1 VLT kinematics for Omega Centauri : Further support for a central BH E. Noyola et al. 2010, ApJ, 719, L60 2011 Jun 30 (Thu) Sang Chul KIM ( 김상철 )

Slides:



Advertisements
Similar presentations
Dark Matter in Dwarf Galaxies
Advertisements

An Abundance Spread in the Bootes I Dwarf Spheroidal Galaxy? John E. Norris The Australian National University Gerard Gilmore University of Cambridge R.F.G.
Myung Gyoon LEE (K-GMT SWIG/Seoul National University) GMT2010:Opening New Frontiers with the GMT , Seoul National University, Korea 1.
P. Miocchi 1,2, R. Capuzzo-Dolcetta 2, P. Di Matteo 2,3 1 INAF - Osserv. Astron. di Teramo (Teramo, Italy) 2 Dept. of Physics, Univ. of Rome “La Sapienza”
Padova 03 3D Spectrography 3D Spectrography IV – The search for supermassive black holes.
Dissolving globular clusters: the fate of M 12 Work in collaboration with F. Paresce (INAF) and L. Pulone (Obs. Rome)
Hypervelocity Stars Ejected from the Galactic Center STScI Colloquium Oct 3, 2007 Warren R. Brown Smithsonian Astrophysical Observatory Collaborators:
Supermassive Black Holes Course 689 Presentation by Yan Shi Nov 5, 2009.
Kinematics of planetary nebulae in the outskirts of galaxies, from slitless FOCAS radial velocities Roberto H. Mendez Institute for Astronomy, University.
The M-81 Group of Galaxies Brian Fleming Stephanie LaMassa Seamus Riley (The Chunky Ponies)
Dwarf Galaxies and Their Destruction... Marla Geha Carnegie Observatories (OCIW) Collaborators: P. Guhathakurta (UCSC), R. van der Marel (STScI)
Black Holes and the Fundamental Correlations Karl Gebhardt (UT Austin, MPE/USM)
Internal motions in star clusters Gordon Drukier Dept. of Astronomy, Yale University Yale Astrometry Workshop — 21 July 2005 Gordon Drukier Dept. of Astronomy,
Largest SMBH Author: Mr. Ryan Houghton, Astrophysics, University of Oxford, U.K. Collaborators: N. Thatte (Oxford, UK), R. Davies (Oxford, UK), M. Sarzi.
Our galaxy's double halo Department of Physics National Tsing Hua University G.T. Chen 2007/12/20 December.
Observational Evidence for Black Holes in Globular Clusters Karl Gebhardt (UT Austin)
RECOILING BLACK HOLES IN GALACTIC CENTERS Michael Boylan-Kolchin, Chung-Pei Ma, and Eliot Quataert (UC Berkeley) astro-ph/
On the Distribution of Dark Matter in Clusters of Galaxies David J Sand Chandra Fellows Symposium 2005.
M15 Remco van den Bosch Sterrewacht Leiden Tim de Zeeuw, Karl Gebhardt, Eva Noyola, Glenn van de Ven.
CDM cusps in LSB galaxies by means of stellar kinematics A.Pizzella, E.M.Corsini, F. Bertola Università di Padova And J. Magorrian, M. Sarzi University.
Evidence for a Central Black Hole in Omega Centauri Eva Noyola, Karl Gebhardt (University of Texas at Austin) & Marcel Bergmann (Gemini Observatory)
Black Holes in Nearby Galaxies Claire Max NGAO Team Meeting March 7, 2007.
Dynamics of the outer parts of  Centauri Gary Da Costa Mt Stromlo Observatory, Research School of Astronomy & Astrophysics, Australian National University.
Kinematics of Globular Clusters in Giant Elliptical Galaxies Hong Soo Park 1, Myung Gyoon Lee 1, Ho Seong Hwang 2, Nobuo Arimoto 3, Naoyuki Tamura 4, Masato.
M101 Group Dave Riebel & Justice Bruursema 12 Februrary 2007.
Globular Clusters: HST Breathes New Life into Old Fossils STScI Public Lecture Series Jay Anderson August 3, 2010.
Photometric Properties of Spiral Galaxies Disk scale lengthCentral surface brightness (I d in BM) Bulges Luminosity profiles fit r 1/4 or r 1/n laws Structure.
Roeland van der Marel Intermediate-Mass Black Holes: Formation Mechanisms and Observational Constraints.
Structural Parameters for confirmed Globular Clusters in NGC 5128 Matias Gomez Universidad de Concepcion - Chile Collaboration with: K. Woodley, W. E.
Unravelling the formation and evolutionary histories of the most massive galaxies Ilani Loubser (Univ. of the Western Cape)
Globular Clusters: HST Breathes New Life into Old Fossils Hubble Science Briefing Jay Anderson STScI June 3,
IAS, June 2008 Caty Pilachowski. Visible in the Southern Sky Listed in Ptolemy's catalog Discovered by Edmond Halley in 1677 –non-stellar –"luminous spot.
