328 research outputs found
Modeling the optical/UV polarization while flying around the tilted outflows of NGC 1068
Recent modeling of multi-waveband spectroscopic and maser observations
suggests that the ionized outflows in the nuclear region of the archetypal
Seyfert-2 galaxy NGC 1068 are inclined with respect to the vertical axis of the
obscuring torus. Based on this suggestion, we build a complex reprocessing
model of NGC 1068 for the optical/UV band. We apply the radiative transfer code
STOKES to compute polarization spectra and images. The effects of electron and
dust scattering and the radiative coupling occurring in the inner regions of
the multi-component object are taken into account and evaluated at different
polar and azimuthal viewing angles. The observed type-1/type-2 polarization
dichotomy of active galactic nuclei is reproduced. At the assumed observer's
inclination toward NGC 1068, the polarization is dominated by scattering in the
polar outflows and therefore it indicates their tilting angle with respect to
the torus axis. While a detailed analysis of our model results is still in
progress, we briefly discuss how they relate to existing polarization
observations of NGC 1068.Comment: To appear in the proceedings of the meeting "The Central Kiloparsec
in Galactic Nuclei" held in Bad Honnef (Germany) from August 29th to
September 2nd 201
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Line Shifts, Broad-Line Region Inflow, And The Feeding Of Active Galactic Nuclei
Velocity-resolved reverberation mapping suggests that the broad-line regions (BLRs) of active galactic nuclei (AGNs) can have significant net inflow. We use the STOKES radiative transfer code to show that electron and Rayleigh scattering off the BLR and torus naturally explains the blueshifted profiles of high-ionization lines and the ionization dependence of the blueshifts. This result is insensitive to the geometry of the scattering region. If correct, then this model resolves the long-standing conflict between the absence of outflow implied by velocity-resolved reverberation mapping and the need for outflow if the blueshifting is the result of obscuration. The accretion rate implied by the inflow is sufficient to power the AGN. We suggest that the BLR is part of the outer accretion disk and that similar magnetohydrodynamic processes are operating. In the scattering model, the blueshifting is proportional to the accretion rate so high-accretion-rate AGNs will show greater high-ionization line blueshifts, as is observed. Scattering can lead to systematically too high black hole mass estimates from the C IV line. We note many similarities between narrow-line region (NLR) and BLR blueshiftings, and suggest that NLR blueshiftings have a similar explanation. Our model explains the higher blueshifts of broad absorption line QSOs if they are more highly inclined. Rayleigh scattering from the BLR and torus could be more important in the UV than electron scattering for predominantly neutral material around AGNs. The importance of Rayleigh scattering versus electron scattering can be assessed by comparing line profiles at different wavelengths arising from the same emission-line region.US National Science Foundation AST 03-07912, AST 08-03883Space Telescope Science Institute AR-09926.01GEMINI-CONICYT Fund of Chile 32070017FONDECYT of Chile 1120957French GdR PCHECenter for Theoretical Astrophysics (CTA) through Czech Ministry of Education, Youth and Sports LC06014ANR-11-JS56-013-01Astronom
The case for inflow of the broad-line region of active galactic nuclei
The high-ionization lines of the broad-line region (BLR) of thermal active
galactic nuclei (AGNs) show blueshifts of a few hundred km/s to several
thousand km/sec with respect to the low-ionization lines. This has long been
thought to be due to the high-ionization lines of the BLR arising in a wind of
which the far side of the outflow is blocked from our view by the accretion
disc. Evidence for and against the disc-wind model is discussed. The biggest
problem for the model is that velocity-resolved reverberation mapping
repeatedly fails to show the expected kinematic signature of outflow of the
BLR. The disc-wind model also cannot readily reproduce the red side of the line
profiles of high-ionization lines. The rapidly falling density in an outflow
makes it difficult to obtain high equivalent widths. We point out a number of
major problems with associating the BLR with the outflows producing broad
absorption lines. An explanation which avoids all these problems and satisfies
the constraints of both the line profiles and velocity-resolved
reverberation-mapping is a model in which the blueshifting is due to scattering
off material spiraling inwards with an inflow velocity of half the velocity of
the blueshifting. We discuss how recent reverberation mapping results are
consistent with the scattering-plus-inflow model but do not support a disc-wind
model. We propose that the anti-correlation of the apparent redshifting of
H with the blueshifting of CIV is a consequence of contamination of the
red wings of H by the broad wings of [O III].Comment: 15 pages, 15 figures. To appear in special issue of Astrophysics and
Space Science, "Spectral Line Shapes in Astrophysics
Constraints on a strong X-ray flare in the Seyfert galaxy MCG-6-30-15
We discuss implications of a strong flare event observed in the Seyfert
galaxy MCG-6-30-15 assuming that the emission is due to localized magnetic
reconnection. We conduct detailed radiative transfer modeling of the
reprocessed radiation for a primary source that is elevated above the disk. The
model includes relativistic effects and Keplerian motion around the black hole.
We show that for such a model setup the observed time-modulation must be
intrinsic to the primary source. Using a simple analytical model we then
investigate time delays between hard and soft X-rays during the flare. The
model considers an intrinsic delay between primary and reprocessed radiation,
which measures the geometrical distance of the flare source to the reprocessing
sites. The observed time delays are well reproduced if one assumes that the
reprocessing happens in magnetically confined, cold clouds.Comment: 4 pages, 2 figures, proceedings of a talk given at the symposium 238
at the IAU General Assembly 200
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