Differential interferometry of QSO broad-line regions – I. Improving the reverberation mapping model fits and black hole mass estimates

Reverberation mapping (RM) estimates the size and kinematics of broad-line regions (BLR) in quasars and type I AGNs. It yields size–luminosity relation to make QSOs standard cosmological candles, and mass–luminosity relation to study the evolution of black holes and galaxies. The accuracy of these relations is limited by the unknown geometry of the BLR clouds distribution and velocities. We analyse the independent BLR structure constraints given by super-resolving differential interferometry. We developed a three-dimensional BLR model to compute all differential interferometry and RM signals. We extrapolate realistic noises from our successful observations of the QSO 3C 273 with AMBER on the VLTI. These signals and noises quantify the differential interferometry capacity to discriminate and measure BLR parameters including angular size, thickness, spatial distribution of clouds, local-to-global and radial-to-rotation velocity ratios, and finally central black hole mass and BLR distance. A Markov Chain Monte Carlo model-fit, of data simulated for various VLTI instruments, gives mass accuracies between 0.06 and 0.13?dex, to be compared to 0.44?dex for RM mass–luminosity fits. We evaluate the number of QSOs accessible to observe with current (AMBER), upcoming (GRAVITY) and possible (OASIS with new generation fringe trackers) VLTI instruments. With available technology, the VLTI could resolve more than 60 BLRs, with a luminosity range larger than four decades, sufficient for a good calibration of RM mass–luminosity laws, from an analysis of the variation of BLR parameters with luminosity.

[1]  T. Treu,et al.  GEOMETRIC AND DYNAMICAL MODELS OF REVERBERATION MAPPING DATA , 2011, 1101.4952.

[2]  Western Michigan University,et al.  A near-infrared relationship for estimating black hole masses in active galactic nuclei , 2013, 1303.1923.

[3]  Brandon C. Kelly,et al.  Are the Variations in Quasar Optical Flux Driven by Thermal Fluctuations , 2009 .

[4]  Determining Central Black Hole Masses in Distant Active Galaxies and Quasars. II. Improved Optical and UV Scaling Relationships , 2006, astro-ph/0601303.

[5]  Brendon J. Brewer,et al.  Modelling reverberation mapping data – II. Dynamical modelling of the Lick AGN Monitoring Project 2008 data set , 2013, 1311.6475.

[6]  Antoine Labeyrie,et al.  Stellar Interferometry Methods , 1978 .

[7]  Romain G. Petrov,et al.  Signal-to-noise ratio in differential speckle interferometry , 1986 .

[8]  Gerd Weigelt,et al.  VLTI/AMBER differential interferometry of the broad-line region of the quasar 3C273 , 2014, Other Conferences.

[9]  Bradley M. Peterson,et al.  The Radius-Luminosity Relationship for Active Galactic Nuclei: The Effect of Host-Galaxy Starlight on Luminosity Measurements , 2006, 0812.2283.

[10]  Gerd Weigelt,et al.  Possible evidence for a common radial structure in nearby AGN tori , 2008, 0812.1964.

[11]  A. Treves,et al.  On the geometry of broad emission region in quasars , 2008, 0804.1875.

[12]  T. Treu,et al.  THE MASS OF THE BLACK HOLE IN Arp 151 FROM BAYESIAN MODELING OF REVERBERATION MAPPING DATA , 2011, 1104.4794.

[13]  K. Hofmann,et al.  AMBER : a near infrared focal instrument for the VLTI , 2005, astro-ph/0507398.

[14]  B. M. Peterson,et al.  Central Masses and Broad-Line Region Sizes of Active Galactic Nuclei. II. A Homogeneous Analysis of a Large Reverberation-Mapping Database , 2004, astro-ph/0407299.

[15]  Paul S. Smith,et al.  Reverberation Measurements for 17 Quasars and the Size-Mass-Luminosity Relations in Active Galactic Nuclei , 1999 .

[16]  Margarita Karovska,et al.  Quasar Parallax: A Method for Determining Direct Geometrical Distances to Quasars , 2002 .

[17]  Systematic effects in measurement of black hole masses by emission-line reverberation of active galactic nuclei: Eddington ratio and inclination , 2006, astro-ph/0603460.

[18]  W. Welsh,et al.  Echo images of broad-line regions in active Galactic nuclei , 1991 .

[19]  K. Korista,et al.  The broad emission-line region: the confluence of the outer accretion disc with the inner edge of the dusty torus , 2012, 1207.6339.

[20]  R. J. de Kok,et al.  DETECTION OF MOLECULAR ABSORPTION IN THE DAYSIDE OF EXOPLANET 51 PEGASI b? , 2013, 1302.6242.

[21]  N. Ross,et al.  The C iv linewidth distribution for quasars and its implications for broad-line region dynamics and virial mass estimation , 2010, 1005.5287.

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

[23]  Romain G. Petrov,et al.  Colour‐differential interferometry for the observation of extrasolar planets , 2006 .

[24]  B. Peterson,et al.  The Near-Infrared Broad Emission Line Region of Active Galactic Nuclei. I. The Observations , 2007, 0708.1083.

[25]  A. Myers,et al.  Constraining the quasar population with the broad-line width distribution , 2008, 0807.1155.

[26]  India,et al.  THE 2013 RELEASE OF CLOUDY , 2013, 1302.4485.

[27]  Jeffrey A. Meisner,et al.  The Nova Fringe Tracker: a second-generation cophasing facility for up to six telescopes at the VLTI , 2012, Other Conferences.

