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Radio evidence for AGN activity: relativistic jets as tracers of SMBHs

Published online by Cambridge University Press:  07 March 2016

Kenneth I. Kellermann*
Affiliation:
National Radio Astronomy Observatory, 520 Edgemont Rd., Charlottesville, VA, USA email: kkellerm@nrao.edu
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Abstract

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Although the radio emission from most quasars appears to be associated with star forming activity in the host galaxy, about ten percent of optically selected quasars have very luminous relativistic jets apparently powered by a SMBH which is located at the base of the jet. When these jets are pointed close to the line of sight their apparent luminosity is enhanced by Doppler boosting and appears highly variable. High resolution radio interferometry shows directly the outflow of relativistic plasma jets from the SMBH. Apparent transverse velocities in these so-called “blazars” are typically about 7c but reach as much as 50c indicating true velocities within one percent of the speed of light. The jets appear to be collimated and accelerated in regions as much as a hundred parsecs downstream from the SMBH. Measurements made with Earth to space interferometers indicate apparent brightness temperatures of ~ 1014 K or more. This is well in excess of the limits imposed by inverse Compton cooling. The modest Doppler factors deduced from the observed ejection speeds appear to be inadequate to explain the high observed brightness temperatures in terms of relativistic boosting.

Type
Contributed Papers
Copyright
Copyright © International Astronomical Union 2016 

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