1. Black Holes in Galaxies and Globular Clusters  The Current Status of Supermassive Black Hole Detections  Scaling Relations and SBH Demographics  Missing Pieces and Prospects for Future Progress Laura Ferrarese (Rutgers University)

2. Resolution is the Key  With the exception of the Iron K  observations, every other technique used to measure supermassive black holes masses probes regions well beyond the strong field regime. In units of the Schwarzschild radius R S = GM/c 2 = 1.5  10 13 M  cm.

3. Proper Motion in the Galactic Center  Schodel et al. 2003; Ghez et al. 2003  The most recent measurements exclude with high confidence that the central dark mass could consists of a cluster of unusual stars or elementary particles, leaving a supermassive black hole as the only viable possibility.

4. H20 Megamasers in NGC 4258  VLBI 1.35cm observations; Resolution:  =0.0006   0.0003 ,  v= 0.2 km s -1 oOnly 4% of Seyfert 2s host H 2 0 megamasers (Braatz et al. 1994 & 1996; Greenhill et al. 1997, 2002 & 2003). Of these only a small (~20%) fraction exhibit high velocity masers. +M51, NGC1068, NGC3079, NGC4945, NGC5793, NGC6240, IC2560, Mrk348, Mrk1419, Circinus oOf these, only N4258 has so far yielded a conclusive detection (Greenhill et al. 1996, 1997, Trotter et al. 1998) Miyoshi et al. 1995 0.13 pc 0.26 pc M ~ 4  10 7 M   h = 10 12 M  pc -3

5. Kinematics of Nuclear Dust Disks  Nuclear dust/gas disks are present in ~20% of Early-Type galaxies (Tran et al. 2001; Ferrarese et al. 2004) The ACS/Virgo Cluster Survey Collaboration, Côté et al. 2004

6. Kinematics of Nuclear Dust Disks  Ferrarese et al. 1994; Macchetto et al. 1997; Bower et al. 1998; van der Marel & van den Bosch 1998; Ferrarese & Ford 1999; Verdoes Kleijn et al. 2000; Marconi et al. 2001; Barth et al. 2001; Sarzi et al. 2001; Devereux et al. 2003; Tadhunter et al. 2003.  Attempts to apply the method to spiral galaxies are underway (Marconi et al. 2003; Sarzi et al. 2001; Coccato et al. 2004 - see poster by Elena Dalla Bontá et al.) Ford et al. 1994; Harms et al. 1994 Spatial resolution 0.1  with HST Gas emission lines are easy to measure Failure of the models is easily recognizable (Cappellari et al. 2002; Barth et al. 2001; Marconi et al. 2003) 7Dust disks are detected only in active galaxies 7Disk geometry (warps, etc.) needs to be constrained. 7Turbolence, asymmetric drifts and instrumental effects must be taken into account (Verdoes & Klejin et al. 2000, Barth et al. 2001, Maciejewski & Binney 2001) 7The disks must be in Keplerian motion: 2D velocity maps are essential Macchetto et al. 1997

7. The ACS/Virgo Cluster Survey Collaboration, Côté et al. 2004 Stellar Dynamics  Emsellem et al. 1999; Cappellari et al. 2002, Gebhardt et al. 2003 Spatial resolution 0.1  with HST Stellar kinematics is always gravitational 3I models provide a general description of the stellar system (Verolme et al. 2002; Gebhardt et al., Valluri et al. 2004). 7The galaxy’s inclination angle is generally assumed a priori. 7Axysimmetry is assumed (but see vanden Ven 2003) 72D velocity maps are rarely available. 7The stellar M/L ratio is assumed constant. 7Systematics are not well understood (Valluri et al. 2004; Richstone et al. 2004). 7The sphere of influence is not always resolved

8. Ferrarese & Ford 2004 Stellar Dynamics  Emsellem et al. 1999; Cappellari et al. 2002, Gebhardt et al. 2003 Spatial resolution 0.1  with HST Stellar kinematics is always gravitational 3I models provide a general description of the stellar system (Verolme et al. 2002; Gebhardt et al., Valluri et al. 2004). 7The galaxy’s inclination angle is generally assumed a priori. 7Axysimmetry is assumed (but see vanden Ven 2003) 72D velocity maps are rarely available. 7Systematics are not well understood (Valluri et al. 2004; Richstone et al. 2004). 7Importance of resolving the sphere of influence not recognized (Merritt & Ferrarese 2001; Marconi & Hunt 2003; Graham et al. 2001 vs Kormendy & Gebhardt 2001; Richstone et al. 2004).

