The Role of Baryonic and Dark Matter in Bar Kinematics

TL;DR

This study provides observational evidence that bars in galaxies slow down over time, correlating with galaxy mass and dark matter profile characteristics, supporting simulation predictions.

Contribution

It combines kinematic measurements and mass estimates to empirically demonstrate the relationship between bar pattern speed and galaxy mass, including dark matter effects.

Findings

Significant anti-correlation between bar pattern speed and galaxy mass.

Bars in more massive galaxies tend to have lower pattern speeds.

Lower pattern speed bars are associated with more extended dark matter profiles.

Abstract

Simulations predict that bars in galaxies should slow down over time. This is often attributed to the exchange of angular momentum between the bar and other regions of the galaxy, such as the outer disc and dark matter halo, which implies that galaxies with a more massive halo or disc should be able to slow down the bar more efficiently. However, observational evidence for this process has been limited. In this work, we provide observational support for the slowing down of bars as predicted by simulations. We combine bar kinematics measurements obtained with the Tremaine-Weinberg method and host galaxy mass estimates derived from Jeans anisotropic models for a sample of 30 galaxies from the MaNGA survey. We find a statistically significant anti-correlation (>4sigma) between the bar pattern speed and both the stellar and total dynamical mass, which suggests that the slowest bars reside in the most massive galaxies. However, while the slope of the best-fit line between the pattern speed and dark matter mass is negative, it is not statistically significant (2.43sigma). We also find that bars with lower pattern speeds have more extended NFW dark matter profiles with lower central densities. Additionally, we find statistically significant correlations (>3sigma) between the corotation radius and the stellar mass, dark matter mass, and total dynamical mass. Finally, we find no significant correlations that involve the dark matter fraction or R, likely due to the inherent challenges associated with measuring these specific parameters accurately.