Book contents
- Frontmatter
- Contents
- Index of Participants
- Preface
- I Evidence and Implications of Anisotropy in AGN
- II Luminosity Functions and Continuum Energy Distributions
- III The Broad Line Region: Variability and Structure
- IV X-rays and Accretion Disks
- V Beams, Jets and Blazars
- Magnetic Propulsion of Jets in AGN
- MHD Accretion-Ejection Model: X- and γ-rays and Formation of Relativistic Pair Beams
- Relativistic Electron Beams in AGN: Construction of Transonic Solutions
- Properties of Relativistic Jets
- A Massive Binary Black Hole in 1928+738?
- Gamma-Rays from Blazars: a Comparison of 3C 279, PKS 0537-441 and Mrk 421
- Microquasars in the Galactic Centre Region
- A Comparison of the Ultra-violet Continuum Variability Properties of Blazars and Seyfert 1s
- Simultaneous Optical and IR Monitoring of the Seyfert Nucleus NGC 7469
- Broad-Band Spectra and Polarization Properties of Variable Flat-Spectrum Radio Sources
- The Radio to Optical Variability of the BL Lac Object ON 231
- January 1992 Microvariability Campaign of OJ 287
- Blazar Microvariability: a Case Study of AO 0235+164
- Timescales of the Optical Variability of the BL Lacertae Galaxy PKS 2201+044
- Dynamics of Quasar Variability
- The Variability of a Large Sample of Quasars
- The Fate of Central Black Holes in Merging Galaxies
- Polarimetric Searching for Goldstone Bosons from AGNs
- VI Concluding Talk
Gamma-Rays from Blazars: a Comparison of 3C 279, PKS 0537-441 and Mrk 421
from V - Beams, Jets and Blazars
Published online by Cambridge University Press: 04 August 2010
- Frontmatter
- Contents
- Index of Participants
- Preface
- I Evidence and Implications of Anisotropy in AGN
- II Luminosity Functions and Continuum Energy Distributions
- III The Broad Line Region: Variability and Structure
- IV X-rays and Accretion Disks
- V Beams, Jets and Blazars
- Magnetic Propulsion of Jets in AGN
- MHD Accretion-Ejection Model: X- and γ-rays and Formation of Relativistic Pair Beams
- Relativistic Electron Beams in AGN: Construction of Transonic Solutions
- Properties of Relativistic Jets
- A Massive Binary Black Hole in 1928+738?
- Gamma-Rays from Blazars: a Comparison of 3C 279, PKS 0537-441 and Mrk 421
- Microquasars in the Galactic Centre Region
- A Comparison of the Ultra-violet Continuum Variability Properties of Blazars and Seyfert 1s
- Simultaneous Optical and IR Monitoring of the Seyfert Nucleus NGC 7469
- Broad-Band Spectra and Polarization Properties of Variable Flat-Spectrum Radio Sources
- The Radio to Optical Variability of the BL Lac Object ON 231
- January 1992 Microvariability Campaign of OJ 287
- Blazar Microvariability: a Case Study of AO 0235+164
- Timescales of the Optical Variability of the BL Lacertae Galaxy PKS 2201+044
- Dynamics of Quasar Variability
- The Variability of a Large Sample of Quasars
- The Fate of Central Black Holes in Merging Galaxies
- Polarimetric Searching for Goldstone Bosons from AGNs
- VI Concluding Talk
Summary
Abstract
The γ-ray emission from three of the sources detected by the COMPTON Observatory is discussed in the framework of relativistic jets emitting via the synchrotron self-Compton mechanism. The physical conditions in the three sources are derived and compared.
One of the most exciting discoveries of the COMPTON Observatory is the observation of γ-ray emission from 16 blazars. The broad band continuum (radio to X-ray) from these objects can be understood on the basis of the synchrotron self-Compton process in an inhomogeneous jet of plasma moving with relativistic speed (e.g.). In this model the synchrotron emission usually extends up to the UV and possibly to the X-ray bands. It is therefore natural to expect γ-rays produced by first order self-Compton scattering. The strength of this component depends on the ratio between the radiation and magnetic energy densities, and on the optical depth to photon-photon absorption. The latter process can be avoided if the source is beamed, and independent evidence for beaming is indeed found from radio and X-ray observations.
Nevertheless the γ-ray intensity measured from 3C 279 was a great surprise, in that the γ-ray power exceeded that in all other bands. This requires the radiation energy density to be larger than the magnetic energy density, a situation usually called the “Compton catastrophe” since at first sight it gives rise to divergent Compton energy losses.
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- The Nature of Compact Objects in Active Galactic NucleiProceedings of the 33rd Herstmonceux Conference, held in Cambridge, July 6-22, 1992, pp. 381 - 384Publisher: Cambridge University PressPrint publication year: 1994
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