Ring Formation from an Oscillating Black Hole

TL;DR

This paper investigates how oscillating black holes after mergers can induce resonant effects in galaxy disks, potentially triggering star formation and ring structures through shocks and wakes.

Contribution

It introduces a model analyzing black hole oscillations and their resonant interactions with galaxy disks, revealing mechanisms for ring and star formation.

Findings

Resonant radii induce strong radial flows and density enhancements.

Black hole wakes can trigger star formation and form ring-like structures.

Oscillations can cause significant disk perturbations at specific radii.

Abstract

Massive black hole (BH) mergers can result in the merger remnant receiving a "kick", of order 200 km s$^{-1}$ or more, which will cause the remnant to oscillate about the galaxy centre. Here we analyze the case where the BH oscillates through the galaxy centre perpendicular or parallel to the plane of the galaxy for a model galaxy consisting of an exponential disk, a Plummer model bulge, and an isothermal dark matter halo. For the perpendicular motion we find that there is a strong resonant forcing of the disk radial motion near but somewhat less than the "resonant radii" $r_R$ where the BH oscillation frequency is equal one-half, one-fourth, (1/6, etc.) of the radial epicyclic frequency in the plane of the disk. Near the resonant radii there can be a strong enhancement of the radial flow and disk density which can lead to shock formation. In turn the shock may trigger the formation of a ring of stars near $r_R$. As an example, for a BH mass of $10^8 M_\odot$ and a kick velocity of 150 km s$^{-1}$, we find that the resonant radii lie between 0.2 and 1 kpc. For BH motion parallel to the plane of the galaxy we find that the BH leaves behind it a supersonic wake where star formation may be triggered. The shape of the wake is calculated as well as the slow-down time of the BH. The differential rotation of the disk stretches the wake into ring-like segments.