MAGICS II. Seed black holes stripped of their surrounding stars do not sink

TL;DR

This study uses high-resolution simulations to investigate the dynamics of seed black holes in galaxy mergers, revealing that stripped stars hinder black hole sinking and binary formation, emphasizing the importance of resolving stellar environments.

Contribution

The paper introduces the MAGICS-II simulation suite with enhanced resolution and models to accurately track seed black hole dynamics down to 0.1 pc, highlighting the role of stellar stripping in black hole sinking.

Findings

Most MBH seeds stall at >200 pc separation due to stellar stripping.

Only 1 of 6 systems forms a bound MBH binary.

Bound stars significantly influence MBH sinking and binary formation.

Abstract

MBH seed mergers are expected to be among the loudest sources of gravitational waves detected by the Laser Interferometer Space Antenna (LISA), providing a unique window into the birth and early growth of SMBH. We present the MAGICS-II simulation suite, consisting of 6 galaxy mergers that result in MBH seeds mergers identified in the cosmological simulation ASTRID. With the enhanced resolution (mass resolution: 500 $\mathrm{M}_{\odot}$; softening length: $5$ pc), improved subgrid models for the MBH dynamics and accretion, and the accurate regularized gravity integrator included in KETJU, we trace MBH seeds dynamics down to 0.1 pc. After evolving all the systems for $\approx$ 1.2 Gyr in three stages (MAGICS-2000, MAGICS-500, and MAGICS-K), we find in 4 of the 6 systems the MBHs stall at separations $ \Delta r \gtrsim 200$ pc. Only in 2 systems, the MBHs manage to sink further, and only in one of them a bound binary forms. In the sinking systems, the MBH retains a population of bound stars. The final separation between the MBH is related to the surrounding unstripped stellar (and/or dark matter) mass: if more than 90\% of the surrounding stellar system is stripped away, the MBHs stall. Besides the unstripped stars from the original host galaxy, we find that newly formed stars bound to the MBH significantly contribute to its sinking. Resolving the stellar system around MBH seeds, and its induced tidal interactions and dynamical friction is key for accurately capturing MBH dynamics. For this, high resolution simulations are required. In a companion paper (MAGICS-III), we resimulate the central regions of these systems with increased resolution to model directly the effects of actual star clusters around MBHs.