No evidence that the majority of black holes in binaries have zero spin

Callister, Thomas A.; Miller, Simona J.; Chatziioannou, Katerina; Farr, Will M.

doi:10.48550/arxiv.2205.08574

Cited by 10 publications

(20 citation statements)

References 74 publications

(142 reference statements)

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“…For the case of GW190521, a strong precession signature was also reported [14], though potential degeneracies with the eccentricity still need to be fully understood [20]. Collective evidence for spin precession was reported in the context of BH binary populations, with all current fits requiring some misaligned spins at high confidence [21][22][23].…”

Section: Introductionmentioning

confidence: 95%

Characterization of merging black holes with two precessing spins

De Renzis,

Gerosa,

Pratten

et al. 2022

Preprint

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Spin precession in merging black-hole binaries is a treasure trove for both astrophysics and fundamental physics. There are now well-established strategies to infer from gravitational-wave data whether at least one of the two black holes is precessing. In this paper we tackle the next-in-line target, namely the statistical assessment that the observed system has two precessing spins. We find that the recently-developed generalization of the effective precession spin parameter χp is a well-suited estimator to this task. With this estimator, the occurrence of two precessing spins is a necessary (though not sufficient) condition to obtain values 1 < χp ≤ 2. Confident measurements of gravitational-wave sources with χp values in this range can be taken as a conservative assessment that the binary presents two precessing spins. We investigate this argument using a large set of >100 software injections assuming anticipated LIGO/Virgo sensitivities for the upcoming fourth observing run, O4. Our results are very encouraging, suggesting that, if such binaries exist in nature and merge at a sufficient rate, current interferometers are likely to deliver the first confident detection of merging black holes with two precessing spins. We investigate prior effects and waveform systemics and, though these need to be better investigated, did not find any confident false-positive case among all the configurations we tested. Our assessment should thus be taken as conservative.

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Section: Introductionmentioning

confidence: 95%

Characterization of merging black holes with two precessing spins

De Renzis,

Gerosa,

Pratten

et al. 2022

Preprint

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“…Other important but contended features of the BBH spin distribution include the possibility of a zerospin excess (Roulet et al 2021;Galaudage et al 2021), and the presence of systems with spin-orbit misalign-ments larger than 90 • (implying χ eff < 0) (Abbott et al 2021c,d). Implementing a series of hierarchical analyses of the BBH population, Callister et al (2022) found preference for significant spin-orbit misalignment among the merging BBH population, but show that there is no evidence that GW data includes an excess of zero-spin systems. This latter point is in agreement with other studies (Kimball et al 2020(Kimball et al , 2021Mould et al 2022), and indicates that the majority of merging BBHs have small but non-zero spin (Abbott et al 2021c).…”

Section: Introductionmentioning

confidence: 96%

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

Gallegos-Garcia¹,

Fishbach²,

Kalogera³

et al. 2022

Preprint

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Gravitational-wave observations of binary black hole (BBH) systems point to black hole spin magnitudes being relatively low. These measurements appear in tension with high spin measurements for high-mass X-ray binaries (HMXBs). We use grids of MESA simulations combined with the rapid population-synthesis code COSMIC to examine the origin of these two binary populations. It has been suggested that Case-A mass transfer while both stars are on the main sequence can form high-spin BHs in HMXBs. Assuming this formation channel, we show that depending on critical mass ratios for the stability of mass transfer, 48-100% of these Case-A HMXBs merge during the common-envelope phase and up to 42% result in binaries too wide to merge within a Hubble time. Both MESA and COSMIC show that high-spin HMXBs formed through Case-A mass transfer can only form merging BBHs within a small parameter space where mass transfer can lead to enough orbital shrinkage to merge within a Hubble time. We find that only up to 11% of these Case-A HMXBs result in BBH mergers, and at most 20% of BBH mergers came from Case-A HMXBs. Therefore, it is not surprising that these two spin distributions are observed to be different.

