The Role of Natal Kicks in Forming Asymmetric Compact Binary Mergers

Oh, Madeline; Fishbach, M.; Kimball, C.; Kalogera, V.; Ye, Christine

doi:10.3847/1538-4357/ace349

Cited by 7 publications

(5 citation statements)

References 85 publications

(99 reference statements)

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“…The absolute value of the neutrino kick is subdominant but reaches ∼400 km s −1 . The aggregate kick speed is quite unlike the birth kicks inferred for the stellarmass black holes in X-ray binaries (Willems et al 2005;Atri et al 2019;Oh et al 2023) and suggests that the black holes of this birth channel are unlikely to have companions. This would make observing the population of such black holes exceedingly difficult.…”

Section: Recoil Kick and Induced Rotationmentioning

confidence: 75%

“…The anisotropic blast hydrodynamics, aspherical infall, asymmetric neutrino emissions, and integrated anisotropic gravitational attraction between the core and clumpy ejecta together result in a net recoil kick of the PNS core. Pulsars as a group manifest some of the fastest speeds seen in the galaxy (Lyne & Lorimer 1994;Burrows & Hayes 1996;Faucher-Giguère & Kaspi 2006;Scheck et al 2006Scheck et al , 2008Ng & Romani 2007;Nordhaus et al 2012;Wongwathanarat et al 2013;Janka 2017;Yang et al 2021;), but black holes have generally been thought to receive a significantly smaller recoil kick (Willems et al 2005;Atri et al 2019;Oh et al 2023). However, the grossly asymmetrical explosion dynamics of our 40 M e model results in a kick speed (absolute value of the vector sum of the various components) just before black hole formation of ∼1150 km s −1 (Janka 2013), using the formalism of .…”

Section: Recoil Kick and Induced Rotationmentioning

confidence: 93%

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Black Hole Formation Accompanied by the Supernova Explosion of a 40 M _⊙ Progenitor Star

Burrows,

Vartanyan,

Wang

2023

ApJ

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We have simulated the collapse and evolution of the core of a solar-metallicity 40 M ⊙ star and find that it explodes vigorously by the neutrino mechanism, despite its very high “compactness.” Within ∼1.5 s of explosion, a black hole forms. The explosion is very asymmetrical and has a total explosion energy of ∼1.6 × 1051 erg. At black hole formation, its baryon mass is ∼2.434 M ⊙ and gravitational mass is 2.286 M ⊙. Seven seconds after black hole formation, an additional ∼0.2 M ⊙ is accreted, leaving a black hole baryon mass of ∼2.63 M ⊙. A disk forms around the proto−neutron star, from which a pair of neutrino-driven jets emanates. These jets accelerate some of the matter up to speeds of ∼45,000 km s−1 and contain matter with entropies of ∼50. The large spatial asymmetry in the explosion results in a residual black hole recoil speed of ∼1000 km s−1. This novel black hole formation channel now joins the other black hole formation channel between ∼12 and ∼15 M ⊙ discovered previously and implies that the black hole/neutron star birth ratio for solar-metallicity stars could be ∼20%. However, one channel leaves black holes in perhaps the ∼5–15 M ⊙ range with low kick speeds, while the other leaves black holes in perhaps the ∼2.5–3.0 M ⊙ mass range with high kick speeds. However, even ∼8.8 s after core bounce the newly formed black hole is still accreting at a rate of ∼2 × 10−2 M ⊙ s−1, and whether the black hole eventually achieves a significantly larger mass over time is yet to be determined.

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Section: Recoil Kick and Induced Rotationmentioning

confidence: 75%

Section: Recoil Kick and Induced Rotationmentioning

confidence: 93%

Black Hole Formation Accompanied by the Supernova Explosion of a 40 M _⊙ Progenitor Star

Burrows,

Vartanyan,

Wang

2023

ApJ

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“…The MT stability is also affected by the star's rotation. For instance, when an accretor (i.e., BH in this work) rotates, the accretion rate of the rotating accretor might be reduced by a factor of (1 − ω/ω crit ) (e.g., Stancliffe & Eldridge 2009;Ablimit 2021;Ablimit et al 2022;Oh et al 2023).…”

Section: Main Physics Adopted In Mesamentioning

confidence: 99%

A Channel to Form Fast-spinning Black Hole–Neutron Star Binary Mergers as Multimessenger Sources. II. Accretion-induced Spin-up

