# Mapping the Galactic disk with the LAMOST and Gaia Red clump sample. II.   3D asymmetrical kinematics of mono-age populations in the disk between 6$-14$   \,kpc

**Authors:** H.-F. Wang, M. L\'opez-Corredoira, Y. Huang, J. L. Carlin, B.-Q. Chen,, C. Wang, J. Chang, H.-W. Zhang, M.-S. Xiang, H.-B. Yuan, W.-X. Sun, X.-Y. Li,, Y. Yang, L.-C. Deng

arXiv: 1905.11944 · 2020-01-08

## TL;DR

This study analyzes the 3D kinematics of Milky Way disk stars across different ages and distances, revealing asymmetrical motions and possible influences from various dynamical processes.

## Contribution

It provides a detailed analysis of asymmetrical kinematics in the Galactic disk using combined LAMOST and Gaia data, highlighting age-dependent features and potential perturbation sources.

## Key findings

- Radial motions up to 10 km/s vary with stellar age.
- North-south asymmetry correlates with early perturbations.
- Bending mode motions are sensitive over approximately 8 Gyr.

## Abstract

We perform analysis of the three-dimensional kinematics of Milky Way disk stars in mono-age populations. We focus on stars between Galactocentric distances of $R=6$ and 14 \,kpc, selected from the combined LAMOST DR4 red clump giant stars and Gaia DR2 proper motion catalogue. We confirm the 3D asymmetrical motions of recent works and provide time tagging of the Galactic outer disk asymmetrical motions near the anticenter direction out to Galactocentric distances of 14\,kpc. Radial Galactocentric motions reach values up to 10 km s$^{-1}$, depending on the age of the population, and present a north-south asymmetry in the region corresponding to density and velocity substructures that were sensitive to the perturbations in the early 6 \,Gyr. After that time, the disk stars in this asymmetrical structure have become kinematically hotter, and are thus not sensitive to perturbations, and we find the structure is a relatively younger population. With quantitative analysis, we find stars both above and below the plane at $R\gtrsim 9$ kpc that exhibit bending mode motions of which the sensitive duration is around 8 \,Gyr. We speculate that the in-plane asymmetries might not be mainly caused by a fast rotating bar, intrinsically elliptical outer disk, secular expansion of the disk, or streams. Spiral arm dynamics, out-of-equilibrium models, minor mergers or others are important contributors. Vertical motions might be dominated by bending and breathing modes induced by complicated inner or external perturbers. It is likely that many of these mechanisms are coupled together.

## Full text

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## Figures

19 figures with captions in the complete paper: https://tomesphere.com/paper/1905.11944/full.md

## References

118 references — full list in the complete paper: https://tomesphere.com/paper/1905.11944/full.md

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Source: https://tomesphere.com/paper/1905.11944