Neutron Star Quantum Death by Small Black Holes

Giffin, Pierce; Lloyd, John; McDermott, Samuel D.; Profumo, Stefano

doi:10.48550/arxiv.2105.06504

Cited by 7 publications

(6 citation statements)

References 40 publications

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“…As mentioned, an isolated PBH is commonly assumed, but as PBHs form just after inflation they will interact with the radiation dominated, almost homogeneous early universe. [110] found that accounting for those interactions pushed the minimum mass of PBHs to 10 14 g instead, with [111] reaching a similar conclusion via a very different method of constantly accreting matter instead.…”

Section: Black Hole Evaporationmentioning

confidence: 95%

Constraints on PBH as dark matter from observations: a review

Oncins¹

2022

Preprint

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Primordial black holes (PBHs) are a fascinating candidate for being the dark matter, albeit one which has been heavily constrained. This review presents an in depth look at those observational constraints, particularly at their nuances and uncertainties. Despite their varied origins, the standard PBH formation path is assumed to be collapse of perturbations after inflation, which should leave signals visible in the CMB at certain scales. Other constraints come from microlensing surveys, which severely limit PBHs as dark matter in the solar to satellite range, but there are diminishing results in regards to lower mass ranges. Gravitational waves signals and PBH evaporation from Hawking radiation also make for useful probes, but the former requires the next generation of experiments before making constraints beyond the solar mass range, and the later is severely limited above 10 −16 M . Other dynamical and accretion constraints exist for PBH of large masses. Care also has to be given, as all these constraints can carry different implications coming from differences between monochromatic and extended mass distributions, and their degree of clustering. Beyond all these issues, a window still exists for primordial black holes to be all of the dark matter between 10 −16 and 10 −11 M .

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Section: Black Hole Evaporationmentioning

confidence: 95%

Constraints on PBH as dark matter from observations: a review

Oncins¹

2022

Preprint

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“…Once again, tidal deformability measurement can in principle be used to break the degeneracy. Additionally, solar-mass BHs can form out of NS transmutation in certain particle-dark-matter scenarios [90][91][92][93]. In the upper half of this mass range (2 ≲ m i =M ⊙ ≲ 3), the component BHs in the binary may form out of previous NS-NS mergers and then pair again to produce a light binary [94].…”

Section: B Pbh Masses and Spinsmentioning

confidence: 99%

How to assess the primordial origin of single gravitational-wave events with mass, spin, eccentricity, and deformability measurements

et al. 2022

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A population of primordial black holes formed in the early Universe could contribute to at least a fraction of the black-hole merger events detectable by current and future gravitational-wave interferometers. With the ever-increasing number of detections, an important open problem is how to discriminate whether a given event is of primordial or astrophysical origin. We systematically present a comprehensive and interconnected list of discriminators that would allow us to rule out, or potentially claim, the primordial origin of a binary by measuring different parameters, including redshift, masses, spins, eccentricity, and tidal deformability. We estimate how accurately future detectors (such as the Einstein Telescope and LISA) could measure these quantities, and we quantify the constraining power of each discriminator for current interferometers. We apply this strategy to the GWTC-3 catalog of compact binary mergers. We show that current measurement uncertainties do not allow us to draw solid conclusions on the primordial origin of individual events, but this may become possible with next-generation ground-based detectors.

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“…Arguably, the most natural explanation for such a remarkable claim would be a population of subsolar PBHs which, given current microlensing constraints in that mass range [79], could account for as much as a few percent of the dark matter [12]. In certain particledark-matter scenarios solar-mass BHs can form out of neutron star transmutation [80,81], but lighter BHs can essentially be of primordial origin only (see, however, Ref. [82] for models in which subsolar BHs are born out of dark sector interactions).…”

Section: -3mentioning

confidence: 99%