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“…Combining information across multiple events, Abbott et al (2021bAbbott et al ( , 2021c and Callister et al (2022) found that the BBH population likely contains systems with (small) negative χ eff (χ eff  −0.02), but this evidence weakens under population models that include a correlation between χ eff and mass ratio (Callister et al 2021) or a nonspinning subpopulation that would create a narrow peak at zero in the χ eff distribution (Galaudage et al 2021;Roulet et al 2021). Disentangling small negative χ eff from nonspinning systems requires resolving the χ eff distribution to very small scales, -( )  10 2 (Callister et al 2022). If dynamically assembled BBHs always consist of slowly spinning, or even nonspinning, BHs (Fuller & Ma 2019), the ambiguity around the presence of systems with negative χ eff will persist.…”

Section: Introductionmentioning

confidence: 99%

“…However, a few GWTC-3 events, GW191109 010717 and GW200225 060421 have χ eff < 0 with 90% and 85% credibility, respectively (Abbott et al 2021a), and lower-significance candidate events with negative χ eff have been reported in independent analyses (Venumadhav et al 2020;Olsen et al 2022). Combining information across multiple events, Abbott et al (2021c,b) and Callister et al (2022) find that the BBH population likely contains systems with (small) negative χ eff (χ eff −0.02), but this evidence weakens under population models that include a correlation between χ eff and mass ratio (Callister et al 2021), or a nonspinning subpopulation that would create a narrow peak at zero in the χ eff distribution (Roulet et al 2021a;Galaudage et al 2021). Disentangling small negative χ eff from nonspinning systems requires resolving the χ eff distribution to very small scales O(10 −2 ) (Callister et al 2022).…”

Section: Introductionmentioning

confidence: 99%

Limits on Hierarchical Black Hole Mergers from the Most Negative χ _eff Systems

Fishbach

Kimball

Kalogera

2022

ApJL

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It has been proposed that some black holes (BHs) in binary black hole (BBH) systems are born from “hierarchical mergers” (HMs), i.e., earlier mergers of smaller BHs. These HM products have spin magnitudes χ ∼ 0.7, and, if they are dynamically assembled into BBH systems, their spin orientations will sometimes be antialigned with the binary orbital angular momentum. In fact, as Baibhav et al. showed, ∼16% of BBH systems that include HM products will have an effective inspiral spin parameter, χ eff < −0.3. Nevertheless, the LIGO–Virgo–KAGRA (LVK) gravitational-wave (GW) detectors have yet to observe a BBH system with χ eff ≲ −0.2, leading to upper limits on the fraction of HM products in the population. We fit the astrophysical mass and spin distribution of BBH systems and measure the fraction of BBH systems with χ eff < −0.3, which implies an upper limit on the HM fraction. We find that fewer than 26% of systems in the underlying BBH population include HM products (90% credibility). Even among BBH systems with primary masses m 1 = 60 M ⊙, the HM fraction is less than 69%, which may constrain the location of the pair-instability mass gap. With 300 GW events (to be expected in the LVK’s next observing run), if we fail to observe a BBH with χ eff < −0.3, we can conclude that the HM fraction is smaller than 2.5 − 2.2 + 9.1 % .

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No evidence that the majority of black holes in binaries have zero spin

Cited by 10 publications

References 74 publications

Characterization of merging black holes with two precessing spins

Characterization of merging black holes with two precessing spins

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

Limits on Hierarchical Black Hole Mergers from the Most Negative χ _eff Systems

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No evidence that the majority of black holes in binaries have zero spin

Cited by 10 publications

References 74 publications

Characterization of merging black holes with two precessing spins

Characterization of merging black holes with two precessing spins

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

Limits on Hierarchical Black Hole Mergers from the Most Negative χ eff Systems

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Product

Resources

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Limits on Hierarchical Black Hole Mergers from the Most Negative χ _eff Systems