Intermediate-mass Black Holes in Star Clusters Holger Baumgardt Astrophysical Computing Laboratory, RIKEN, Tokyo new address:

Slides:

Advertisements

Similar presentations

The W i d e s p r e a d Influence of Supermassive Black Holes Christopher Onken Herzberg Institute of Astrophysics Christopher Onken Herzberg Institute.

Advertisements

Formation of Globular Clusters in  CDM Cosmology Oleg Gnedin (University of Michigan)

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”

February 9, 11:00 am. The unusually bright centers found in some galaxies are called 1.active galactic nuclei. 2.starbursts. 3.halos. 4.supermassive.

Chapter 16 Dark Matter And The Fate Of The Universe.

Chapter 20 Dark Matter, Dark Energy, and the Fate of the Universe.

Clusters & Super Clusters Large Scale Structure Chapter 22.

Stars and the HR Diagram Dr. Matt Penn National Solar Observatory

LISA will be able to detect compact objects that spiral into a MBH by GW emission from up to a distance of a Gpc. The signal is expected to be weak. To.

The Milky Way PHYS390 Astrophysics Professor Lee Carkner Lecture 19.

© 2010 Pearson Education, Inc. Chapter 21 Galaxy Evolution.

Weak-Lensing selected, X-ray confirmed Clusters and the AGN closest to them Dara Norman NOAO/CTIO 2006 November 6-8 Boston Collaborators: Deep Lens Survey.

Spatial Structure Evolution of Open Star Clusters W. P. Chen and J. W. Chen Graduate Institute of Astronomy National Central University IAU-APRM

Andrej Čadež Colaborators Uroš Kostić Massimo Calvani Andreja Gomboc Tidal energy release before plunging into a black hole Andrej Čadež Uroš Kostić Massimo.

Galaxies What is a galaxy? How many stars are there in an average galaxy? About how many galaxies are there in the universe? What is the name of our galaxy?

Class 24 : Supermassive black holes Recap: What is a black hole? Case studies: M87. M106. MCG What’s at the center of the Milky Way? The demographics.

The Swansong of Stars Orbiting Massive Black Holes Clovis Hopman Weizmann Institute of Science Israel Advisor: Tal Alexander.

Galactic Evolution PHYS390 Astrophysics Professor Lee Carkner Lecture 21.

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/

ASTR100 (Spring 2008) Introduction to Astronomy Galaxy Evolution & AGN Prof. D.C. Richardson Sections

Dynamical Evolution and the Mass Function of Globular Cluster Systems Dynamical Evolution and the Mass Function of Globular Cluster Systems Steve Zepf.

Close encounters between stars and Massive Black Holes Clovis Hopman Weizmann Institute of Science Israel Advisor: Tal Alexander.

Galaxies and the Foundation of Modern Cosmology III.

X-ray Binaries in Nearby Galaxies Vicky Kalogera Northwestern University Super Star Clusters Starburst galaxies Ultra-Luminous X-Ray Sources Elliptical.

Theoretical Studies of X-Ray Binaries in Clusters Vicky Kalogera MODEST-6 ExtraGalactic only…

An alternative hypothesis to account for the LMC microlensing events Jordi Miralda-Escudé The Ohio State University IEEC/ICREA.

The Milky Way Galaxy. The Milky Way We see a band of faint light running around the entire sky. Galileo discovered it was composed of many stars. With.

Review for Exam 3.

J. Cuadra – Accretion of Stellar Winds in the Galactic Centre – IAU General Assembly – Prague – p. 1 Accretion of Stellar Winds in the Galactic Centre.

Stellar Disruptions of Super Massive Black Holes Ron Caplan March 7, 2003.

Black holes: do they exist?

The Milky Way Appears as a band of light stretching across the sky There are dark regions along the band, giving the appearance of a lack of stars This.

Star Clusters and their stars Open clusters and globular clusters General characteristics of globular clusters Globular cluster stars in the H-R diagram.

The Evolution of Quasars and Massive Black Holes “Quasar Hosts and the Black Hole-Spheroid Connection”: Dunlop 2004 “The Evolution of Quasars”: Osmer 2004.

Remnant of a Type II supernova explosion Iron core collapses until neutrons are squeezed tightly together During the explosion core remains intact, outer.

Detection rates for a new waveform background design adopted from The Persistence of Memory, Salvador Dali, 1931 Bence Kocsis, Merse E. Gáspár (Eötvös.

Accretion in Early-Type Galaxies Haiguang Xu Department of Physics Shanghai Jiao Tong University

© 2010 Pearson Education, Inc. Chapter 21 Galaxy Evolution.

1. Exoplanet detection (500+) 2 Gravitational attraction between a stellar mass (sun) and planets (bigger the better, why?) makes sun’s position wobble.

Delayed mergers: The contribution of ellipticals, globular clusters, and protoclusters to the LIGO detection rate Aug 16, 2005 Richard O’Shaughnessy (

Major dry-merger rate and extremely massive major dry-mergers of BCGs Deng Zugan June 31st Taiwan.

Quiz #10 What would really happen to you if you were to fall all the way into the Event Horizon of a black hole? We know the gravity is unbelievably strong.

Copyright © 2010 Pearson Education, Inc. Chapter 16 Galaxies and Dark Matter Lecture Outline.

Black Holes and the Evolution of Galaxies…. Summary Quasars and Evolution: the universe becomes interesting How we do it: things invisible to see. Demographics:

Super Massive Black Holes The Unknown Astrophysics of their initial formation.

17 - Galaxy Evolution (and interactions).

The Inter-Galactic Populations and Unbound Dark Matter Ing-Guey Jiang and Yu-Ting Wu National Tsing-Hua University Taiwan.

