Bar-like galaxies in IllustrisTNG

TL;DR

This study investigates prolate, bar-like galaxies in the IllustrisTNG100 simulation, classifying their origins and evolution, and finds their properties are consistent despite diverse formation histories, with low gas fractions at bar formation.

Contribution

It introduces a new classification of prolate, bar-like galaxies based on their formation mechanisms and evolutionary paths within a cosmological simulation.

Findings

Bars are similar in strength, length, and formation time across classes.

Low gas fraction (<0.4) at bar formation supports previous thresholds from controlled simulations.

Different evolutionary histories lead to similar bar properties.

Abstract

We study a sample of bar-like galaxies in the Illustris TNG100 simulation, in which almost the whole stellar component is in the form of a prolate spheroid. The sample is different from the late-type barred galaxies studied before. In addition to the requirement of a high enough stellar mass and resolution, the 277 galaxies were selected based on the single condition of a low enough ratio of the intermediate to long axis of the stellar component. We followed the mass and shape evolution of the galaxies as well as their interactions with other objects and divided them into three classes based on the origin of the bar and the subsequent history. In galaxies of class A (comprising 28% of the sample), the bar was induced by an interaction with a larger object, most often a cluster or group central galaxy, and the galaxies were heavily stripped of dark matter and gas. In classes B and C (27% and 45% of the sample, respectively) the bars were induced by a merger or a passing satellite, or they were formed by disk instability. Class B galaxies were then partially stripped of mass, while those of class C evolved without strong interactions, thus retaining their dark matter and gas in the outskirts. We illustrate the properties of the different classes with three representative examples of individual galaxies. In spite of the different evolutionary histories, the bars are remarkably similar in strength, length, and formation times. The gas fraction in the baryonic component within two stellar half-mass radii at the time of bar formation is always below 0.4 and usually very low, which confirms in the cosmological context the validity of this threshold, which has previously been identified in controlled simulations. Observational counterparts of these objects can be found among early-type fast rotators, S0 galaxies, or red spirals with bars.