The nature of the Milky Way's stellar halo revealed by the three integrals of motion

Abstract

We developed a new selection method of halo stars in the phase-space distribution defined by the three integrals of motion in an axisymmetric Galactic potential, (E, Lz, I3), where I3 is the third integral of motion. The method is used to explore the general chemo-dynamical structure of the halo based on stellar samples from SDSS-SEGUE DR7 and DR16-APOGEE, matched with Gaia-DR2. We found, (a) halo stars can be separated from disk stars by selecting over (1) 0 < Lz < 1500 , (2I3)1/2 > 1000 (orbital angle θ orb > 15-20 deg), and E < -1.5 × 105 km2 s-2, and (2) Lz < 0 . These selection criteria are free from kinematical biases introduced by the simple high-velocity cuts adopted in recent literature; (b) the averaged, or coarse-grained, halo phased-space distribution shows a monotonic exponential decrease with increasing E and I3 like the Michie-Bodenheimer models; (c) the inner stellar halo described in carollo2007,carollo2010 is found to comprise a combination of Gaia Enceladus debris (GE; helmi2018), lowest-E stars (likely in-situ stars), as well as metal-poor prograde stars missed by the high velocity cuts selection; (d) the very metal poor outer halo, ([Fe/H] < -2.2), exhibits both retrograde and prograde rotation, with an asymmetric Lz distribution towards high retrograde motions, and larger θ orb than those possessed by the GE dominated inner halo; (e) the Sgr dSph galaxy could induce a long-range dynamical effect on local halo stars. Implication for the formation of the stellar halo are also discussed.