The kinematic properties of Milky Way stellar halo populations

In the Gaia era, stellar kinematics are extensively used to study Galactic halo stellar populations, to search for halo structures, and to characterize the interface between the halo and hot disc populations. We use distribution function-based models of modern data sets with 6D phase space data to qualitatively describe a variety of kinematic spaces commonly used in the study of the Galactic halo. Furthermore, we quantitatively assess how well each kinematic space can separate radially anisotropic from isotropic halo populations. We find that scaled action space (the 'action diamond') is superior to other commonly used kinematic spaces at this task. We present a new, easy to implement selection criterion for members of the radially anisotropic Gaia-Enceladus merger remnant. Assuming a 1:1 ratio of Gaia-Enceladus stars to more isotropic halo, we find our selection achieves a sample purity of 86 per cent in our models with respect to contamination from the more isotropic halo. We compare this criterion to literature criteria, finding that it produces the highest purity in the resulting samples, at the expense of a modest reduction in completeness. We also show that selection biases that underlie nearly all contemporary spectroscopic data sets can noticeably impact the E-L-z distribution of samples in a manner that may be confused for real substructure. We conclude by providing recommendations for how authors should use stellar kinematics in the future to study the Galactic stellar halo.

Automated summary

In the Gaia era, stellar kinematics are extensively used to study Galactic halo stellar populations and search for halo structures. This study evaluates different kinematic spaces in separating radially anisotropic from isotropic halo populations, finding the scaled action space to be superior. A new selection criterion is proposed for the radially anisotropic Gaia-Enceladus merger remnant with a high sample purity of 86%. The study also highlights the impact of selection biases on the distribution of samples and provides recommendations for future use of stellar kinematics in studying the Galactic stellar halo.