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Promotionskolloquium |
Vieri Bartolini
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MPIfR
This thesis investigates the physical connection between accretion
processes and relativistic jet properties in radio-loud active galactic
nuclei (AGN), with emphasis on misaligned AGN (MAGN). By combining
multi-frequency VLBI observations up to 88 GHz with long-term γ-ray
monitoring from the Fermi Large Area Telescope and ancillary
multiwavelength data, this work explores how different accretion
regimes
influence jet magnetization, internal structure, and high-energy
variability. Growing observational evidence indicates that the
excitation class and accretion mode play a fundamental role in shaping
jet dynamics and radiative behaviour. Therefore, we explore the
dichotomy between High-Excitation Galaxies (HEGs), associated with
radiatively efficient thin disks, and Low-Excitation Galaxies (LEGs),
typically powered by radiatively inefficient accretion flows. MAGN
provide an ideal laboratory for this investigation because relativistic
and projection effects are reduced, allowing VLBI observations to probe
the compact jet base where high-energy emission is expected to
originate.
A detailed polarimetric analysis of the HEG radio galaxy 3C 111 reveals
a complex magnetized parsec-scale jet. Spectral and rotation-measure
mapping identify an optically thick feature located approximately 1–2
parsecs from the core that is co-spatial with extremely high Faraday
rotation, suggesting an interaction between the jet and a dense clumpy
torus cloud. Farther downstream, a significant transverse RM gradient
provides strong evidence for a helical magnetic field. These results
indicate that the jet in 3C 111 is still strongly magnetized on parsec
scales and propagates in a dense environment, possibly providing dense
external photon fields for γ-ray production through inverse Compton.
The role of the accretion regime is further explored through a
comparative multi-epoch and multi-wavelength analysis of the HEG 3C 111
and the LEG 3C 371, two MAGN with similar global properties but
markedly
different Eddington ratios. The HEG 3C 111 is dominated by superluminal
moving knots and is detected in γ-rays primarily during major flares
associated with the ejection of new jet features. In contrast, the LEG
3C 371 exhibits predominantly stationary structures that may act as
persistent particle acceleration sites, producing steadier high-energy
emission. The observed RM evolution and jet kinematics suggest that
stronger disk winds in HEGs may stabilize a relativistic spine through
mass loading of an outer sheath, whereas weaker winds in LEGs favor the
formation of standing recollimation shocks. We propose that the link
between accretion mode and jet properties is driven by differences in
disk winds: radiatively efficient HEGs produce strong winds that
stabilize the spine–sheath jet, enabling extended acceleration and
superluminal features, while weaker winds in LEGs leave the spine more
unstable, favoring stationary recollimation shocks.
Extending the analysis to a sample of nine nearby Fermi-LAT-detected
MAGN reveals differences between HEGs and LEGs in core brightness
temperatures and variability patterns. HEG cores tend to approach the
inverse-Compton limit and exhibit a higher probability of strong γ-ray
flaring, while LEG cores remain closer to equipartition and display
more
persistent, lower-amplitude emission. Limb-brightening, possibly
indicative of a spine-sheath velocity stratification, is observed in
three of the four LEGs, as well as in the closest HEG, suggesting that
the less frequent detection of this feature in HEGs may be due to their
average larger distances, resulting in insufficient spatial resolution
in VLBI imaging.
The results of this thesis support a unified scenario in which the
accretion mode is a primary driver of jet internal structure,
stability,
and high-energy dissipation. The work provides a framework for future
large-sample radio–γ studies and offers observational constraints
for
relativistic magnetohydrodynamic simulations of disk–jet coupling in
radio-loud AGN.