Dusty Winds in Active Galactic Nuclei: Reconciling Observations with Models

This letter presents a revised radiative transfer model for the infrared (IR) emission of active galactic nuclei (AGN). While current models assume that the IR is emitted from a dusty torus in the equatorial plane of the AGN, spatially resolved observations indicate that the majority of the IR emission from 100 pc in many AGN originates from the polar region, contradicting classical torus models. The new model CAT3D-WIND builds upon the suggestion that the dusty gas around the AGN consists of an inflowing disk and an outflowing wind. Here, it is demonstrated that (1) such disk+wind models cover overall a similar parameter range of observed spectral features in the IR as classical clumpy torus models, e.g. the silicate feature strengths and mid-IR spectral slopes, (2) they reproduce the 3-5{\mu}m bump observed in many type 1 AGN unlike torus models, and (3) they are able to explain polar emission features seen in IR interferometry, even for type 1 AGN at relatively low inclination, as demonstrated for NGC3783. These characteristics make it possible to reconcile radiative transfer models with observations and provide further evidence of a two-component parsec-scaled dusty medium around AGN: the disk gives rise to the 3-5{\mu}m near-IR component, while the wind produces the mid-IR emission. The model SEDs will be made available for download.

[1]  K. Meisenheimer,et al.  Mid-infrared interferometry of 23 AGN tori: On the significance of polar-elongated emission , 2016, 1602.05592.

[2]  D. M. Crenshaw,et al.  DETERMINING INCLINATIONS OF ACTIVE GALACTIC NUCLEI VIA THEIR NARROW-LINE REGION KINEMATICS. I. OBSERVATIONAL RESULTS* , 2013 .

[3]  Florentin Millour,et al.  Mapping the radial structure of AGN tori , 2011, 1110.4290.

[4]  R. I. Davies,et al.  OUTFLOWS FROM ACTIVE GALACTIC NUCLEI: KINEMATICS OF THE NARROW-LINE AND CORONAL-LINE REGIONS IN SEYFERT GALAXIES, , 2011, 1107.3140.

[5]  Wolfgang J. Duschl,et al.  Theory of accretion disks--2 , 1989 .

[6]  J. R. Houck,et al.  The Distribution of Silicate Strength in Spitzer Spectra of AGNs and ULIRGs , 2006, astro-ph/0612509.

[7]  MPE,et al.  DUST IN THE POLAR REGION AS A MAJOR CONTRIBUTOR TO THE INFRARED EMISSION OF ACTIVE GALACTIC NUCLEI , 2013, 1306.4312.

[8]  H. Netzer,et al.  Hot graphite dust and the infrared spectral energy distribution of active galactic nuclei , 2011, 1110.5326.

[9]  M. Kishimoto,et al.  The dusty heart of nearby active galaxies , 2010 .

[10]  M. A. Malkan,et al.  Spectral Energy Distributions of Active Galactic Nuclei between 0.1 and 100 Microns , 1986 .

[11]  Heidelberg,et al.  Towards a physical model of dust tori in Active Galactic Nuclei Radiative transfer calculations for a hydrostatic torus model , 2005, astro-ph/0504105.

[12]  R. Antonucci,et al.  QUANTIFYING THE ANISOTROPY IN THE INFRARED EMISSION OF POWERFUL ACTIVE GALACTIC NUCLEI , 2011, 1105.0429.

[13]  S. Gallagher,et al.  Investigating the structure of the windy torus in quasars , 2015, 1505.04219.

[14]  Heidelberg,et al.  Three-dimensional radiative transfer models of clumpy tori in Seyfert galaxies , 2008, 0802.2604.

[15]  University of Crete,et al.  TORUS AND ACTIVE GALACTIC NUCLEUS PROPERTIES OF NEARBY SEYFERT GALAXIES: RESULTS FROM FITTING INFRARED SPECTRAL ENERGY DISTRIBUTIONS AND SPECTROSCOPY , 2011, 1105.2368.

[16]  Martin Elvis A Structure for Quasars , 2000 .

[17]  J. Krolik,et al.  RADIATION-DRIVEN OUTFLOWS FROM AND RADIATIVE SUPPORT IN DUSTY TORI OF ACTIVE GALACTIC NUCLEI , 2015, 1511.00333.

[18]  W. Duschl,et al.  Resolving the mid-infrared cores of local Seyferts , 2009, 0902.2777.

[19]  E. Phinney Dusty Disks and the Infrared Emission from AGN , 1989 .

