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- First part: Quasars and Active Galactic Nuclei
- Some supplemental reading: GREAT compilation of review articles at http://nedwww.ipac.caltech.edu/level5/active_galaxies.html
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- Who am I???
- See http://www.mikebrotherton.com and http://physics.uwyo.edu/~mbrother
for information about me and course materials.
- Who are you???
- Tell me what you want to learn!
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3
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- Read Introductory material from Peterson: at http://nedwww.ipac.caltech.edu/level5/Cambridge/frames.html
- Make your own redshift vs. magnitude diagram of quasars from the Sloan
Digital Sky Survey (hint: google sdss quasar catalog) and be able to
discuss it
- Email me at mbrother@uwyo.edu if you have questions or need help
- Deadline Tuesday, October 14, 2008
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4
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5
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- Probable Black hole
- High velocities
- Large energy generation
- At a=275 AU P=2.8 yr Þ 2.7 million solar masses
- Radio image of Sgr A*
about 3 pc across, with model of surrounding disk
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6
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- The Genzel et al. movie based on NIR speckle interferometry of the
Galactic core.
- Basic orbital mechanics confirm, to high precision, a mass of 2.6
million solar masses that the stars are orbiting.
- X-ray flaring also seen.
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- FYI, here is one of the the Genzel groups individual K-band images taken
at high spatial resolution using the technique of speckle
interferometry..
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8
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- A small fraction of galaxies have extremely bright “unresolved”
star-like cores (active nuclei)
- Shown here is an HST image of NGC 7742, a so-called “Seyfert galaxy”
after Carl Seyfert who did pioneering work in the 1940s (you might look
up his original papers).
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9
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10
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- Small fraction of galaxies have extremely
bright “unresolved” star-like nuclei
- Very large energy generation
- Brightness often varies quickly
- Implies small size (changes not smeared out by light-travel time)
- High velocities often seen (> 10,000 km/s in lines)
- Emission all over the electro-magnetic spectrum
- Jets seen emerging from galaxies
- Think about the implications of jets.
Timescales, angular momentum.
What do they imply?
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12
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13
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14
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15
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16
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- Supermassive black hole (millions to billions of solar masses)
- Powered by an accretion disk.
- Jet mechanisms proposed, but very uncertain. Most quasars don’t have strong
jets. Some quasars clearly have
outflowing winds not well collimated.
- Also, an “obscuring torus” seems to be present. (Unified models apply
here.)
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17
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18
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- Black hole is “active” only if gas is present to spiral into it
- Isolated stars just orbit black hole same as they would any other mass
- Gas collides, tries to slow due to friction, and so spirals in (and
heats up)
- Conservation of angular momentum causes gas to form a disk as it spirals
in
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19
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20
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21
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- Very nice and relatively brief review article from “Quasars and
Cosmology” conference by Belinda Wilkes (CfA), a world expert on the
subject:
- http://nedwww.ipac.caltech.edu/level5/Sept01/Wilkes/Wilkes_contents.html
- Must account for physical processes producing prodigious luminosity
from radio wavelengths through the X-ray and even gamma ray regimes.
- Particular features of interest include radio-jets and the radio-quiet
vs. radio-loud dichotomy, the “big blue bump” that produces the
optical/UV energy peak and is thought to arise from an accretion disk,
and the far infrared that represents re-radiation by hot dust.
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22
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23
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- “Unified Models” explain some of the different classes of AGN,
particularly type 1 and type 2 Seyferts, via orientation.
- For specifics, see the Annual Reviews article by Antonucci, 1993, a
“bishop” in the “Church of Unification.”
- Another nice website:
http://www.mssl.ucl.ac.uk/www_astro/agn/agn_unified.html
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- The torus of gas and dust can block part of our view
- Seyfert 2 galaxies: Edge on view
Only gas well above and below disk is visible
See only “slow” gas Þ narrow emission lines
- Seyfert 1 galaxies: Slightly tilted view
Hot high velocity gas close to black hole is visible
High velocities Þ broad emission lines
- BL Lac objects: Pole on view
Looking right down the jet at central region
Extremely bright – vary on time scales of hours
- Quasars: Very active AGN at large distances
Can barely make out the galaxy surrounding them
Were apparently more common in distant past
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- The torus of gas and dust can block part of our view
- Seyfert 2 galaxies: Edge on view
Only gas well above and below disk is visible
See only “slow” gas Þ narrow emission lines
- Seyfert 1 galaxies: Slightly tilted view
Hot high velocity gas close to black hole is visible
High velocities Þ broad emission lines
- BL Lac objects: Pole on view
Looking right down the jet at central region
Extremely bright – vary on time scales of hours
- Quasars: Very active AGN at large distances
Can barely make out the galaxy surrounding them
Were more common in distant past
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- Core-dominant sources are seen jet-on, have flat radio spectra, and are
variable, optically polarized and beamed.
- Lobe-dominant sources are not very variable, have steep radio spectra
dominated by optically thin synchrotron emission, and are not beamed
strongly.
- Can measure orientation by various methods, e.g., LogR* = core/lobe
radio flux at 5 GHz rest-frame (Orr & Browne 1982), also Rv which
normalizes core flux with an optical magnitude (Wills and Brotherton
1995).
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- From Wills and Brotherton (1995), plotting Log R (which is rest-frame 5
GHz) core to lobe flux ratio), vs. the jet angle to the line of sight
where the jet angle is estimated from VLBI superluminal motion.
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- Need a supply of gas to feed to the black hole
- (Black holes from 1 million to >1 billion solar masses!
- Scales as a few percent of galaxy bulge mass.)
