Galaxy fly-bys sustain bar-halo friction and bar slowdown in disk galaxies

TL;DR

This study uses self-consistent N-body simulations to show that galaxy fly-bys can sustain bar slowdown in disk galaxies by exciting long-lived halo fluctuations, despite not triggering long-lived tidal bars.

Contribution

It reveals that galaxy fly-bys can maintain bar-halo dynamical friction and slow bars, highlighting a new mechanism for bar evolution influenced by minor interactions.

Findings

Fly-bys do not trigger long-lived tidal bars but strengthen existing bars.

Perturbed models develop slower, stronger bars compared to isolated models.

Halo fluctuations from fly-bys sustain phase-space gradients, prolonging bar slowdown.

Abstract

Bars in disk galaxies slow down as they transfer their angular momentum to their dark matter halo via dynamical friction from near-resonant orbits. This bar-halo dynamical friction can become ineffective once phase mixing erases the phase-space gradient around the main resonances. We present fully self-consistent $N$-body simulations of a Milky Way-like disk galaxy with a single dwarf-galaxy fly-by in prograde and retrograde orbits before, during, and after bar formation. In our models, the fly-bys do not trigger a long-lived tidal bar; the bar forms on essentially the same time as in the isolated model. After the encounter, however, all perturbed models develop bars that are stronger and slower than in the isolated one. The final pattern speed depends little on the encounter time, but it does depend on the encounter direction relative to the disk rotation: prograde encounters slow the bar more than retrograde ones. The angular-momentum evolution shows that the disk loses its angular momentum and the halo gains it, consistent with bar-halo friction. By probing the particle distribution of the halo in angle-action space, we demonstrate that the isolated bar enters a metastable, saturated state with a flattened distribution in the phase space around the bar's corotation resonance, whereas a dwarf passage excites long-lived fluctuations in the halo that restore the phase-space gradients near the corotation and thereby sustain the bar-halo friction. This mechanism explains the continued slowdown and growth of bars after fly-bys. It may be relevant to the Milky Way, whose bar formed near the epoch of a major ancient accretion event, suggesting that an early encounter could have influenced the subsequent secular evolution of the bar.