TY - JOUR
T1 - The Nature and Orbit of the Ophiuchus Stream
AU - Sesar, Branimir
AU - Bovy, Jo
AU - Bernard, Edouard J.
AU - Caldwell, Nelson
AU - Cohen, Judith G.
AU - Fouesneau, Morgan
AU - Johnson, Christian I.
AU - Ness, Melissa
AU - Ferguson, Annette M. N.
AU - Martin, Nicolas F.
AU - Price-Whelan, Adrian M.
AU - Rix, Hans-Walter
AU - Schlafly, Edward F.
AU - Burgett, William S.
AU - Chambers, Kenneth C.
AU - Flewelling, Heather
AU - Hodapp, Klaus W.
AU - Kaiser, Nick
AU - Magnier, Eugene A.
AU - Platais, Imants
AU - Tonry, John L.
AU - Waters, Christopher
AU - Wyse, Rosemary F. G.
PY - 2015/8/1
Y1 - 2015/8/1
N2 - The Ophiuchus stream is a recently discovered stellar tidal stream in the Milky Way. We present high-quality spectroscopic data for 14 stream member stars obtained using the Keck and MMT telescopes. We confirm the stream as a fast moving (vlos ∼ 290 km s-1), kinematically cold group ({σ }{v{los}}≲ 1 km s-1) of α-enhanced and metal-poor stars ([α/Fe] ∼ 0.4 dex, [Fe/H] ∼ -2.0 dex). Using a probabilistic technique, we model the stream simultaneously in line-of-sight velocity, color-magnitude, coordinate, and proper motion space, and so determine its distribution in 6D phase-space. We find that the stream extends in distance from 7.5 to 9 kpc from the Sun; it is 50 times longer than wide, merely appearing highly foreshortened in projection. The analysis of the stellar population contained in the stream suggests that it is ∼12 Gyr old, and that its initial stellar mass was ∼2 × 104 M⊙ (or at least ≳7 × 103 M⊙). Assuming a fiducial Milky Way potential, we fit an orbit to the stream that matches the observed phase-space distribution, except for some tension in the proper motions: the stream has an orbital period of ∼350 Myr, and is on a fairly eccentric orbit (e ∼ 0.66) with a pericenter of ∼3.5 kpc and an apocenter of ∼17 kpc. The phase-space structure and stellar population of the stream show that its progenitor must have been a globular cluster that was disrupted only ∼240 Myr ago. We do not detect any significant overdensity of stars along the stream that would indicate the presence of a progenitor, and conclude that the stream is all that is left of the progenitor.
AB - The Ophiuchus stream is a recently discovered stellar tidal stream in the Milky Way. We present high-quality spectroscopic data for 14 stream member stars obtained using the Keck and MMT telescopes. We confirm the stream as a fast moving (vlos ∼ 290 km s-1), kinematically cold group ({σ }{v{los}}≲ 1 km s-1) of α-enhanced and metal-poor stars ([α/Fe] ∼ 0.4 dex, [Fe/H] ∼ -2.0 dex). Using a probabilistic technique, we model the stream simultaneously in line-of-sight velocity, color-magnitude, coordinate, and proper motion space, and so determine its distribution in 6D phase-space. We find that the stream extends in distance from 7.5 to 9 kpc from the Sun; it is 50 times longer than wide, merely appearing highly foreshortened in projection. The analysis of the stellar population contained in the stream suggests that it is ∼12 Gyr old, and that its initial stellar mass was ∼2 × 104 M⊙ (or at least ≳7 × 103 M⊙). Assuming a fiducial Milky Way potential, we fit an orbit to the stream that matches the observed phase-space distribution, except for some tension in the proper motions: the stream has an orbital period of ∼350 Myr, and is on a fairly eccentric orbit (e ∼ 0.66) with a pericenter of ∼3.5 kpc and an apocenter of ∼17 kpc. The phase-space structure and stellar population of the stream show that its progenitor must have been a globular cluster that was disrupted only ∼240 Myr ago. We do not detect any significant overdensity of stars along the stream that would indicate the presence of a progenitor, and conclude that the stream is all that is left of the progenitor.
KW - Galaxy: halo
KW - Galaxy: kinematics and dynamics
KW - Galaxy: structure
KW - globular clusters: general
KW - Astrophysics - Astrophysics of Galaxies
U2 - 10.1088/0004-637X/809/1/59
DO - 10.1088/0004-637X/809/1/59
M3 - Article
SN - 0004-637X
VL - 809
JO - Astrophysical Journal
JF - Astrophysical Journal
ER -