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Spins of primordial black holes formed in the matter-dominated phase of the Universe

Canonical reference. 80% of citing Pith papers cite this work as background.

12 Pith papers citing it
Background 80% of classified citations
abstract

Angular momentum plays very important roles in the formation of PBHs in the matter-dominated phase if it lasts sufficiently long. In fact, most collapsing masses are bounced back due to centrifugal force, since angular momentum significantly grows before collapse. As a consequence, most of the formed PBHs are rapidly rotating near the extreme value $a_{*}=1$, where $a_{*}$ is the nondimensional Kerr parameter at their formation. The smaller the density fluctuation $\sigma_{H}$ at horizon entry is, the stronger the tendency towards the extreme rotation. Combining the effect of angular momentum with that of anisotropy, we estimate the black hole production rate. We find that the production rate suffers from suppression dominantly due to angular momentum for a smaller value of $\sigma_{H}$, while due to anisotrpopy for a larger value of $\sigma_{H}$. We argue that matter domination significantly enhances the production of PBHs despite the suppression. If the matter-dominated phase does not last so long, the effect of the finite duration significantly suppresses PBH formation and weakens the tendency towards large spins. (abridged)

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representative citing papers

PBHs and GWs from Scaling Monopoles

hep-ph · 2026-06-30 · unverdicted · novelty 6.0

Scaling monopoles generate PBHs via stochastic overdensities and GWs with correlated spectra, potentially with magnetically charged PBHs as a signature if the scaling ends via gauge boson mass.

Constraints on Primordial Black Holes

astro-ph.CO · 2020-02-27 · accept · novelty 4.0

Updated compilation shows PBHs are tightly constrained across 55 orders of magnitude in mass, ruling out dominant dark matter contributions except in narrow windows, with many limits carrying observational uncertainties.

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Showing 7 of 7 citing papers after filters.

  • Are Primordial Black Holes a Natural Dark Matter Candidate? hep-ph · 2026-06-11 · unverdicted · none · ref 76 · internal anchor

    PBH dark matter spans all naturalness tiers, with some mechanisms as natural as WIMPs or freeze-in particles, determined by abundance map structure rather than candidate type.

  • Gravitational Waves from Black Hole Reheating: The Scalar-Induced Component hep-ph · 2026-05-20 · unverdicted · none · ref 120 · internal anchor

    Accounting for the minimal mass spread of primordial black holes from gravitational collapse suppresses the Poltergeist GW background to the level of generic scalar-induced signals and reopens ultra-light PBH parameter space.

  • PBHs and GWs from Scaling Monopoles hep-ph · 2026-06-30 · unverdicted · none · ref 57 · internal anchor

    Scaling monopoles generate PBHs via stochastic overdensities and GWs with correlated spectra, potentially with magnetically charged PBHs as a signature if the scaling ends via gauge boson mass.

  • Asteroid-mass Primordial Black Holes as Dark Matter from Supersymmetry hep-ph · 2026-04-28 · unverdicted · none · ref 64

    Supersymmetry with heavy particles above ~10^5 GeV enhances asteroid-mass PBH production via transient equation-of-state softening, allowing them to comprise all dark matter unlike in the Standard Model.

  • String Axiverse Enhancement of Superradiant Dark Matter Production hep-ph · 2026-06-18 · unverdicted · none · ref 18 · internal anchor

    O(100-10^5) string axions enhance PBH superradiance efficiency via increased spin, expanding viable mass-spin regions for micro-boson star dark matter while too many axions cause overly rapid evaporation.

  • Reviving primordial black hole formation in slow first-order phase transitions hep-ph · 2026-05-11 · unverdicted · none · ref 44 · 2 links · internal anchor

    Slow reheating after a supercooled first-order phase transition allows an early matter-dominated era in which small curvature perturbations grow sufficiently to form primordial black holes.

  • Dark matter production from evaporation of regular primordial black holes hep-ph · 2025-10-10 · unverdicted · none · ref 94 · internal anchor

    Regular primordial black holes can evaporate completely like singular ones and yield the observed dark matter density under modified cosmological constraints.