ACTIVE GALAXIES and GALAXY EVOLUTION Quasars Radio Galaxies
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ACTIVE GALAXIES and GALAXY EVOLUTION Quasars, Radio Galaxies, Seyfert Galaxies and BL Lacertae Objects Immense powers emerging from ACTIVE GALACTIC NUCLEI: it’s just a phase they’re going through!
Typical Quasar Appearance • Most are actually very faint • BUT their huge redshifts imply they are billions of light-years away and intrinsically POWERFUL
Radio Loud Quasar, 3 C 175
Thought Question What can you conclude from the fact that quasars usually have very large redshifts? A. B. C. D. They are generally very distant They were more common early in time Galaxy collisions might turn them on Nearby galaxies might hold dead quasars
Thought Question What can you conclude from the fact that quasars usually have very large redshifts? A. B. C. D. They are generally very distant They were more common early in time Galaxy collisions might turn them on Nearby galaxies might hold dead quasars All of the above!
Birth of a Quasar Movie • Fast variability implies small size • Immense powers emerging from a volume similar to the solar system!
SEYFERT GALAXIES • Sa, Sb galaxies with BRIGHT, SEMI-STELLAR NUCLEI • NON-THERMAL & STRONG EMISSION LINES • VARIABLE in < 1 yr COMPACT CORE • Type 1: Broad Emission lines (like QSOs), strong in X-rays • Type 2: Only narrow Emission lines, weak in X-rays • About 1% of all Spirals are SEYFERTS, so • Either 1% of all S's are always Seyferts OR • 100% of S's are Seyferts for about 1% of the time (MORE LIKELY) • OR 10% of S's are Seyferts for about 10% of the time (or any other combination of fraction and lifetime)
A Seyfert and X-ray Variability • Circinus, only 4 Mpc away; 3 C 84
More About Seyferts • Seyferts are weak radio emitters. • CONCLUSIONS ABOUT SEYFERTS Fundamentally, they are WEAKER QSOs • Type 1: we see the center more directly Type 2: dusty gas torus blocks view of the center
BL Lacertae Objects • NON-THERMAL SPECTRUM: Radio through X-ray (and gamma-ray) • Radiation strongly POLARIZED • HIGHLY VARIABLE in ALL BANDS • But (when discovered) NO REDSHIFT, so distances unknown • Later, surrounding ELLIPTICAL galaxies found • CONCLUSION: greatly enhanced emission from the AGN due to RELATIVISTIC BOOSTING of a JET pointing very close to us. • BL Lacs + OPTICALLY VIOLENTLY VARIABLE QUASARS ARE OFTEN CALLED BLAZARS
AGN CONTAIN SUPERMASSIVE BLACK HOLES (SMBHs) • KEY LONGSTANDING ARGUMENTS: • ENERGETICS: Powers up to 1048 erg/s (1041 W) Even at 100% efficiency would demand conversion of about 18 M /yr (=Mdot) into energy. • Nuclear processes produce < 1% efficiency. • GRAVIATIONAL ENERGY via ACCRETION can produce between 6% (non-rotating BH) and 32% (fastest-rotating BH), and the Luminosity is • L = G MBH Mdot / R, • with R the main distance from the Super Massive Black Hole (SMBH) where mass is converted to energy.
Time Variability • • • t. VAR = R / c t. VAR = 104 s R = 3 x 1014 cm = 10 -4 pc For L = 1047 erg/s, M_dot = 10 M /yr we get MBH = 3 x 108 M and RS = 9 x 1013 cm • So, R = 3 RS • MUTUALLY CONSISTENT POWERS AND TIMESCALES.
RECENT OBSERVATIONAL SUPPORT • The Hubble Space Telescope has revealed that star velocities rise to very high values close to center of many galaxies and gas is orbiting rapidly, e. g. M 87 • Disks have been seen via MASERS in some nearby Seyfert AGN. • VLBI: radio jets formed within 1 pc of center. • There are several other more technical lines of evidence also supporting the SMBH hypothesis for AGN.
Rapidly Rotating Gas in M 87 Nucleus M 87 zoom toward black hole
Direct Evidence for Rotating Disk Masers formed in warped disk in NGC 4258 (and a few other Seyfert galaxies)
Evidence for Supermassive Black Holes NGC 4261: at core of radio emitting jets is a clear disk ~300 light-yrs across and knot of emission near BH
SMBH Model for AGN
UNIFIED MODELS FOR AGN • Three main parameters: MBH; the accretion rate, M_dot, and viewing angle to the accretion disk axis, • Main ingredients: • SMBH > 106 M • 10 -5 pc < accretion disk < 10 -1 pc (AD) • broad line clouds < 1 pc (BLR) • thick, dusty, torus < 100 pc • narrow line clouds < 1000 pc (NLR) • sometimes, a JET (usually seen from < 102 pc to maybe 106 pc!)
Unification for Radio Quiet and Radio Loud • RADIO QUIET • High MBH, M_dot: • small: QSO is seen including AD and BLR • large: only NLR plus radiating torus: seen as Ultra. Luminous Infra. Red Galaxies (ULIRGs) • Low MBH, M_dot: • small: Seyfert Type 1 big: Seyfert Type 2 • RADIO LOUD (Jets) • High MBH, M_dot: • very small: Optically Violently Variable Quasar • small: radio loud quasar (QSR) • large: classical double radio galaxy (FR II type) • Low MBH. M_dot: • very small: BL Lac object • small: broad line radio galaxy (FR I type) • large: narrow line radio galaxy
Different AGN from Different Angles Luminous: Quasars seen close to perpendicular to disk and Ultraluminous Infrared Galaxies near disk plane Weaker: Type 1 or Type 2 Seyferts If jets are important: BL Lacs along jet axis, Quasars at modest angles & Radio Galaxies at larger angles
Black Holes in Galaxies • Many nearby galaxies – perhaps all of them – have supermassive black holes at their centers • These black holes seem to be dormant active galactic nuclei • All galaxies may have passed through a quasar-like stage earlier in time
Galaxies and Black Holes • Mass of a galaxy’s central black hole is closely related to mass of its bulge
Pop Quiz • Print your name (1) • Draw a labeled diagram of the Milky Way as it would be viewed “edge-on”. Be sure to give the overall size of the stellar disk as well as the distance of the solar system from the galactic center (6). • Draw a labeled Hubble “tuning-fork” diagram (I. e. , the simplest galaxy classifcation scheme). (4).
- How big is the galaxy
- Evolution of galaxies
- How are galaxies classified? *
- Radio galaxy
- Radio galaxy
- Waves are produced by stars and galaxies.
- Chapter 30 galaxies and the universe
- Conventional radio system
- And or boolean
- Primary active transport and secondary active transport
- Radio active decay
- Why do disk stars bob up and down as they orbit the galaxy?
- Life cycle of a galaxy
- Elliptical galaxies facts
- Galaxies
- The pity relation for an adiabatic expansion is
- Most galaxies in the inner region of a large cluster are
- Types of galaxies
- Brainpop galaxies quiz answers
- 4 types of galaxies
- Tipus de galaxies
- Properties of elliptical galaxies
- Universepg
- Galaxies lesson plan