The Black Hole Mass Distribution in the Galaxy

Özel, Feryal; Psaltis, Dimitrios; Narayan, Ramesh; McClintock, Jeffrey E.

doi:10.1088/0004-637x/725/2/1918

Cited by 687 publications

(590 citation statements)

References 63 publications

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“…The explosion occurs within the first 0.1-0.2 s driven by a convection and neutrino enhanced engine. This "rapid" supernova engine reproduces ) the observed mass gap (apparent lack of neutron stars and black holes with mass in range 2-5 M e ) in Galactic X-ray binaries (Bailyn et al 1998;Özel et al 2010). Additionally, we include NS star formation through electron capture supernovae (ECS) for low mass progenitors M zams ∼ 7-11 M e .…”

Section: Tying It All Together: Population Synthesismentioning

confidence: 65%

“…For a non-spinning BH this occurs already near M BH = 8 M ,  so that BHs of the masses that are thought (Belczynski et al 2008b;Özel et al 2010) to be most likely (∼10 M  ) need large dimensionless spin parameters, a 0.9, BH  to form sizeable disks (Foucart 2012). Finally, the inclination of vector of BH-NS orbital angular momentum to BH spin vector plays an important role in the formation of a torus.…”

Section: Bh-ns Mergersmentioning

confidence: 99%

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The Fate of the Compact Remnant in Neutron Star Mergers

Fryer

Belczyński

Ramírez-Ruiz

et al. 2015

ApJ

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Neutron star (binary neutron star and neutron star-black hole) mergers are believed to produce short-duration gamma-ray bursts (GRBs). They are also believed to be the dominant source of gravitational waves to be detected by the advanced LIGO and advanced VIRGO and the dominant source of the heavy r-process elements in the universe. Whether or not these mergers produce short-duration GRBs depends sensitively on the fate of the core of the remnant (whether, and how quickly, it forms a black hole). In this paper, we combine the results of Newtonian merger calculations and equation of state studies to determine the fate of the cores of neutron star mergers. Using population studies, we can determine the distribution of these fates to compare to observations. We find that black hole cores form quickly only for equations of state that predict maximum non-rotating neutron star masses below 2.3-2.4 solar masses. If quick black hole formation is essential in producing GRBs, LIGO/Virgo observed rates compared to GRB rates could be used to constrain the equation of state for dense nuclear matter.

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Section: Tying It All Together: Population Synthesismentioning

confidence: 65%

Section: Bh-ns Mergersmentioning

confidence: 99%

The Fate of the Compact Remnant in Neutron Star Mergers

Fryer

Belczyński

Ramírez-Ruiz

et al. 2015

ApJ

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“…Although a low system inclination would still allow for a BH more massive than 5 M e , the mass function of GX 339−4 is much lower than has been assumed to date and it may in fact be the first BH to fall in the "mass-gap" of 2-5 M e (Özel et al 2010;Farr et al 2011). …”

Section: Discussionmentioning

confidence: 92%

The Mass Function of GX 339–4 from Spectroscopic Observations of Its Donor Star^*

Heida

Jonker

Torres

et al. 2017

ApJ

110

107

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We obtained 16 VLT/X-shooter observations of GX 339−4 in quiescence during the period 2016 May-September and detected absorption lines from the donor star in its NIR spectrum. This allows us to measure the radial velocity curve and projected rotational velocity of the donor for the first time. We confirm the 1.76 day orbital period and we find that K 2 = 219±3 km s −1 , γ = 26±2 km s −1 , and v i sin = 64±8 km s −1 . From these values we compute a mass function f (M) = 1.91±0.08  M , a factor ∼3 lower than previously reported, and a mass ratio q = 0.18±0.05. We confirm the donor is a K-type star and estimate that it contributes~-4% 50% of the light in the J-and H-bands. We constrain the binary inclination to 37°< < i 78°and the black hole (BH) mass to. GX 339−4 may therefore be the first BH to fall in the "mass-gap" of 2-5 M e .

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“…We summarize the neutron star mass measurements and their uncertainties in each subgroup in Figure 13 and compare them to those of black holes in Figure 14 (compiled and analyzed in Ozel et al 2010a). In these figures, the error bars correspond to a 68% confidence level calculated from the detailed likelihood distribution presented for each subgroup of sources in Section 2.…”

Section: Discussionmentioning

confidence: 99%

On the Mass Distribution and Birth Masses of Neutron Stars

Özel

Psaltis

Narayan

et al. 2012

ApJ

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364

274

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We investigate the distribution of neutron star masses in different populations of binaries, employing Bayesian statistical techniques. In particular, we explore the differences in neutron star masses between sources that have experienced distinct evolutionary paths and accretion episodes. We find that the distribution of neutron star masses in non-recycled eclipsing high-mass binaries as well as of slow pulsars, which are all believed to be near their birth masses, has a mean of 1.28 M and a dispersion of 0.24 M . These values are consistent with expectations for neutron star formation in core-collapse supernovae. On the other hand, double neutron stars, which are also believed to be near their birth masses, have a much narrower mass distribution, peaking at 1.33 M , but with a dispersion of only 0.05 M . Such a small dispersion cannot easily be understood and perhaps points to a particular and rare formation channel. The mass distribution of neutron stars that have been recycled has a mean of 1.48 M and a dispersion of 0.2 M , consistent with the expectation that they have experienced extended mass accretion episodes. The fact that only a very small fraction of recycled neutron stars in the inferred distribution have masses that exceed ∼2 M suggests that only a few of these neutron stars cross the mass threshold to form low-mass black holes.

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The Black Hole Mass Distribution in the Galaxy

Cited by 687 publications

References 63 publications

The Fate of the Compact Remnant in Neutron Star Mergers

The Fate of the Compact Remnant in Neutron Star Mergers

The Mass Function of GX 339–4 from Spectroscopic Observations of Its Donor Star^*

On the Mass Distribution and Birth Masses of Neutron Stars

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The Black Hole Mass Distribution in the Galaxy

Cited by 687 publications

References 63 publications

The Fate of the Compact Remnant in Neutron Star Mergers

The Fate of the Compact Remnant in Neutron Star Mergers

The Mass Function of GX 339–4 from Spectroscopic Observations of Its Donor Star*

On the Mass Distribution and Birth Masses of Neutron Stars

Contact Info

Product

Resources

About

The Mass Function of GX 339–4 from Spectroscopic Observations of Its Donor Star^*