The velocity field of our Milky Way outer stellar halo based on DESI DR2

Songting Li; Wenting Wang; Sergey E. Koposov; Jo\~ao A. S. Amarante; Alis J. Deason; Monica Valluri; Ting S. Li; Amanda Bystr\"om; Mika Lambert; Tian Qiu; Joan Najita; Gustavo E. Medina; Oleg Y. Gnedin; Leandro Beraldo e Silva; Richard A. N. Brooks; Raymond G. Carlberg; Namitha Kizhuprakkat; Jiaxin Han; Jessica Nicole Aguilar; Steven Ahlen; Davide Bianchi; David Brooks; Todd Claybaugh; Andrei Cuceu; Axel de la Macorra; Peter Doel; Andreu Font-Ribera; Jaime E. Forero-Romero; Simone Ferraro; Enrique Gazta\~naga; Satya Gontcho A Gontcho; Gaston Gutierrez; Julien Guy; Klaus Honscheid; Dick Joyce; Anthony Kremin; Martin Landriau; Laurent Le Guillou; Aaron Meisner; Ramon Miquel; John Moustakas; Seshadri Nadathur; Will Percival; Francisco Prada; Ignasi P\'erez-R\`afols; Graziano Rossi; Eusebio Sanchez; David Schlegel; Michael Schubnell; Ray Sharples; Joseph Harry Silber; David Sprayberry; Gregory Tarl\'e; Benjamin Alan Weaver; Rongpu Zhou; Hu Zou

arXiv:2604.01628·astro-ph.GA·April 3, 2026

The velocity field of our Milky Way outer stellar halo based on DESI DR2

Songting Li, Wenting Wang, Sergey E. Koposov, Jo\~ao A. S. Amarante, Alis J. Deason, Monica Valluri, Ting S. Li, Amanda Bystr\"om, Mika Lambert, Tian Qiu, Joan Najita, Gustavo E. Medina, Oleg Y. Gnedin, Leandro Beraldo e Silva, Richard A. N. Brooks, Raymond G. Carlberg

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TL;DR

This study analyzes the Milky Way's outer stellar halo using DESI DR2 data, revealing distinct metal-rich and metal-poor components, their kinematics, and the influence of the Large Magellanic Cloud on halo motions.

Contribution

It provides a detailed, distance-resolved characterization of the MW's stellar halo, including its decomposition, kinematic properties, and perturbations from the LMC.

Findings

01

Metal-rich stars are mainly from Gaia-Sausage/Enceladus debris.

02

Outer halo shows contraction and reflex motions influenced by the LMC.

03

Distinct kinematic behaviors for metal-rich and metal-poor populations.

Abstract

Using 64,000 halo K giants from Dark Energy Spectroscopic Instrument (DESI) second Data Release (DR2), we decompose the Milky Way (MW) stellar halo between 3 and 160 kpc into metal-rich (MR) and metal-poor (MP) components via a Gaussian mixture model (GMM). The two populations are nearly equal in number but chemically and kinematically distinct: MR stars occupy highly radial orbits with velocity anisotropy of beta ~0.94 and metallicity dispersion sigma([Fe/H]) ~0.17 dex, without obvious dependence on distance, and are mainly contributed by Gaia-Sausage/Enceladus (GSE) debris. MR component dominates the inner 30 kpc and re-emerges beyond 50 kpc, implying GSE debris can extend to ~70-80 kpc. MP stars exhibit a weaker radial bias of beta ~0.46, decreasing to -0.5 beyond 80 kpc, and with a larger metallicity dispersion of sigma([Fe/H]) ~0.46 dex, showing signatures of multiple minor…

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