Press-Schechter Formalism and The PBH Mass Distributions

Abstract

Primordial black holes (PBHs) can form during radiation domination from rare primordial perturbations that re-enter the Hubble radius and undergo gravitational collapse. We derive PBH mass distributions using Press--Schechter theory completed by the excursion-set first-crossing construction. We define the smoothed density contrast δR and its variance S(R)=σ2(R), and connect S to the primordial curvature spectrum P R(k) through the radiation-era transfer. For Gaussian statistics and a constant collapse threshold δc, the formation fraction is an erfc tail with a controlled rare-event asymptotic. For a sharp-k filter, δ(S) is Markovian; solving the diffusion equation with an absorbing barrier yields the first-crossing density f(S)=δc2πS-3/2\!(-δc2/(2S)). This gives a differential formation fraction dβ/d M=f(S)\,|dS/d M| and a mass-conserving formation-era mass function dnPBH/dM. We then map to the present-day PBH dark-matter fraction per logarithmic mass, fPBH(M), using horizon-entry scaling M k-2 and radiation-era redshifting.