around the inner binary. Subsequently, the tertiary star can transfer mass to the inner binary in a stable manner, or Roche lobe overflow (RLOF) can be unstable and lead to common-envelope (CE) evolution. In the latter case, the inner binary enters the extended envelope of the tertiary star and spirals in towards the donor's core, potentially leading to mergers or ejections. Although studied in detail for individual systems, a comprehensive statistical view on the various outcomes of triple RLOF is lacking. Here, we carry out 10 5 population synthesis simulations of tight triples, self-consistently taking into account stellar evolution, binary interactions, and gravitational dynamics. Also included are prescriptions for the long-term evolution of stable triple mass transfer, and triple CE evolution. Although simple and ignoring hydrodynamic effects, these prescriptions allow for a qualitative statistical study. We find that triple RLOF occurs in ∼ 0.06% of triples, with ∼ 64% leading to stable mass transfer, and ∼ 36% to triple CE evolution. Triple CE is most often (∼ 76%) followed by one or multiple mergers in short succession, most likely an inner binary merger of two main-sequence stars. Other outcomes of triple CE are a binary+single system (∼ 23%, most of which not involving exchange interactions), and a stable triple (∼ 1%). We also estimate the rate of Type Ia supernovae involving white dwarf mergers following triple RLOF, but find only a negligible contribution.

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The role of mass transfer and common envelope evolution in the formation of merging binary black holes

Cited by 107 publications

References 203 publications

Impact of Massive Binary Star and Cosmic Evolution on Gravitational Wave Observations II: Double Compact Object Rates and Properties

Impact of Massive Binary Star and Cosmic Evolution on Gravitational Wave Observations II: Double Compact Object Rates and Properties

The spins of compact objects born from helium stars in binary systems

A statistical view on stable and unstable Roche lobe overflow of a tertiary star onto the inner binary in triple systems

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