Evolution of stellar bars in spinning dark matter haloes and stellar bulges

Evolution of stellar bars in spinning dark matter haloes and stellar bulges

ABSTRACT We use numerical simulations to follow evolution of barred galaxies in a suite of models with progressively more massive stellar bulges, with bulge-to-total (disc+bulge) mass ratios of B/T ∼ 0–0.25, embedded in dark matter (DM) haloes with spin $\lambda\sim 0\!-\!0.09$. We focus on models w...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society Vol. 527; no. 4; pp. 11026 - 11042
Main Authors: Li, Xingchen, Shlosman, Isaac, Pfenniger, Daniel, Heller, Clayton
Format: Journal Article
Language:English
Published: Oxford University Press 01-02-2024
Subjects:
galaxies: formation
galaxies: kinematics and dynamics
methods: numerical
galaxies: bar
galaxies: evolution
galaxies: bulges
Online Access:Get full text
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Summary:ABSTRACT We use numerical simulations to follow evolution of barred galaxies in a suite of models with progressively more massive stellar bulges, with bulge-to-total (disc+bulge) mass ratios of B/T ∼ 0–0.25, embedded in dark matter (DM) haloes with spin $\lambda\sim 0\!-\!0.09$. We focus on models with a sequence of initial rotational support for bulges, and analyse their spinup and spindown. We find that (1) the presence of a bulge affects evolution of bars, i.e. the time-scale of bar instability, bar pattern speed, and its decay, and the vertical buckling instability. Bar strength is nearly independent of B/T in haloes with spin $\lambda=0$, and is suppressed by a factor ∼2 for haloes with $\lambda=0.09$; (2) The main effect of the bulge is the destruction of the harmonic core which affects the buckling; (3) The bulge plays a minor role in the exchange of angular momentum between the barred disc and the DM halo, during its spinup and spindown; (4) Buckling process triggers different response above/below the disc mid-plane, which anticorrelates with the bulge mass; (5) In spinning haloes, the buckling process has a prolonged amplitude tail, extending by few Gyr, as verified by measuring distortions in the Laplace plane; (6) Furthermore, as verified by orbital spectral analysis, the bulge gains its spin from the bar mainly via the inner Lindblad resonance, while losing it via a number of resonances lying between the outer and inner Lindblad resonance. The corollary is that we do not expect to find non-rotating bulges in barred galaxies.
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/stad3907