Observational Evidence for Primordial Black Holes: A Positivist Perspective

TL;DR

This paper reviews observational evidence supporting primordial black holes as a significant component of dark matter and their potential role in early universe phenomena, offering a positivist perspective that unifies various astrophysical observations.

Contribution

It presents observational arguments for PBHs as dark matter candidates, emphasizing a positivist approach and proposing a unified explanation for multiple cosmic phenomena.

Findings

Microlensing suggests PBHs of around 1 solar mass could be dark matter.

PBHs could explain early galaxy formation and cosmic background correlations.

PBHs may seed supermassive black holes and account for LIGO/Virgo/KAGRA detections.

Abstract

We review numerous arguments for primordial black holes (PBHs) based on observational evidence from a variety of lensing, dynamical, accretion and gravitational-wave effects. This represents a shift from the usual emphasis on PBH constraints and provides what we term a positivist perspective. Microlensing observations of stars and quasars suggest that PBHs of around $1\,M_{\odot}$ could provide much of the dark matter in galactic halos, this being allowed by the Large Magellanic Cloud microlensing observations if the PBHs have an extended mass function. More generally, providing the mass and dark matter fraction of the PBHs is large enough, the associated Poisson fluctuations could generate the first bound objects at a much earlier epoch than in the standard cosmological scenario. This simultaneously explains the recent detection of high-redshift dwarf galaxies, puzzling correlations of the source-subtracted infrared and X-ray cosmic backgrounds, the size and the mass-to-light ratios of ultra-faint-dwarf galaxies, the dynamical heating of the Galactic disk, and the binary coalescences observed by LIGO/Virgo/KAGRA in a mass range not usually associated with stellar remnants. Even if PBHs provide only a small fraction of the dark matter, they could explain various other observational conundra, and sufficiently large ones could seed the supermassive black holes in galactic nuclei or even early galaxies themselves. We argue that PBHs would naturally have formed around the electroweak, quantum chromodynamics and electron-positron annihilation epochs, when the sound-speed inevitably dips. This leads to an extended PBH mass function with a number of distinct bumps, the most prominent one being at around $1\,M_{\odot}$, and this would allow PBHs to explain many of the observations in a unified way.