An advanced approach for definition of the "Milky Way galaxies-analogues"

TL;DR

This paper proposes an enhanced multi-parameter approach to identify Milky Way analogues by incorporating additional features like 3D kinematics and chemical properties, aiming for more accurate galaxy matching.

Contribution

It introduces a comprehensive method that enlarges the set of features used to find Milky Way analogues, including new parameters like star kinematics and chemical composition.

Findings

Expanded feature set improves MWA identification accuracy

Method enables better characterization of Milky Way-like galaxies

Potential to define necessary and sufficient conditions for MWA detection

Abstract

Our Galaxy - the Milky Way - has certain features of the structure and evolution. The morphological, photometric, kinematic, and chemodynamical properties are usually considered in the search for the Milky Way galaxies-analogues (MWAs). The discovery of MWA galaxies with a larger number of simultaneous selection parameters and more stringent constraints on a given parameter yields a sample of MWA galaxies with properties closer to the true properties of the Milky Way. So, in general, such MW parameters as the morphological type, luminosity, color indices, structural parameters (size, bar, bulge, thin and thick disks, inner ring, halo), bulge to total ratio, stellar mass, star formation rate, metallicity, and rotation velocity were used in various combinations for comparison with other galaxies. However, the offset of some MW features in the multiparameter space of MWAs features should be significant. The paper aims to give a brief overview of the problematics and to present our approach for studying Milky Way and MWAs matching characteristics (this project is supported by the National Research Fund of Ukraine). We propose to enlarge as much as possible the number of Milky Way features and compile various samples of MWAs in our comoving cosmological volume for their further optimization. Such features can include 3Dkinematics of star's movement in certain regions, low oxygen content on the periphery, low nuclear activity, and the lack of significant merging over the past 10 Gyrs (isolation criterion). This approach will make it possible to widely formulate the necessary and sufficient conditions for the detection of MWA galaxies as well as to reveal other MW multiwavelength features.