Complex narrow-line Seyfert 1s: high spin or high inclination?

Complex narrow-line Seyfert 1s: high spin or high inclination?

Complex narrow-line Seyfert 1s (NLS1s), such as 1H 0707−495, differ from simple NLS1s like PG 1244+026 by showing stronger broad spectral features at Fe K and larger amplitude flux variability. These are correlated: the strongest Fe K features are seen during deep dips in the light curves of complex...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society Vol. 448; no. 3; pp. 2245 - 2259
Main Authors: Gardner, Emma, Done, Chris
Format: Journal Article
Language:English
Published: London Oxford University Press 11-04-2015
Subjects:
Accretion disks
Black holes
Clumps
Correlation analysis
Dipping
Discs
Disks
Flux
Iron
Relativistic effects
Star & galaxy formation
X-ray astronomy
X-ray sources
galaxies: individual: PG 1244+026
galaxies: Seyfert
black hole physics
accretion, accretion discs
galaxies: individual: 1H 0707−495
X-rays: galaxies
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Summary:Complex narrow-line Seyfert 1s (NLS1s), such as 1H 0707−495, differ from simple NLS1s like PG 1244+026 by showing stronger broad spectral features at Fe K and larger amplitude flux variability. These are correlated: the strongest Fe K features are seen during deep dips in the light curves of complex NLS1s. There are two competing explanations for these features, one where a compact X-ray source on the spin axis of a highly spinning black hole approaches the horizon and the consequent strong relativistic effects focus the intrinsic flux on to the inner edge of a thin disc, giving a dim, reflection-dominated spectrum. The other is that the deep dips are caused by complex absorption by clumps close to the hard X-ray source. The reflection-dominated model is able to reproduce the very short 30 s soft lag from reverberation seen in the complex NLS1 1H 0707−495. However, it does not explain the characteristic switch to hard lags on longer time-scales. Instead, a full model of propagating fluctuations coupled to reverberation can explain the switch in the simple NLS1 PG 1244+026 using a low spin black hole. However, PG 1244+026 has a longer reverberation lag of ∼200 s. Here we extend the successful propagation–reverberation model for the simple NLS1 PG 1244+026 to include the effect of absorption from clumps in a turbulent region above the disc. The resulting occultations of the inner accretion flow can introduce additional hard lags when relativistic effects are taken into account. This dilutes the soft lag from reverberation and shifts it to higher frequencies, making a smooth transition between the 200 s lags seen in simple NLS1s to the 30 s lags in complex NLS1s. These two classes of NLS1 could then be determined by inclination angle with respect to a clumpy, probably turbulent, failed wind structure on the disc.
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content type line 23
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/stv168