Wang,

Hu,

Qin

et al. 2024

ApJ

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In this work, we investigate an alternative channel for the formation of fast-spinning black hole–neutron star (BHNS) binaries, in which super-Eddington accretion is expected to occur in accreting BHs during the stable mass transfer phase within BH-stripped helium (BH–He-rich) star binary systems. We evolve intensive MESA grids of close-orbit BH–He-rich star systems to systematically explore the projected aligned spins of BHs in BHNS binaries, as well as the impact of different accretion limits on the tidal disruption probability and electromagnetic (EM) signature of BHNS mergers. Most of the BHs in BHNS mergers cannot be effectively spun up through accretion if the accretion rate is limited to ≲ 10 M ̇ Edd , where M ̇ Edd is the standard Eddington accretion limit. In order to reach high spins (e.g., χ BH ≳ 0.5), the BHs are required to be born less massive (e.g., ≲3.0 M ⊙) in binary systems with initial periods of ≲0.2–0.3 days and accrete material at ∼ 100 M ̇ Edd . However, even under this high accretion limit, ≳6 M ⊙ BHs are typically challenging to significantly spin up and generate detectable associated EM signals. Our population simulations suggest that different accretion limits have a slight impact on the ratio of tidal disruption events. However, as the accretion limit increases, the EM counterparts from the cosmological BHNS population can become bright overall.

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“…Supernova kicks may also be different for firstborn versus secondborn components in merging binaries, because kicks determine whether or not the binary can merge within the age of the Universe (Kalogera 1996;Gallegos-Garcia et al 2022). Because natal kicks are related to the remnant mass via the supernova prescription (Fryer et al 2012;Mandel et al 2021), different preferences for the natal kick magnitudes between firstborn and secondborn BHs may cause the primary and secondary mass distributions to differ in merging binaries formed through isolated binary evolution (e.g., Oh et al 2023).…”

Section: Introductionmentioning

confidence: 99%

Two of a Kind: Comparing Big and Small Black Holes in Binaries with Gravitational Waves

Farah,

Fishbach,

Holz

2024

ApJ

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When modeling the population of merging binary black holes, analyses have generally focused on characterizing the distribution of primary (i.e., more massive) black holes in the binary, while using simplistic prescriptions for the distribution of secondary masses. However, the secondary mass distribution and its relationship to the primary mass distribution provide a fundamental observational constraint on the formation history of coalescing binary black holes. If both black holes experience similar stellar evolutionary processes prior to collapse, as might be expected in dynamical formation channels, the primary and secondary mass distributions would show similar features. If they follow distinct evolutionary pathways (for example, due to binary interactions that break symmetry between the initially more massive and less massive stars), their mass distributions may differ. We present the first analysis of the binary black hole population that explicitly fits for the secondary mass distribution. We find that the data is consistent with a ∼30 M ⊙ peak existing only in the distribution of secondary rather than primary masses. This would have major implications for our understanding of the formation of these binaries. Alternatively, the data is consistent with the peak existing in both component mass distributions, a possibility not included in most previous studies. In either case, the peak is observed at 31.4 − 2.6 + 2.3 M ⊙ , which is shifted lower than the value obtained in previous analyses of the marginal primary mass distribution, placing this feature in further tension with expectations from a pulsational pair-instability supernova pileup.

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The Role of Natal Kicks in Forming Asymmetric Compact Binary Mergers

Cited by 7 publications

References 85 publications

Black Hole Formation Accompanied by the Supernova Explosion of a 40 M _⊙ Progenitor Star

Black Hole Formation Accompanied by the Supernova Explosion of a 40 M _⊙ Progenitor Star

A Channel to Form Fast-spinning Black Hole–Neutron Star Binary Mergers as Multimessenger Sources. II. Accretion-induced Spin-up

Two of a Kind: Comparing Big and Small Black Holes in Binaries with Gravitational Waves

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The Role of Natal Kicks in Forming Asymmetric Compact Binary Mergers

Cited by 7 publications

References 85 publications

Black Hole Formation Accompanied by the Supernova Explosion of a 40 M ⊙ Progenitor Star

Black Hole Formation Accompanied by the Supernova Explosion of a 40 M ⊙ Progenitor Star

A Channel to Form Fast-spinning Black Hole–Neutron Star Binary Mergers as Multimessenger Sources. II. Accretion-induced Spin-up

Two of a Kind: Comparing Big and Small Black Holes in Binaries with Gravitational Waves

Contact Info

Product

Resources

About

Black Hole Formation Accompanied by the Supernova Explosion of a 40 M _⊙ Progenitor Star

Black Hole Formation Accompanied by the Supernova Explosion of a 40 M _⊙ Progenitor Star