A Disk of Young Stars at the Galactic Center as Determined by Individual Stellar Orbits

Lu, Jessica R.; Ghez, A. M.; Hornstein, S. D.; Morris, Mark; Becklin, E. E.; Matthews, K.

doi:10.1088/0004-637x/690/2/1463

Cited by 329 publications

(519 citation statements)

References 75 publications

(201 reference statements)

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“…Current observations favor in situ formation based on the steep fall off in the number of young disk stars at larger radii. The observed radial density profile is consistent with ρ(r) ∝ r −2 as predicted for in situ gas disks and is much steeper than the ρ(r) ∝ r −0.75 predicted for in-falling cluster scenarios (Lin & Pringle 1987;Berukoff & Hansen 2006;Levin 2007;Lu et al 2009;Bartko et al 2009). The simplest in situ formation scenarios initially produce circular orbits since gas that flows in at low or moderate rates circularizes prior to the onset of star formation (Nayakshin & Cuadra 2005;Alexander et al 2007;Löckmann et al 2009).…”

Section: The Young Nuclear Clustersupporting

confidence: 84%

“…The observed eccentricity distribution peaks at e=0.3 Yelda et al 2013). Scenarios invoking more rapid gas inflow, such as the infall of a single molecular cloud or the collision of two molecular clouds, could produce disk stars with large initial eccentricities and have the added bonus of producing a large population of young stars off the disk (Bonnell & Rice 2008;Wardle & Yusef-Zadeh 2008;Hobbs & Nayakshin 2009;Mapelli et al 2012), similar to what has been observed (Paumard et al 2006;Bartko et al 2009;Lu et al 2009;Yelda et al 2013). However, the evolution of an initially circular disk over 4-6 Myr depends on the initial mass function (IMF) of the stars and it is possible to evolve to today's observed distribution for moderately top-heavy IMFs .…”

Section: The Young Nuclear Clustersupporting

confidence: 77%

“…These surveys are deep enough to identify B main-sequence stars; however, they have very small fields of view (∼2"), which has led to incomplete spatial coverage (Figure 1). Proper motions and radial velocities of the young stars have revealed coherent dynamical structures, including one well-defined inner disk (Genzel et al 2000;Levin & Beloborodov 2003;Paumard et al 2006), and there is continued discussion on the possibility of a disk warp or a second disk (Genzel et al 2003;Bartko et al 2009;Lu et al 2009;Yelda et al 2013).…”

Section: The Young Nuclear Clustermentioning

confidence: 99%

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Young stars in the Galactic center

Lu¹,

Ghez

Morris

et al. 2013

Proc. IAU

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Abstract. The central parsec of our Galaxy hosts not only a supermassive black hole, but also a large population of young stars (age <6 Myr) whose presence is puzzling given how inhospitable the region is for star formation. The strong tidal forces require gas densities many orders of magnitude higher than is found in typical molecular clouds. Kinematic observations of this young nuclear cluster show complex structures, including a well-defined inner disk, but also a substantial off-disk population. Spectroscopic and photometric measurements indicate the initial mass function (IMF) differs significantly from the canonical IMF found in the solar neighborhood. These observations have led to a number of proposed star formation scenarios, such as an infalling massive star cluster, a single infalling molecular cloud, or cloud-cloud collisions. I will review recent works on the young stars in the central parsec and discuss connections with young nuclear star clusters in other galaxies, such as M31, and with star formation in the larger central molecular zone.

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Section: The Young Nuclear Clustersupporting

confidence: 84%

Section: The Young Nuclear Clustersupporting

confidence: 77%

Section: The Young Nuclear Clustermentioning

confidence: 99%

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Young stars in the Galactic center

Lu¹,

Ghez

Morris

et al. 2013

Proc. IAU

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“…As displayed in Figures 4(b), (c), RS5 and RS6 have near-IR counterparts. Although there is an early-type star, S1-22, that may be associated with RS6, RS5 is not identified as a near-IR star in various catalogs (e.g., Lu et al 2009Lu et al , 2013. There is no evidence for a known young and massive star associated with RS5.…”

Section: Proplyd Candidates Near Sgr a * ?mentioning

confidence: 96%

“…To see if these stars have radio continuum counterparts, their positions at the epoch of our 34 GHz observation on 2014 March 9 (2014.19) have been calculated based on proper motions and orbital accelerations have been derived from near-IR observations (Lu et al 2009;Gillessen et al 2009;Yelda et al 2014). Tables 2 and 3 give the positions of the S-cluster and their corresponding positional uncertainties at the epoch of 2014.19 and from two different catalogs (Gillessen et al 2006;Lu et al 2009). Table 4 Table 5 lists Gaussian-fitted positions of 8 radio sources (RS1-8) embedded within the diffuse extended emission associated with the Sgr A * ridge and the plume-like structure at 34 GHz (see Figures 1 and 2).…”

Section: Radio Emission From the S Clustermentioning

confidence: 99%

SGR A* and Its Environment: Low-Mass Star Formation, the Origin of X-Ray Gas and Collimated Outflow

Yusef‐Zadeh

Wardle

Schödel

et al. 2016

ApJ

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We present high-resolution multiwavelength radio continuum images of the region within 150″ of SgrA * , revealing a number of new extended features and stellar sources in this region. First, we detect a continuous 2″ east-west ridge of radio emission, linking SgrA * and a cluster of stars associated with IRS 13 N and IRS 13E. The ridge suggests that an outflow of east-west blob-like structures is emerging from SgrA * . In particular, we find arc-like radio structures within the ridge with morphologies suggestive of photoevaporative protoplanetary disks. We use infrared K s and L′ fluxes to show that the emission has similar characteristics to those of a protoplanetary disk irradiated by the intense radiation field at the Galactic center. This suggests that star formation has taken place within the S-cluster 2″ from SgrA * . We suggest that the diffuse X-ray emission associated with Sgr A * is due to an expanding hot wind produced by the mass loss from B-type main sequence stars, and/or the disks of photoevaporation of low mass young stellar objects (YSOs) at a rate of ∼10 −6  M yr −1 . The proposed model naturally reduces the inferred accretion rate and is an alternative to the inflow-outflow style models to explain the underluminous nature of Sgr A * . Second, on a scale of 5″ from Sgr A * , we detect new cometary radio and infrared sources at a position angle PA∼50°which is similar to that of two other cometary sources X3 and X7, all of which face Sgr A * . In addition, we detect a striking tower of radio emission at a PA∼50°-60°along the major axis of the Sgr A East supernova remnant shell on a scale of 150″ from Sgr A * . We suggest that the cometary sources and the tower feature are tracing interaction sites of a mildly relativistic jet from Sgr A * with the atmosphere of stars and the nonthermal Sgr A East shell at a PA∼50°-60°with´-, and opening angle 10°. Lastly, we suggest that the east-west ridge of radio emission traces an outflow that is potentially associated with past flaring activity from Sgr A * . The position angle of the outflow driven by flaring activity is close to −90°.

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Hypervelocity Stars in the Galactic Halo

Baumgardt¹

2010

Reviews in Modern Astronomy

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A Disk of Young Stars at the Galactic Center as Determined by Individual Stellar Orbits

Cited by 329 publications

References 75 publications

Young stars in the Galactic center

Young stars in the Galactic center

SGR A* and Its Environment: Low-Mass Star Formation, the Origin of X-Ray Gas and Collimated Outflow

Hypervelocity Stars in the Galactic Halo

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