Massive Black Hole Mergers with Orbital Information: Predictions from the ASTRID Simulation

TL;DR

This study uses the Astrid simulation to predict massive black hole merger rates, orbital eccentricities, and gravitational wave signals, highlighting the importance of initial eccentricity and dynamical processes in merger predictions.

Contribution

It introduces new predictions of black hole merger rates and orbital properties based on the Astrid simulation, emphasizing the impact of initial eccentricities and dynamical friction on merger timescales.

Findings

Most MBH pairs have eccentricities above 0.7 before merger.

Only about 20% of seed MBH pairs merge at z>3 after considering dynamical effects.

Predicted merger rate of 0.3-0.7 per year at z>3, higher than circular orbit estimates.

Abstract

We examine massive black hole (MBH) mergers and their associated gravitational wave signals from the large-volume cosmological simulation Astrid. Astrid includes galaxy formation and black hole models recently updated with a MBH seed population between $3\times 10^4M_{\odot}/h$ and $3\times 10^5M_{\odot}/h$ and a sub-grid dynamical friction (DF) model to follow the MBH dynamics down to $1.5\;\text{ckpc}/h$. We calculate initial eccentricities of MBH orbits directly from the simulation at kpc-scales, and find orbital eccentricities above $0.7$ for most MBH pairs before the numerical merger. After approximating unresolved evolution on scales below ${\sim 200\,\text{pc}}$, we find that the in-simulation DF on large scales accounts for more than half of the total orbital decay time ($\sim 500\,\text{Myrs}$) due to DF. The binary hardening time is an order of magnitude longer than the DF time, especially for the seed-mass binaries ($M_\text{BH}<2M_\text{seed}$). As a result, only $\lesssim20\%$ of seed MBH pairs merge at $z>3$ after considering both unresolved DF evolution and binary hardening. These $z>3$ seed-mass mergers are hosted in a biased population of galaxies with the highest stellar masses of $>10^9\,M_\odot$. With the higher initial eccentricity prediction from Astrid, we estimate an expected merger rate of $0.3-0.7$ per year from the $z>3$ MBH population. This is a factor of $\sim 7$ higher than the prediction using the circular orbit assumption. The LISA events are expected at a similar rate, and comprise $\gtrsim 60\%$ seed-seed mergers, $\sim 30\%$ involving only one seed-mass MBH, and $\sim 10\%$ mergers of non-seed MBHs.