A Two Micron All-Sky Survey View of the Sagittarius Dwarf Galaxy. IV. Modeling the Sagittarius Tidal Tails

A Two Micron All-Sky Survey View of the Sagittarius Dwarf Galaxy. IV. Modeling the Sagittarius Tidal Tails

M giants recovered from the Two Micron All-Sky Survey have recently been used to map the position and velocity distributions of tidal debris from the Sagittarius (Sgr) dwarf spheroidal galaxy around the entire Galaxy. We compare this data set to both test-particle orbits and N-body simulations of sa...

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Bibliographic Details
Published in:The Astrophysical journal Vol. 619; no. 2; pp. 807 - 823
Main Authors: Law, David R, Johnston, Kathryn V, Majewski, Steven R
Format: Journal Article
Language:English
Published: Chicago, IL IOP Publishing 01-02-2005
University of Chicago Press
Subjects:
Galaxy halo
galaxies: individual (Sagittarius)
Galaxy: structure
Stellar content
Local group
Galaxy structure
Dynamics
Dwarf galaxies
Galaxy: halo -Galaxy: kinematics and dynamics
Kinematics
Tidal tail
Modelling
Sky surveys
galaxies: stellar content
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Summary:M giants recovered from the Two Micron All-Sky Survey have recently been used to map the position and velocity distributions of tidal debris from the Sagittarius (Sgr) dwarf spheroidal galaxy around the entire Galaxy. We compare this data set to both test-particle orbits and N-body simulations of satellite destruction run within a variety of rigid Milky Way potentials, and we find that the mass of the Milky Way within 50 kpc of its center should be (3.8-5.6) x 10 super(11) M sub( )in order for any Sgr orbit to simultaneously fit the velocity gradient in the Sgr trailing debris and the apocenter of the Sgr leading debris. Orbital pole precession of young debris and leading debris velocities in regions corresponding to older debris provide contradictory evidence in favor of oblate/prolate Galactic halo potentials, respectively, leading us to conclude that the orbit of Sgr has evolved over the past few gigayears. In light of this discrepancy, we consider constraints from only the younger portions of the debris within three models of the flattening of the Galactic potential [q = 0.90 (O), 1.0 (S), and 1.25 (P), i.e., oblate, spherical, and prolate] in our further N-body simulations. On the basis of the velocity dispersion and width along the trailing tidal stream, we estimate the current bound mass of Sgr to be M sub(Sgr) = (2-5) x 10 super(8) M sub( )independent of the form of the Galactic potential; this corresponds to a range of mass-to-light ratios (M/L) sub(Sgr) = 14-36(M/L) sub( )for the Sgr core. Models with masses in this range best fit the apocenter of leading Sgr tidal debris when they orbit with a radial period of roughly 0.85 Gyr and have perigalactica and apogalactica of about 15 and 60 kpc, respectively. These distances scale with the assumed distance to the Sgr dwarf and the assumed depth of the Galactic potential. The density distribution of debris along the orbit in these models is consistent with the M giant observations, and debris at all orbital phases in which M giants are obviously present is younger (i.e., was lost more recently from the satellite) than the typical age of a Sgr M giant star.
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ISSN:0004-637X
1538-4357
DOI:10.1086/426779