Implications for primordial black holes from cosmological constraints on scalar-induced gravitational wave

Abstract

Sufficiently large scalar perturbations in the early Universe can create over-dense regions that collapse into primordial black holes (PBH). This process is accompanied by the emission of scalar-induced gravitational waves (SIGW) that behave like an extra radiation component, thus contributing to the relativistic degrees of freedom (Neff). We show that the cosmological constraints on Neff can be used to pose stringent limits on PBHs created from this particular scenario as well as the relevant small-scale curvature perturbation (PR(k)). We show that the combination of cosmic microwave background (CMB), baryon acoustic oscillation (BAO) and Big-Bang nucleosynthesis (BBN) datasets can exclude supermassive PBHs with peak mass M ∈ [5 × 105, 5 × 1010]\, M as the major component of dark matter, while the detailed constraints depend on the shape of the PBHs mass distribution. The future CMB mission like CMB-S4 can broaden this constraint window to a much larger range M ∈ [8 × 10-5, 5 × 1010]\, M, covering sub-stellar masses. These limits on PBH correspond to a tightened constraint on PR on scales of k ∈ [10, 1022]\ Mpc-1, much smaller than those probed by direct CMB and large-scale structure power spectra.