Gravitational waves from a universe filled with primordial black holes

TL;DR

This paper derives new constraints on ultra-light primordial black holes by analyzing the gravitational waves produced through second-order effects, showing that certain abundance scenarios are excluded to avoid backreaction issues.

Contribution

It provides the first constraints on ultra-light primordial black holes based on induced gravitational wave considerations and their impact on early universe cosmology.

Findings

Primordial black holes with certain abundances are excluded to prevent backreaction.

Scenarios where black holes dominate immediately after formation are ruled out.

Constraints depend on black hole mass and initial abundance.

Abstract

Ultra-light primordial black holes, with masses $m_\mathrm{PBH}<10^9\mathrm{g}$, evaporate before big-bang nucleosynthesis and can therefore not be directly constrained. They can however be so abundant that they dominate the universe content for a transient period (before reheating the universe via Hawking evaporation). If this happens, they support large cosmological fluctuations at small scales, which in turn induce the production of gravitational waves through second-order effects. Contrary to the primordial black holes, those gravitational waves survive after evaporation, and can therefore be used to constrain such scenarios. In this work, we show that for induced gravitational waves not to lead to a backreaction problem, the relative abundance of black holes at formation, denoted $ \Omega_\mathrm{PBH,f} $, should be such that $ \Omega_\mathrm{PBH,f} <10^{-4}(m_\mathrm{PBH}/10^9\mathrm{g})^{-1/4}$. In particular, scenarios where primordial black holes dominate right upon their formation time are all excluded (given that $m_\mathrm{PBH}>10\, \mathrm{g}$ for inflation to proceed at $\rho^{1/4}<10^{16}\mathrm{GeV}$). This sets the first constraints on ultra-light primordial black holes.