- Collisions disturb regular orbits of stars and gas clouds
- Could feed more gas to the central region
- Galactic orbits were less organized as galaxies were forming, also
recall the “hierarchical” galaxy formation
- Expect more gas to flow to central region when galaxies are young =>
Quasars (“quasar epoch” around z=2 to z=3)
- Most galaxies may have massive black holes in them
- They are just less active now because gas supply is less
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31
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32
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33
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- Hard to see. Why?
- How can you do it?
- HST (Bahcall, others)
- Near Infrared (eg., McLeod et al. 1996)
- What are their properties? Are
they related in any way to the activity?
- Very little known before advent of HST, AO, and large near-IR
detectors. Still a challenging
type of observation.
- Initially thought (based on Seyfert galaxies and radio galaxies) that
radio properties were related to host type. Seems to have been a selection effect.
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36
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37
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38
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39
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40
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- Energy Considerations
- Nuclear luminosities in excess of 1013 suns
- Gravitational release capable of converting on order 10% rest mass to
energy
- Rapid Variability
- Timescales < 1 day imply very small source
- Radio Jet Stability implies large, stable mass with large angular
momentum
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- SgrA* in the Milky Way
- Water Masers in NGC 4258, a few others
- Spatially Resolved Gas or Stellar Dynamics Using the Hubble Space
Telescope (HST)
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42
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43
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- Based on Greenhill et al. (1995)
- Warped Disk Model
- Radial Velocities and Proper Motions Measure a Mass of 4x107
solar masses (20 times more massive than SgrA*)
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- HST STIS shows evidence for a super massive black hole in M84 based on
spatially resolved gas dynamics (Bower et al 1997). Can also be done by examining
spatially resolved stellar absorption line profiles, plus complex 3D
orbital modeling.
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- Black Hole Masses are about 0.1% of the central galactic bulge mass (a
big surprise to theorists) and tightest correlation is with the stellar
velocity dispersion (after Gebhardt et al. 2000).
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- M = f (r ΔV2 / G)
- r = scale length of region
- ΔV is the velocity dispersion
- f is a factor of order unity dependent upon geometry and kinematics
- Estimates therefore require size scales and velocities, and verification
to avoid pitfalls (eg. radiative acceleration).
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- Source Radius
- X-ray Fe Kα 3-10 Rs
- Broad-Line Region 600 Rs
- Megamasers 4x104 Rs
- Gas Dynamics 8x105 Rs
- Stellar Dynamics 106 Rs
- Where Schwarzschild radius Rs = 2GM/c2 = 3x1013
M8 cm
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48
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- Broad lines are photoionized by the central continuum, which varies. The line flux follows the continuum
with a time lag t which is set by the size of the broad-line emitting
region and the speed of light.
Recombination timescales are very short, BLR stable, and
continuum source small and central.
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49
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- Four well studied AGNs, RM of multiple emission lines shows the expected
relationship (slope = -2) between time lags and velocities (note each of
the three will have different central black hole masses).
- NGC7469: 8.4x106 M☼
- NGC3783: 8.7x106 M☼
- NGC5548: 5.9x107 M☼
- 3C 390.3: 3.2x108 M☼
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50
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- RM-derived masses follow the same M-sigma relationship as seen for
normal galaxies that have black hole masses measured from HST spatially
resolved gas or stellar dynamics.
- Not more points since obtaining sigma for AGN is difficult (the AGN
dilutes the stellar absorption line EWs).
- Good to 0.5 dex
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51
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- Photoionization and “LOC” Models (Baldwin et al. 1996) suggests that
strong selection effects make line emission come from same physical
conditions (same U, n)
- U = Q(H)/4πR2nHc ~ L/nHR2
- So, for same U, nH, then expect that…
- R ~ L0.5
- How about in reality?
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52
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- Mentioned previously the Kaspi et al. (2000) result how R ~ L0.7
(above). In China, Misty Bentz of
OSU showed that proper correction for host galaxy leads to a slope of
0.5! Nice work. This permits the possibility of using single-epoch
measurements to estimate black hole masses – much easier!
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53
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- Single epoch FWHM vs. rms FWHM for Hβ
- Single epoch L vs. mean L
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54
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- Single epoch BH Mass vs. RM BH mass
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55
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- Extend Calibration to UV Line CIV λ1549
- This is a calibrated C IV Black Hole Mass – not wholly independent –
should be tested at high-z, high-L
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56
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- Hβ and C IV Black Hole Mass Comparison
- All high-z sources very luminous, massive, high L/Ledd. Please excuse the color code.
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- Hβ and C IV Black Hole Mass Comparison
- All high-z sources very luminous, massive, high L/Ledd. Please excuse the color code.
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- Black Hole Demographics (growth with z)
- Is all growth as AGN? Does that
produce the mass seen in relic black holes at low z?
- How does the M-sigma correlation arise?
- That is, how is black hole growth linked to the growth of galaxy bulges
and star formation?
- How do AGN behave as a function of mass, L/Ledd, viewing angle, etc.?
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- Intrinsic
- Broad (BALs)
- Narrow (NALs)
- Intervening
- Galactic
- Lyman alpha
- Metal line systems
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- Are they normal quasars with equatorial winds, seen edge-on?
- Or are they an evolutionary phase?
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63
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- Originally exclusively radio-quiet, but the first radio-loud BALQSOs
found by Becker et al. 1997 and Brotherton et al. 1998. From Becker et al. (2000), 90% of the
radio-selected BALQSOs are compact in FIRST maps (vs. 60% in the non-BAL
sample), and BOTH steep and flat radio spectra are present.
- Seems to rule out simple orientation schemes, right?
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- BALQSO Spectra from Brotherton et al. 1998.
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- Not to scale!
- Probably updated from “clouds” to “flows”
- I’ll look for more recent pictures
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Notes