[20]  A. Königl,et al.  DISK-DRIVEN HYDROMAGNETIC WINDS AS A KEY INGREDIENT OF ACTIVE GALACTIC NUCLEI UNIFICATION SCHEMES , 1994 .

[21]  G. Weigelt,et al.  The innermost region of AGN tori: implications from the HST/NICMOS type 1 point sources and near-IR reverberation , 2007, 0709.0431.

[22]  P. Gandhi,et al.  THE SUBARCSECOND MID-INFRARED VIEW OF LOCAL ACTIVE GALACTIC NUCLEI. III. POLAR DUST EMISSION , 2016, 1603.02710.

[23]  P. Hopkins,et al.  THREE-DIMENSIONAL RADIATIVE TRANSFER CALCULATIONS OF RADIATION FEEDBACK FROM MASSIVE BLACK HOLES: OUTFLOW OF MASS FROM THE DUSTY “TORUS” , 2012, 1204.0063.

[24]  G. Weigelt,et al.  The dusty heart of nearby active galaxies - I. High-spatial resolution mid-IR spectro-photometry of Seyfert galaxies , 2010, 1003.0920.

[25]  K. Wada RADIATION-DRIVEN FOUNTAIN AND ORIGIN OF TORUS AROUND ACTIVE GALACTIC NUCLEI , 2012, 1208.5272.

[26]  Walter Jaffe,et al.  Resolving the obscuring torus in NGC 1068 with the power of infrared interferometry: revealing the inner funnel of dust , 2009, 0901.1306.

[27]  Walter Jaffe,et al.  Infrared interferometry and AGNs: Parsec-scale disks and dusty outflows , 2016, Astronomical Telescopes + Instrumentation.

[28]  F. Millour,et al.  VLTI/AMBER observations of the Seyfert nucleus of NGC 3783 , 2012, 1204.6122.

[29]  P. Roche,et al.  A mid-infrared spectroscopic atlas of local active galactic nuclei on sub-arcsecond resolution using GTC/CanariCam , 2015, 1510.02631.

[30]  D. Proga,et al.  PARSEC-SCALE ACCRETION AND WINDS IRRADIATED BY A QUASAR , 2015, 1512.03854.

[31]  R. Maiolino,et al.  The relation between AGN hard X-ray emission and mid-infrared continuum from ISO spectra: Scatter and unification aspects , , 2004, astro-ph/0402082.

[32]  K. Wada OBSCURING FRACTION OF ACTIVE GALACTIC NUCLEI: IMPLICATIONS FROM RADIATION-DRIVEN FOUNTAIN MODELS , 2015, 1509.00576.

[33]  J. M. Rodríguez Espinosa,et al.  THE INFRARED NUCLEAR EMISSION OF SEYFERT GALAXIES ON PARSEC SCALES: TESTING THE CLUMPY TORUS MODELS , 2009, Proceedings of the International Astronomical Union.

[34]  U. Toronto,et al.  SWEEPING AWAY THE MYSTERIES OF DUSTY CONTINUOUS WINDS IN ACTIVE GALACTIC NUCLEI , 2012, 1202.4681.

[35]  A. Dorodnitsyn,et al.  AGN OBSCURATION THROUGH DUSTY, INFRARED-DOMINATED FLOWS. II. MULTIDIMENSIONAL, RADIATION-HYDRODYNAMICS MODELING , 2011, 1111.2103.

[36]  Heidelberg,et al.  The dusty torus in the Circinus galaxy: a dense disk and the torus funnel , 2013, 1312.4534.

[37]  Robert Antonucci,et al.  Unified models for active galactic nuclei and quasars , 1993 .

[38]  O. Shemmer,et al.  STAR FORMATION BLACK HOLE GROWTH AND DUSTY TORI IN THE MOST LUMINOUS AGNS AT Z = 2–3.5 , 2015, 1511.07876.

[39]  Konrad Tristram,et al.  PARSEC-SCALE DUST EMISSION FROM THE POLAR REGION IN THE TYPE 2 NUCLEUS OF NGC 424 , 2012, 1206.4307.

[40]  S. Hoenig,et al.  The dusty heart of nearby active galaxies. II. From clumpy torus models to physical properties of dust around active galactic nuclei , 2009, 0909.4539.

[41]  W. Duschl,et al.  The subarcsecond mid-infrared view of local active galactic nuclei – II. The mid-infrared–X-ray correlation , 2015, 1508.05065.

[42]  Revisiting the infrared spectra of active galactic nuclei with a new torus emission model , 2005, astro-ph/0511428.