Astrometry & the Yale/WIYN ODI Survey. Potential astrometric projects Local luminosity function (van Altena, et al.) obtain  ≤ 0.10 parallaxes to 150.
Roeland van der Marel HST’s Search for Intermediate-Mass Black Holes (IMBHs) in Globular Clusters.
Hot gas in galaxy pairs Olga Melnyk. It is known that the dark matter is concentrated in individual haloes of galaxies and is located in the volume of.
The shapes of the THINGS HI profiles Presented by : Ianjamasimanana Roger Supervisor : Erwin de Blok UNIVERSITY OF CAPE TOWN.
Counterrotating core in the LMC: Accretion and/or Merger ? Annapurni Subramaniam Indian Institute of Astrophysics, Bangalore, INDIA (Evidence of a counterrotating.
Globular clusters in the galactic plane Václav Glos Star clusters.
Dimitri Gadotti (Max Planck Institute for Astrophysics – Garching) MAGPOP Network Meeting What can we learn from imaging and spectroscopy of well-resolved.
Globular Cluster and Satellite Orbits: 2008 Status Dana Casetti-Dinescu - Wesleyan and Yale.
Selection criteria: 21 < R < 24 (-14 < M R < -11) 0.45 < (B – V) < 1.1 (3 arcsec apertures) Highest priority to sources showing any sign of having profiles.
25 Years of Globular Clusters with HST
The Milky Way Galaxy. Sky Maps in Different Bands.
1 Supermassive BHs do not correlate with DM haloes of galaxies J. Kormendy & R. Bender 2011, Nature, 469, Feb 10 Sang Chul KIM ( 김상철 )
17 - Galaxy Evolution (and interactions).
Intermediate-mass Black Holes in Star Clusters Holger Baumgardt Astrophysical Computing Laboratory, RIKEN, Tokyo new address:
David R. Law Hubble Fellow, UCLA The Physical Structure of Galaxies at z ~ John McDonald, CFHT Galaxies in the Distant Universe: Ringberg Castle.
Gurtina Besla Harvard CfA Collaborators: Nitya Kallivayalil
Our Changing View of the Galaxy NGC 2915 Ed Elson Department of Astronomy, UCT Supervised by: Prof. R. C. Kraan-Korteweg Prof W. J. G. de Blok 3 rd Annual.
Xiangxiang Xue Hans-Walter Rix, G. Zhao, P. Re Fiorentin, T. Naab, M. Steinmetz, E. F. Bell, F. C. van den Bosch, T. C. Beers, R. Wilhelm, Y. S. Lee, C.
Measuring the Stars What properties of stars might you want to determine?
SEGUE Target Selection on-going SEGUE observations.
Competitive Science with the WHT for Nearby Unresolved Galaxies Reynier Peletier Kapteyn Astronomical Institute Groningen.
Parallax Luminosity and mass functions - a few basic facts Kinematics of the solar neighborhood Asymmetric drift Thin disk, thick disk Open and globular.
Galactic Structure and Near-field Cosmology via Astrometry with ODI Dana Casetti, Terry Girard, Bill van Altena - Yale Orbits of MW: satellites satellites.
IFU studies of GRBs and SNe regions Lise Christensen (Excellence Cluster Universe, Technical University Munich) + Maryam Modjaz (NY), + Christina Thoene.
Black Holes in Globular Clusters Karl Gebhardt (UT)
Vatican 2003 Lecture 30 HWR Black Holes. Vatican 2003 Lecture 30 HWR Black Holes and Galaxy Centers Two most important energy production mechanisms in.
Julio Chanamé 10/March/2009 On the Full Exploitation of Discrete Velocity Data: Motivation, Method, and some Applications.
“Globular” Clusters: M15: A globular cluster containing about 1 million (old) stars. distance = 10,000 pc radius  25 pc “turn-off age”  12 billion years.
Evolution of massive binary black holes Qingjuan Yu Princeton University July 21, 2002.
Lecture 16 Measurement of masses of SMBHs: Sphere of influence of a SMBH Gas and stellar dynamics, maser disks Stellar proper motions Mass vs velocity.
The Origin and Structure of Elliptical Galaxies
OB and Wolf-Rayet stars
Dynamical Models for Galaxies Observed with SAURON Michele Cappellari
Resolving the black hole - nuclear cluster - spheroid connection
how they might form and evolve
Towards a kinematic model of the Local Group as-Astrometry with VLBI
Observational Evidence for Black Holes in Globular Clusters
E. Moulin, C. Medina, J.-F. Glicenstein and A. Viana IRFU, CEA-Saclay
Presentation transcript:

