Abstract:
In this thesis an attempt is made to address the Fanaroff-Riley (FR) dichotomy
observed in radio-powerful active galactic nuclei (AGNs) within the framework of the
“Unification Scheme” for radio-loud AGNs, using high angular resolution total intensity
and polarization observations in the radio and optical wavebands. We describe the
technique of Very Long Baseline Interferometry (VLBI) and VLBI polarimetry (VLBP)
which were made use of in order to study the magnetic (B) field structure and orientation
in AGN jets on parsec-scales. In this thesis we present the first VLBP images of four
relatively low-luminosity FRI radio galaxies with detected polarized emission on parsecscales.
We further present the results from our multi-frequency, multi-epoch VLBP
observations of the broad-line FRII radio galaxy – 3C111. We compare and contrast our
VLBP results in the light of the Fanaroff-Riley dichotomy and the Unified Scheme that
relates the FRI and FRII radio galaxies to BL Lac objects and quasars, respectively. We
find that the B-field geometry in FRIs and FRII(s) is similar to radio-powerful BL Lacs
and quasars respectively, in accordance with the Unified Scheme. We present VLBP
images of the relatively poorly studied subclass of BL Lacertae objects, the high-energy
peaked BL Lacs (HBLs). We find that they tend to exhibit a predominantly longitudinal
B-field geometry in their VLBI jets, similar to the radio-loud quasars but different from
the low-energy peaked BL Lacs (LBLs) which show a predominantly transverse B-field
geometry in their jets. We examine the nature of the unresolved optical nuclei discovered
by the Hubble Space Telescope in the centres of a majority of FR radio galaxies by fitting
simple models to the optical and radio data. We conclude that the nature of the optical
nuclei in the FRI population (FRI radio galaxies and BL Lac objects) and the FRII
population (FRII radio galaxies and radio-loud quasars) differs in a significant manner.
FRI sources probably lack the optically thick obscuring tori around their central engines
while FRII sources do not. Further, the contribution to the nuclear optical luminosity
from the accretion disk is much more significant in the FRII population.
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