The Evolution of Intracluster Light Craig Rudick Department of Astronomy Case Western Reserve University.

BH Astrophys. Ch4 Intermediate Mass Black Holes. Outline 1. The definition Possible candidates: 2. ULXs (Ultra-luminous X-ray sources) in star-forming.

Milky Way: Galactic Structure and Dynamics Milky Way has spiral structure Galactic Bulge surrounds the Center Powerful radio source Sagittarius A at Center.

Oct. 30, 2002Source Simulation & Data Analysis1 Gravitational-Wave Observations of Galactic Populations of Compact Binaries M. Benacquista Montana State.

Chapter 21 Galaxy Evolution Looking Back Through Time Our goals for learning How do we observe the life histories of galaxies? How did galaxies.

KASI Galaxy Evolution Journal Club A Massive Protocluster of Galaxies at a Redshift of z ~ P. L. Capak et al. 2011, Nature, in press (arXive: )

Chapter 25 Galaxies and Dark Matter. 25.1Dark Matter in the Universe 25.2Galaxy Collisions 25.3Galaxy Formation and Evolution 25.4Black Holes in Galaxies.

Black Holes in Globular Clusters Karl Gebhardt (UT)

Galaxies. The Hubble Tuning-Fork Diagram This is the traditional scheme for classifying galaxies:

Evolution of massive binary black holes Qingjuan Yu Princeton University July 21, 2002.

Astronomy 1020-H Stellar Astronomy Spring_2016 Day-38.

An Overabundance of X-ray Binaries Near the Galactic Center

evolution, core collapse, binaries, collisions

Chapter 21 Galaxy Evolution

Theoretical ideas for the formation and feeding of IMBHs

M. Benacquista Montana State University-Billings

Star Clusters and their stars

Observational Evidence for Black Holes in Globular Clusters

Black Hole Binaries Dynamically Formed in Globular Clusters

Galaxies With Active Nuclei

Super Massive Black Holes

Galaxies With Active Nuclei

Presentation transcript:

Intermediate-mass Black Holes in Star Clusters Holger Baumgardt Astrophysical Computing Laboratory, RIKEN, Tokyo new address: University of Bonn, Germany in collaboration with Jun Makino, Simon Portegies Zwart, Piet Hut, Steve McMillan, Toshikazu Ebisuzaki

NBODY4 + GRAPE6

Formation of IMBH's in star clusters Observations indicate that there might be a connection between ULX and star clusters. Matsumoto et al. (2001) for example found a bright X-ray source at the center of the starburst galaxy M82 with an Eddington luminosity corresponding to a black hole of several hundred solar masses. Optical follow-up observations showed that the position of this source coincides with that of a young luminous star cluster.

McCrady et al. (2003) used the HST and Keck telescopes to determine the density profile and total masses for a number of young star clusters in M82. MGG-11 was the most concentrated (half-light radius 1.2 pc) and second heaviest cluster in their sample (M= 3.5*10**5 Msun). In addition it appears to have a top-heavy IMF. Formation of IMBH's in star clusters

Simulations of Black Hole Formation We followed the evolution of MGG-11 by N-body simulations of star clusters containing N= stars, and starting from King models with initial concentrations in the range 3.0 < Wo < We found that heavy mass stars sink into the cluster center as a result of dynamical friction. For central concentrations Wo>9.0, this happened fast enough that runaway merging of stars occurs in the center.

Simulations of Black Hole Formation The runaway merging leads to the formation of a single object of more than 1000 Msun within a few Myrs. This object could form an intermediate- mass black hole which creates the X-ray radiation. Simulations of other clusters show that only MGG-11 is concentrated enough to undergo runaway merging, in agreement with the fact that only MGG-11 contains an ULX. (from Portegies Zwart et al. 2004)

Black Holes in Globular Clusters

Observations of M15 The radial velocities of stars show an increase of the vel. dispersion towards the center. If one estimates the observed velocity dispersion from the cluster light profile with a constant M/L ratio, one obtains a mismatch in the inner parts. This was seen as evidence for an IMBH of about 2000 Msun in the center of M15. (from Gerssen et al )

N-body simulations of M15 Density profile Velocity dispersion

Evolution of Star Clusters with Black Holes Our simulations have shown that star clusters with high enough densities can form black holes through run-away merging of stars. In addition, the simulations done so far have shown that a black hole in M15 is not necessary to explain the observations, but they do not rule it out. We therefore also made simulations of star clusters which start with an IMBH at their center.

Evolution of clusters with an IMBH Cluster expansion Projected radii

Evolution of clusters with an IMBH 3D Density profile:

Projected Density Profile The projected density distribution of bright stars has a constant density core and would appear like a standard King profile cluster to observers. HST observations of the central velocity dispersion would reveal the IMBH for galactic GCs.

Dynamical Processes in the Center Black hole ejection The innermost stars

Gravitational radiation from IMBH Scaling our result to larger particle numbers, we find that each IMBH in a globular cluster will undergo at least one merging event with another BH. Assuming a 10% IMBH fraction, there is only a 10% chance that any galactic GC presently emits detectable amounts of GR. Within 1 Gpc, about 5 events should be detectable per year.

Disruption of stars by the IMBH IMBHs in the densest globular clusters have disruption rates of up to 1E-6/yr. Most clusters with high disruption rates are however core collapse clusters. IMBH in clusters with large enough radii have disruption rates of only 1E- 9/yr. IMBHs would therefore probably be invisible in X-rays most of the time.

Disruption of Stars by the IMBH Most stars disrupted by the IMBH are main-sequence stars and giants. Disruption of neutron stars are rare. During the simulations, no black holes merged with the IMBH. Stars disrupted by the IMBH move on very elongated orbits, so the fate of the stellar material is uncertain.