Massive Black Hole Mergers with Orbital Information: Predictions from the ASTRID Simulation
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× 104M/h and 3× 105M/h and a sub-grid dynamical friction (DF) model to follow the MBH dynamics down to 1.5\;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 200\,pc, we find that the in-simulation DF on large scales accounts for more than half of the total orbital decay time ( 500\,Myrs) due to DF. The binary hardening time is an order of magnitude longer than the DF time, especially for the seed-mass binaries (MBH<2Mseed). As a result, only 20\% 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 >109\,M. 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 7 higher than the prediction using the circular orbit assumption. The LISA events are expected at a similar rate, and comprise 60\% seed-seed mergers, 30\% involving only one seed-mass MBH, and 10\% mergers of non-seed MBHs.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.