A vast population of wandering and merging IMBHs at cosmic noon

TL;DR

This paper uses cosmological simulations to show that many wandering intermediate mass black holes exist at cosmic noon, producing detectable gravitational waves and offering insights into black hole seed formation.

Contribution

It demonstrates the prevalence of wandering IMBHs at high redshift and predicts their gravitational wave signatures, providing new constraints on black hole seed models.

Findings

Hundreds of wandering IMBHs per galaxy at z~2

Nearly a million GW events from seed IMBH mergers between z=2-3

Detectable GW signals by LISA and future space interferometers

Abstract

Massive black holes in the centers of galaxies today must have grown by several orders of magnitude from seed black holes formed at early times. Detecting a population of intermediate mass black holes (IMBHs) can provide constraints on these elusive BH seeds. Here we use the large volume, cosmological hydrodynamical simulation Astrid, which includes IMBH seeds and dynamical friction to investigate the population of IMBH seeds. Dynamical friction is largely inefficient at sinking and merging seed IMBHs at high-z. This leads to an extensive population (several hundred per galaxy) of wandering IMBHs in large halos at z~2. A small fraction of these IMBHs are detectable as HLXs, Hyper Luminous X-ray sources. Importantly, at z ~ 2, IMBHs mergers produce the peak of GW events. We find close to a million GW events in Astrid between z=2-3 involving seed IMBH mergers. These GW events (almost all detectable by LISA) at cosmic noon should provide strong constraints on IMBH seed models and their formation mechanisms. At the center of massive galaxies, where the number of IMBHs can be as high as 10-100, SMBH-IMBH pairs can form. These Intermediate mass ratio inspirals (IMRIs) and extreme mass ratio inspirals (EMRIs), will require the next generation of milli-muHz space-based GW interferometers to be detected. Large populations of IMBHs around massive black holes will probe their environments and MBH causal structure.