Stellar bars form dark matter counterparts in TNG50

TL;DR

This study demonstrates that dark matter bars, which shadow stellar bars, are common in cosmological simulations of barred galaxies, and introduces new methods for measuring their pattern speeds and dynamics over time.

Contribution

The paper provides the first evidence of dark matter bars in cosmological simulations and develops novel techniques to measure their pattern speeds and evolution.

Findings

DM bars are common in barred galaxies in TNG50

DM bars are shorter and weaker than stellar bars

Bar pattern speeds evolve over time, influenced by mergers and external torques

Abstract

Dark matter (DM) bars that shadow stellar bars have been previously shown to form in idealized simulations of isolated disk galaxies. Here, we show that DM bars commonly occur in barred disk galaxies in the TNG50 cosmological simulation suite, but do not appear in unbarred disk galaxies. Consistent with isolated simulations, DM bars are typically shorter than their stellar counterparts and are $75\%$ weaker as measured by the Fourier $A_2$ moment. DM bars dominate the shape of the inner halo potential and are easily identified in the time series of quadrupolar coefficients. We present two novel methods for measuring the bar pattern speed using these coefficients, and use them to make a measurement of the pattern speed and rotation axis orientation for one sample galaxy located in one of the high-time resolution subboxes of TNG50. The stellar and dark bars in this galaxy remain co-aligned throughout the last 8 Gyr and have identical pattern speeds throughout. Both the pattern speed and rotation axis orientation of the bars evolve considerably over the last 8 Gyr, consistent with torques on the bars due to dynamical friction and gas accretion. While the bar pattern speed generally decreases over the time course, it is seen to increase after mergers. Rather than remaining static in time, the rotation axis displays both precession and nutation possibly caused by torques outside the plane of rotation. We find that the shape of the stellar and DM mass distributions are tightly correlated with the bar pattern speed.