The Star‐forming Torus and Stellar Dynamical Black Hole Mass in the Seyfert 1 Nucleus of NGC 3227

Davies, R. I.; Thomas, Jens; Genzel, R.; Sánchez, Francisco; Tacconi, L. J.; Sternberg, A.; Eisenhauer, F.; Abuter, R.; Saglia, R.; Bender, R.

doi:10.1086/504963

Cited by 210 publications

(272 citation statements)

References 95 publications

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“…Given the size of the broad line region and its velocity, mass is given by the virial theorem M B H = fR B LR v 2 f w hm (f represents the unknown BLR geometry and v f w hm is the velocity width of the broad emission line). In general, masses estimated from the scaling relations are accurate to ∼ 0.4 dex (Vestergaard et al 2006, Shen et al 2008 and agree with local AGN masses from dynamical estimators (Davies et al 2006, Onken et al 2007 and the M B H -σ * correlation (Onken et al 2004, Greene et al 2006. Together the mass and the intrinsic accretion luminosity L I can be used to describe the fueling rate of an AGN in terms of the Eddington ratio, L I /L E dd , where L E dd = 1.26 × 10 38 (M/M ) erg s −1 .…”

Section: Black Hole Masses and Accretion Limitssupporting

confidence: 69%

AGN and Host Galaxies in the COSMOS Survey

2010

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Abstract. The Cosmological Evolution Survey (COSMOS) is a unique tool for studying low level AGN activity and the co-evolution of galaxies and supermassive black holes. COSMOS involves the largest contiguous region of the sky ever imaged by HST; it includes very complete multiwavelength coverage, and the largest joint samples of galaxy and AGN redshifts in any deep survey. The result is a search for AGN with low black hole mass, low accretion rates, and levels of obscuration that can remove them from optical surveys. A complete census of intermediate mass black holes at redshifts of 1 to 3 is required to tell the story of the co-evolution of galaxies and their embedded, and episodically active, black holes.

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Section: Black Hole Masses and Accretion Limitssupporting

confidence: 69%

AGN and Host Galaxies in the COSMOS Survey

2010

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“…Below 4000 Å, UVOT measures extra emission that can not be fitted with an accretion disk. According to Davies et al (2006), the central 30 parsecs show remainders of starburst emission accounting for 20% to 60% of the galaxy's bolometric luminosity. We therefore add a starburst template (Kinney et al 1996) below 4000 Å.…”

Section: Multiwavelength Data Analysismentioning

confidence: 99%

A variable-density absorption event in NGC 3227 mapped withSuzakuandSwift

Markowitz

Krauß

Miniutti

et al. 2015

A&A

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Context. The morphology of the circumnuclear gas accreting onto supermassive black holes in Seyfert galaxies remains a topic of much debate. As the innermost regions of active galactic nuclei (AGN) are spatially unresolved, X-ray spectroscopy, and in particular line-of-sight absorption variability, is a key diagnostic to map out the distribution of gas. Aims. Observations of variable X-ray absorption in multiple Seyferts and over a wide range of timescales indicate the presence of clumps/clouds of gas within the circumnuclear material. Eclipse events by clumps transiting the line of sight allow us to explore the properties of the clumps over a wide range of radial distances from the optical/UV broad line region (BLR) to beyond the dust sublimation radius. Time-resolved absorption events have been extremely rare so far, but suggest a range of density profiles across Seyferts. We resolve a weeks-long absorption event in the Seyfert NGC 3227. Methods. We examine six Suzaku and 12 Swift observations from a 2008 campaign spanning five weeks. We use a model accounting for the complex spectral interplay of three absorbers with different levels of ionization. We perform time-resolved spectroscopy to discern the absorption variability behavior. We also examine the IR to X-ray spectral energy distribution (SED) to test for reddening by dust. Results. The 2008 absorption event is due to moderately-ionized (log ξ ∼ 1.2-1.4) gas covering 90% of the line of sight. We resolve the density profile to be highly irregular, in contrast to a previous symmetric and centrally-peaked event mapped with RXTE in the same object. The UV data do not show significant reddening, suggesting that the cloud is dust-free. Conclusions. The 2008 campaign has revealed a transit by a filamentary, moderately-ionized cloud of variable density that is likely located in the BLR, and possibly part of a disk wind.

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“…1. With JWST and an AO-fed GSMT/E-ELT, we will just be able access this regime and map the emission of hot dust (Tristram et al 2007) and hot molecular hydrogen (Davies et al 2006;Hicks & Malkan 2008). On larger spatial scales, JWST, GSMT/E-ELT, and ALMA could be used to map out the distribution and kinematics of ionized and molecular gas for a large and complete sample of AGN and suitable control sample (e.g., Fathi et al 2006;Storchi-Bergmann et al 2007;Riffel et al 2008;Davies et al 2009a;Lindt-Krieg et al 2008;Schinnerer et al 2000).…”

Section: Fueling the Black Holementioning

confidence: 99%

The Co-Evolution of Galaxies and Black Holes: Current Status and Future Prospects

Heckman

2009

Proc. IAU

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Abstract. I begin by summarizing the evidence that there is a close relationship between the evolution of galaxies and supermassive black holes. They evidently share a common fuel source, and feedback from the black hole may be needed to suppress over-cooling in massive galaxies.I then review what we know about the co-evolution of galaxies and black holes in the modern universe (z < 1). We now have a good documentation of which black holes are growing (the lower mass ones), where they are growing (in the less massive early-type galaxies), and how this growth is related in a statistical sense to star formation in the central region of the galaxy. The opportunity in the next decade will be to use the new observatories to undertake ambitious programs of 3-D imaging spectroscopy of the stars and gas in order to understand the actual astrophysical processes that produce the demographics we observe. At high redshift (z > 2), the most massive black holes and the progenitors of the most massive galaxies are forming. Here, we currently have a tantalizing but fragmented view of their co-evolution. In the next decade, the huge increase in sensitivity and discovery power of our observatories will enable us to analyze the large, complete samples we need to achieve robust and clear results.

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The Star‐forming Torus and Stellar Dynamical Black Hole Mass in the Seyfert 1 Nucleus of NGC 3227

Cited by 210 publications

References 95 publications

AGN and Host Galaxies in the COSMOS Survey

AGN and Host Galaxies in the COSMOS Survey

A variable-density absorption event in NGC 3227 mapped withSuzakuandSwift

The Co-Evolution of Galaxies and Black Holes: Current Status and Future Prospects

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