1 VLT kinematics for Omega Centauri : Further support for a central BH E. Noyola et al. 2010, ApJ, 719, L Jun 30 (Thu) Sang Chul KIM ( 김상철 )

2 BHs – 3 kinds Stellar mass BHs : M ● ≤ 100 M ⊙  death of massive stars Super massive BHs : M ● ∼ 10 6 – M ⊙ (SMBHs) Intermediate-mass BHs ∼ 10 3 M ⊙ (IMBHs; M ⊙ )

Noyola et al. 2008, ApJ, 676, 1008 (Fig 9) M ● - σ relation

Noyola et al. 2008, ApJ, 676, 1008 (Fig 9) Tremaine et al. (2002, ApJ, 574, 740) IMBHs

ω Centauri RA(J2000) = DEC = (Harris 1996, AJ, 112, 1487) l = , b = E(B-V) = 0.12 [Fe/H] = d = 5.3 kpc 4.8 ± 0.3 kpc (van de Ven+06) largest GC r t = 69 pc most massive GC 5.1 × 10 6 M ⊙ 2.5 × 10 6 M ⊙ (van de Ven+06) M V = most flattened GC ( ε =1-b/a=0.19) N E MPI/ESO 2.2m/WFI (BVI) ~ 30’ × 30’

NGC 1978 in LMC ε = 1-b/a = 0.33

might be the stripped core of a dwarf galaxy Y.-W. Lee et al. 1999, Nature, 402, 55 ω Centauri Metallicity spread Double main sequence  Central σ = 22 ± 4 km/s (Meylan+95) Fast global rotation = 8 km/s at r=11 pc (Merritt+97) Retrograde orbit around the MW (Dinescu+01)

8 BH in ωCentauri Noyola et al. (2008) line-of-sight velocity dispersion (LOSVD) rise toward the center  M ● = (4 ± 1) × 10 4 M ⊙ van der Marel & Anderson (2010) HST/ACS proper motions  M ● = (1.8 ± 0.3) × 10 4 M ⊙ for isotropic model  M ● ≤ 7.4 × 10 3 M ⊙ for anisotropic model ※ Center separation ∼ 12”

9 Surface brightness profile of ωCentauri Noyola et al. (2008, ApJ, 676, 1008) : Fig 1

10 Velocity dispersion profile of ωCentauri Noyola et al. (2008) : Gemini South/GMOS IFU

11 Observations VLT2/ARGUS IFU with FLAMES, 2009 June R ~ 10, – 9400 Å r egion  Ca triplet region (8450 – 8700 Å ) FOV = 11.5” × 7.3” (0.52” × 0.52” pixels) ~ 12”

12 Fig 1 ~ 30” × 40” Noyola+08 new kinematic center Anderson & van der Marel 2010 Previous GMOS IFU obs Constructed ARGUS images ~ 12”

13 Hot stars Exclude regions dominated by (1) hot stars with Paschen-series lines and (2) bright stars  ~ 15% of the pixels are excluded Fig 2 : spectral fit to the integrated spectra

14 Dynamical analysis 5 annuli centered on each center New kinematic center / Noyola et al. (2008) / Anderson & van der Marel (2010) S/N ≥ 40 in each bin Central annulus ∼ 60 px, outer annulus ∼ 500 px

15 Velocity dispersions Fig 3 core radius, r c = 1.40’ = 84” (log 84 = 1.92) New kinematic center / Noyola et al. (2008) / Anderson & van der Marel (2010) Every case : increase in the dispersion inside the r c compared to data r > 50” (log 50 = 1.70) ※ thick lines : isotropic models without a BH Binary fraction ≤ 18% (Carney+ 2005)  will cause only a few % increase in σ 7.5 × 10 4 M ⊙ 0 M ⊙

16 Calculated χ 2 values for each model Noyola et al. (2008) : lower χ 2 values M ● = (5.2 ± 0.5) × 10 4 M ⊙ M ● = (4.75 ± 0.75) × 10 4 M ⊙ M ● = (3.0 ± 0.4) × 10 4 M ⊙

17 Velocity dispersions σ (100”) ∼ 17 km/s 7.5 × 10 4 M ⊙ 0 M ⊙ σ (center) ∼ 22.8 km/s

Noyola et al. 2008, ApJ, 676, 1008 (Fig 9) prediction : M ● = 1.3 × 10 4 M ⊙  sphere of influence ~ 5”

19 Thank you.

20 GCs with possible IMBHs Baumgardt et al. (2005, ApJ, 620, 238) M80 M62 M54 47 Tuc (N104) M10 (N6254)

21 BHs in GCs Safonova & Stalin (2010, NewA, 15, 450)

22 Dark stellar remnants (e.g.) neutron stars, stellar mass BHs, massive WDs Noyola et al. 2008, ApJ, 676, 1008 (Fig 9) Dark stellar remnants Luminous component

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2024 SlidePlayer.com Inc. All rights reserved.