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Case Western Reserve University May 19, 2009. Imaging Black Holes Testing theory of gas accretion:Testing theory of gas accretion: disks, jets Testing.

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Presentation on theme: "Case Western Reserve University May 19, 2009. Imaging Black Holes Testing theory of gas accretion:Testing theory of gas accretion: disks, jets Testing."— Presentation transcript:

1 Case Western Reserve University May 19, 2009

2 Imaging Black Holes Testing theory of gas accretion:Testing theory of gas accretion: disks, jets Testing General Relativity:Testing General Relativity: strong field gravity Avi Loeb Institute for Theory & Computation Harvard University

3 The Black Hole in the Galactic Center: SgrA* VLT with Adaptive Optics “3-color”: 1.5 - 3 u m 8.2 m VLT telescope CONICA (IR camera) NAOS (adaptive optics) 60 mas resolution

4 S-Stars Orbits Around SgrA* Ghez et al. 2008; Genzel et al. 2008 (BH at rest in GC)

5 SgrA* is the largest black hole on the sky

6 Can you hear me now? No, but no worries - you will be able to hear us for ~10 minutes until you reach the singularity… 10 million km

7 Broderick & Loeb 2005 Is general relativity a valid description of strong gravity? *Infrared variability of flux (Genzel et al.) and polarization (Eckart et al.) of SgrA*: hot spots. *Innermost Stable Circular Orbit: radius of 30 (10) micro- arcsecond and orbital time of 30 (8) minutes for a non-rotating (maximally-rotating) black hole at the Galactic center *A hot spot would result in infrared centroid motion (GRAVITY- VLT) and could be imaged by a Very Large Baseline Array of (existing) sub-millimeter observatories. Targets:SgrA* and M87

8 Three Fortunate Coincidences The accretion flow of SgrA* becomes transparent to synchrotron self-absorption at wavelengths shorter than 1 millimeter Interstellar scattering ceases to blur the image of SgrA* on horizon scales at wavelengths shorter than 1 millimeter The horizon scale of SgrA* and M87 (tens of micro-arcseconds) can be resolved by a Very Large Baseline Array across the Earth at wavelengths shorter than 1 millimeter

9 Different orbital phases of the hot spot  SgrA* 230 GHz with interstellar scattering 345 GHz with interstellar scattering

10 Preliminary Data Doeleman et al. (2008) detected SgrA* on 3.5 Giga-lambda baseline (JCMT/SMTO) at 230 GHz (1.3mm), confirming structure on <40 micro-arcseconds(scattering scale ~25x13). Reid et al. (2008) used VLBA to limit the variability in the centroid position of Sgr A* relative to a background quasar at 43GHz (7mm) to <100 +/-50 micro-arcsec for time scales between 50 and 200 minutes

11 Very Large Baseline Interferometry (VLBI) at sub-millimeter wavelengths

12 1.3mm VLBI (Doeleman et al. 2008) 1.3mm VLBI (Doeleman et al. 2008) ARO/SMT (Arizona); CARMA(California); JCMT (Hawaii)

13 Radiative Efficiency of accreting gas An Event Horizon vs a Surface Broderick, Loeb, & Narayan 2009 (arXiv:0903.1105)

14 M87 (~700 times more massive than SgrA*) (~2000 times farther than SgrA*)

15 44GHz, (7 mm) VLBA Junor, Biretta, & Livio (1999) Walker 2008 (Broderick & Loeb 2008)

16 1.3 mm Images US +EU +LMT

17 0.87 mm Images US +EU +LMT

18

19

20 The Forthcoming Collision Between the Milky-Way and Andromeda The merger product is the only cosmological object that will be observable to future astronomers in 100 billion years Collision will occur during the lifetime of the sun The night sky will change Simulated with an N-body/hydrodynamic code (Cox & Loeb 2007) The only paper of mine that has a chance of being cited in five billion years…

21 The Future Collision between the Milky Way and Andromeda Galaxies

22 Black Hole Binaries due to Galaxy Mergers

23 X-ray Image of a binary black hole system in NGC 6240 Komossa et al. 2002 z=0.025 10kpc

24 0402+379 (Rodriguez et al. 2006-9) Projected separation: 7.3 pc, Estimated total mass: VLBI at 1.35 GHz

25 J.Centrella et al. 2007

26 Viscous Dissipation of Gravitational Waves in a Thin Accretion Disk  Equal heating per log radius Kocsis & Loeb, Arxiv:0803.0003 (2008)

27 Gravitational Wave Recoil

28 Anisotropic emission of gravitational waves  momentum recoil GWs

29 Gravitational Wave Recoil

30

31

32  test particles with remain bound

33 Galaxies as “Bubble Chambers” for BHs ejected by gravitational wave recoil Loeb, PRL, 2007; astro-ph/0703722 Ionization trail Schnittman & Buonanno 2007Bonning, Shields & Salviander 2007 Quasar Velocity Offset 500 km/s 1000 km/s

34 Effect of Recoil on BH Growth and Feedback 440 km/s740 km/s Blecha & Loeb arXiv:0805.1420 Only a 10% increase in BH mass

35 Star Clusters Around Recoiled Black Holes in the Milky Way Halo escape(dwarf) <<kick ~hundreds of km/s <<escape(MW) O’Leary & Loeb, arXiv:0809.4262arXiv:0809.4262

36 Highlights Direct imaging of the nearest supermassive black holes (SgrA*, M87) might become feasible within the next few years GW-recoiled black holes have observable signatures: offset quasars, floating star clusters in the Milky-Way, electromagnetic counterparts to LISA sources

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