Do high-spin high mass X-ray binaries contribute to the population of merging binary black holes?

Gallegos-Garcia, Monica; Fishbach, M.; Kalogera, V.; Berry, C. P. L.; Doctor, Z.

doi:10.48550/arxiv.2207.14290

Cited by 2 publications

(2 citation statements)

References 66 publications

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“…The rationale for allowing the possibility χ 1 → 1 is twofold: first, the estimated spins of BHs observed in HMXBs are apparently all quite large (Miller-Jones et al 2021) with values between 0.84 and 0.99; and, second, some of the most massive BH components (and thus in general expected to have formed first) in recorded BH+BH mergers seem to possess rather large values of χ 1 (Abbott et al 2022b, with the usual caveat that these measurements have large uncertainties in general). This evidence suggests that either (i) isolated binary evolution may produce larger spins of the first-born BHs than predicted from current theory, (ii) the BHs in these HMXBs and BH+BH merger sources could possibly have obtained their rapid spins from chemical homogeneous evolution (Mandel & de Mink 2016;Marchant et al 2016), or (iii) the general populations of (near-)Galactic HMXBs with rapid BH spins and BH+BH mergers are distinct (Gallegos-Garcia et al 2022). The rapidly spinning BHs in the former population may give support to the third possibility and could therefore conveniently alleviate the problem of aligning rapidly spinning BHs (see below), following a core collapse with spin-axis tossing.…”

Section: Bh Component Spins and Alignmentmentioning

confidence: 76%

Tossing Black Hole Spin Axes

Tauris

2022

ApJ

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The detection of double black hole (BH+BH) mergers provides a unique possibility to understand their physical properties and origin. To date, the LIGO–Virgo–KAGRA network of high-frequency gravitational-wave observatories has announced the detection of more than 85 BH+BH merger events. An important diagnostic feature that can be extracted from the data is the distribution of effective inspiral spins of the BHs. This distribution is in clear tension with theoretical expectations from both an isolated binary star origin, which traditionally predicts close-to-aligned BH component spins, and formation via dynamical interactions in dense stellar environments that predicts a symmetric distribution of effective inspiral spins. Here it is demonstrated that isolated binary evolution can convincingly explain the observed data if BHs have their spin axis tossed during their formation process in the core collapse of a massive star, similarly to the process evidently acting in newborn neutron stars. BH formation without spin-axis tossing, however, has difficulties reproducing the observed data—even if alignment of spins prior to the second core collapse is disregarded. Based on simulations with only a minimum of assumptions, constraints from empirical data can be made on the spin magnitudes of the first- and second-born BHs, thereby serving to better understand massive binary star evolution prior to the formation of BHs.

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Section: Bh Component Spins and Alignmentmentioning

confidence: 76%

Tossing Black Hole Spin Axes

Tauris

2022

ApJ

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“…However, it is worth nothing that there may still be additional channels that contribute to the formation of binary black holes that are not currently modelled within COMPAS, such as formation through stable mass transfer on the main sequence (so called case A mass transfer) (Valsecchi et al 2010;Qin et al 2019;Neĳssel et al 2021), though we do not expect this to be the dominant channel (cf. Gallegos-Garcia et al 2022).…”

Section: Methodsmentioning

confidence: 99%

Constraints on the contributions to the observed binary black hole population from individual evolutionary pathways in isolated binary evolution

Stevenson

Clarke

2022

Monthly Notices of the Royal Astronomical Society

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Gravitational waves from merging binary black holes can be used to shed light on poorly understood aspects of massive binary stellar evolution, such as the evolution of massive stars (including their mass-loss rates), the common envelope phase, and the rate at which massive stars form throughout the cosmic history of the Universe. In this paper we explore the correlated impact of these phases on predictions for the merger rate and chirp mass distribution of merging binary black holes, aiming to identify possible degeneracies between model parameters. In many of our models, a large fraction (more than 70 per cent of detectable binary black holes) arise from the chemically homogeneous evolution scenario; these models tend to over-predict the binary black hole merger rate and produce systems which are on average too massive. Our preferred models favour enhanced mass-loss rates for helium rich Wolf–Rayet stars, in tension with recent theoretical and observational developments. We identify correlations between the impact of the mass-loss rates of Wolf–Rayet stars and the metallicity evolution of the Universe on the rates and properties of merging binary black holes. Based on the observed mass distribution, we argue that the $\sim 10{{\%}}$ of binary black holes with chirp masses greater than 40 M⊙ (the maximum predicted by our models) are unlikely to have formed through isolated binary evolution, implying a significant contribution (>10 per cent) from other formation channels such as dense star clusters or active galactic nuclei. Our models will enable inference on the uncertain parameters governing binary evolution in the near future.

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Do high-spin high mass X-ray binaries contribute to the population of merging binary black holes?

Cited by 2 publications

References 66 publications

Tossing Black Hole Spin Axes

Tossing Black Hole Spin Axes

Constraints on the contributions to the observed binary black hole population from individual evolutionary pathways in isolated binary evolution

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