9. Scaling Relations Kormendy & Richstone 1995Ferrarese & Merritt 2000; Gebhardt et al. 2000

10. The M - M DM Relation  Ferrarese 2002; Baes et al. 2003; Pizzella et al. 2004 (but see also Franx 1993; Wyse, Gilmore & Franx 1997)

11. Applicability of the M   Relation  “Primary Mass Calibrator” for non-standard methods of estimating masses (e.g. reverberation mapping, Ferrarese et al. 2001; Onken et al. 2004)  Estimating individual masses - 30% accuracy (Barth et al. 2002; Falomo, Kotilainen & Treves 2002; Marchesini et al. 2004).  Constrain models and numerical simulations following the formation and evolution of SBHs (Silk & Rees 1998; Haehnelt, Natarajan & Rees 1998; Kauffmann & Haehnelt 2000; Adams, Graff & Richstone 2000; Haehnelt & Kauffmann 2000; Burkert & Silk 2001; Ciotti & van Albada 2001; Fabian et al. 2001; Portegies-Zwart & McMillan 2002; MacMillan & Henriksen 2002; Zhao et al. 2002)  Study SBH demographics MethodRedshift   (10 5 M  Mpc -3 ) Reference QSO Optical counts0.3 < z < 5.0 2  4 Ferrarese 2002, Yu & Tremaine 2002, Salucci et al. 1999 AGN X-ray population counts z(peak) ~ 0.7~ 2Fabian (2003), Cowie (2003) Local AGNsz < 0.1 0.05  0.6 Padovani et al. 1990; Ferrarese 2002 Local Quiescent Galaxies z < 0.03 2.5  5 Ferrarese 2002; Yu & Tremaine 2002, Aller & Richstone 2002, Wyithe & Loeb 2003

12. SPIRALS ELLIPTICALS LENTICULARS Outstanding Issues  Despite the progress made in the past few years, systematics have not been fully investigated. These include:  Slope, zero point and scatter of SBH scaling relations  Dependence on Hubble type  Dependence on galaxy environment  Cosmic evolution of SBH scaling relations

13. Andromeda, NGC 205 and M32 1.5 X 2 degrees NGC205 - HST/ACS/HRC - 29X29 arcsec

14. The Low Mass End of the SBH Mass Function  3I models applied to the NGC 205 kinematics (Valluri et al. 2004) M(BH) = 0 M  M(BH) = 10 4 M  M(BH) < 5  10 4 M 

15. The Low Mass End of the SBH Mass Function NGC205 M33

16. Baumgardt et al. (2003) How Low Can You Go?  10 2 to 10 4 M  BH have long been suspected to form at the center of dense stellar clusters (e.g. Wyller 1970; Bahcall & Ostriker 1975; Frank & Rees 1976; Lightman & Shapiro 1977; Marchant & Shapiro 1980; Quinlan & Shapiro 1987; Portegies Zwart et al. 1999; Ebisuzaki et al. 2001..)  M15 Gerssen et al. (2002): < a few thousand M  Baumgardt et al. (2003): increase in the central M/L explained by a cluster of neutron stars and/or white dwarf. McNamara et al. (2003): “little evidence that M15 possesses an IMBH” based on proper motion study See poster by Dalia Chakrabarty  G1 (Gebhardt et al. (2002): M(BH) ~ 20,000 M  (1.5  level) based on integrated stellar kinematics Baumgardt et al. (2003) “there seems to be no need to invoke the presence of an IMBH in G1” based on N-body simulations  Off-nuclear ULXs (e.g. Miller & Colbert 2003): fluxes in excess of the angle-averaged flux Eddington luminosity of a 20 M  BH, many associated with star clusters Gebhardt et al. (2002) Gerssen et al. (2002)

17. The High Mass End of the SBH Mass Function  Richstone et al., cycle 9, 50 orbits, stellar dynamics  NGC1399, NGC1961, NGC4061, NGC4649  Ferrarese & Miralda Escudé, cycle12, 29 orbits, gas dynamics  BCGs in A2052, A2593, A1836, A3565  Richstone et al., cycle13, ?? orbits, stellar dynamics  NGC2832, IC1695, NGC4472, ESO507-G045, NGC7619, NGC4486, NGC1316

18. Systematics: Building the Local Sample HST 30m 8m CfA Redshift Sample, (Huchra et al. 1990) FornaxVirgo M101 group

19. Conclusions  HST’s two main contributions to this field, both of which have been made possible by its high spatial resolution, are:  the discovery of small (~ 1 arcsec), regular dust/gas disks, has opened a new possibility of constraining the central potential.  the measurement of SBH masses in a statistically significant number of galaxies, by resolving the sphere of influence  The M  relation must reflect (perhaps indirectly) the fundamental mode by which SBH form and evolve. A connection between SBHs and dark matter halos is certainly present. Establishing whether the relation is fundamental entail measuring dark matter halo masses in large sample of galaxies, which is best done using ground based telescopes.  Future progress hinges on being able to obtain accurate (10%) and reliable, mass determinations in diverse environments. In the optical, this requires the use of Integral Field Units coupled with high spatial resolution data.  HST capabilities in exploring the low and high mass end of the SBH mass function are limited. Reverberation mapping might be the most promising method for this aim.  The cosmic evolution of the SBH mass function must be studies using reverberation mapping or secondary mass estimators based on reverberation mapping.