Gravitational wave background from Population III binary black holes consistent with cosmic reionization

TL;DR

This paper explores how Population III stars could produce a gravitational wave background detectable by future observatories, linking it to cosmic reionization and high-mass black hole formation.

Contribution

It quantifies the relationship between the gravitational wave background amplitude and cosmic reionization, proposing that PopIII stars can produce a detectable GWB with distinctive spectral features.

Findings

PopIII stars produce a GWB detectable if τ_e > 0.07

The GWB spectral index becomes flatter at high frequencies

Detection of spectral flattening indicates high-mass, high-redshift BBH population

Abstract

The recent discovery of the gravitational wave source GW150914 has revealed a coalescing binary black hole (BBH) with masses of $\sim 30~M_\odot$. Previous proposals for the origin of such a massive binary include Population III (PopIII) stars. PopIII stars are efficient producers of BBHs and of a gravitational wave background (GWB) in the $10-100$ Hz band, and also of ionizing radiation in the early Universe. We quantify the relation between the amplitude of the GWB ($\Omega_{\rm gw}$) and the electron scattering optical depth ($\tau_{\rm e}$), produced by PopIII stars, assuming that $f_{\rm esc}\approx 10\%$ of their ionizing radiation escapes into the intergalactic medium. We find that PopIII stars would produce a GWB that is detectable by the future O5 LIGO/Virgo if $\tau_{\rm e} \gtrsim 0.07$, consistent with the recent Planck measurement of $\tau_e=0.055 \pm 0.09$. Moreover, the spectral index of the background from PopIII BBHs becomes as small as ${\rm d}\ln \Omega_{\rm gw}/{\rm d}\ln f\lesssim 0.3$ at $f \gtrsim 30$ Hz, which is significantly flatter than the value $\sim 2/3$ generically produced by lower-redshift and less-massive BBHs. A detection of the unique flattening at such low frequencies by the O5 LIGO/Virgo will indicate the existence of a high-chirp mass, high-redshift BBH population, which is consistent with the PopIII origin. A precise characterization of the spectral shape near $30-50$ Hz by the Einstein Telescope could also constrain the PopIII initial mass function and star formation rate.