[28]  Suvendu Rakshit,et al.  AGN BLR structure, luminosity and mass from combined reverberation mapping and optical interferometry observations , 2014, Astronomical Telescopes and Instrumentation.

[29]  J. Krolik Systematic Errors in the Estimation of Black Hole Masses by Reverberation Mapping , 2000, astro-ph/0012134.

[30]  T. Treu,et al.  COSMIC EVOLUTION OF BLACK HOLES AND SPHEROIDS. IV. THE MBH–Lsph RELATION , 2009, 0911.4107.

[31]  D. N. Okhmat,et al.  THE STRUCTURE OF THE BROAD-LINE REGION IN ACTIVE GALACTIC NUCLEI. I. RECONSTRUCTED VELOCITY-DELAY MAPS , 2012, 1210.2397.

[32]  T. Treu,et al.  THE LICK AGN MONITORING PROJECT: THE MBH–σ* RELATION FOR REVERBERATION-MAPPED ACTIVE GALAXIES , 2010, 1004.0252.

[33]  Berkeley,et al.  THE LICK AGN MONITORING PROJECT: VELOCITY-DELAY MAPS FROM THE MAXIMUM-ENTROPY METHOD FOR Arp 151 , 2010, 1007.0781.

[34]  C. D. Laney,et al.  THE LICK AGN MONITORING PROJECT 2011: DYNAMICAL MODELING OF THE BROAD-LINE REGION IN Mrk 50 , 2012, The Astrophysical Journal.

[35]  Bradley M. Peterson,et al.  REVERBERATION MAPPING OF ACTIVE GALACTIC NUCLEI , 1993 .

[36]  K. Hofmann,et al.  First spectro-interferometric survey of Be stars I. Observations and constraints on the disk geometry and kinematics , 2011, 1111.2487.

[37]  Brendon J. Brewer,et al.  Modelling reverberation mapping data – I. Improved geometric and dynamical models and comparison with cross-correlation results , 2014, 1407.2941.

[38]  T. Davis,et al.  A NEW COSMOLOGICAL DISTANCE MEASURE USING ACTIVE GALACTIC NUCLEI , 2011, 1109.4632.

[39]  C. S. Kochanek,et al.  AN ALTERNATIVE APPROACH TO MEASURING REVERBERATION LAGS IN ACTIVE GALACTIC NUCLEI , 2010, 1008.0641.

[40]  Jonathan R Goodman,et al.  Ensemble samplers with affine invariance , 2010 .

[41]  C. Peng,et al.  PRECISE BLACK HOLE MASSES FROM MEGAMASER DISKS: BLACK HOLE–BULGE RELATIONS AT LOW MASS , 2010, 1007.2851.

[42]  M. Goad,et al.  The Effect of a Variable Anisotropic Continuum Source upon the Broad Emission Line Profiles and Responses , 1996 .

[43]  P. T. O'Brien,et al.  Response functions as diagnostics of the broad-line region in active galactic nuclei – II. Anisotropic line emission , 1994 .

[44]  Astronomy,et al.  THE RADIUS–LUMINOSITY RELATIONSHIP FOR ACTIVE GALACTIC NUCLEI: THE EFFECT OF HOST-GALAXY STARLIGHT ON LUMINOSITY MEASUREMENTS. II. THE FULL SAMPLE OF REVERBERATION-MAPPED AGNs , 2008, 0812.2283.

[45]  Daniel Foreman-Mackey,et al.  emcee: The MCMC Hammer , 2012, 1202.3665.

[46]  R. Blandford,et al.  Are AGN broad emission lines formed by discrete clouds? Analysis of Keck high‐resolution spectroscopy of NGC 4151 , 1998, astro-ph/9801012.

[47]  P. Padovani,et al.  UNIFIED SCHEMES FOR RADIO-LOUD ACTIVE GALACTIC NUCLEI , 1995, astro-ph/9506063.

[48]  M. Schoeller,et al.  The central dusty torus in the active nucleus of NGC 1068 , 2004, Nature.

[49]  R. Blandford,et al.  Keck high-resolution spectroscopy of Mrk 335: constraints on the number of emitting clouds in the broad-line region , 1997 .

[50]  Gerd Weigelt,et al.  A diversity of dusty AGN tori - Data release for the VLTI/MIDI AGN Large Program and first results for 23 galaxies , 2013, 1307.2068.

[51]  Julien Borgnino,et al.  Spectrally resolved Michelson stellar interferometry. I. Exact formalism in the multispeckle mode. , 1999 .

[52]  Christopher F. McKee,et al.  Reverberation mapping of the emission line regions of Seyfert galaxies and quasars. , 1982 .

[53]  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.

[54]  M. C. Bentz,et al.  REVERBERATION MAPPING MEASUREMENTS OF BLACK HOLE MASSES IN SIX LOCAL SEYFERT GALAXIES , 2010, 1006.4160.

[55]  Takeo Minezaki,et al.  THE LICK AGN MONITORING PROJECT: BROAD-LINE REGION RADII AND BLACK HOLE MASSES FROM REVERBERATION MAPPING OF Hβ , 2009, The Astrophysical Journal.

[56]  A. Glindemann,et al.  Perspective of imaging in the mid-infrared at the Very Large Telescope Interferometer , 2012, Other Conferences.

[57]  Bradley M. Peterson,et al.  Supermassive Black Holes in Active Galactic Nuclei. II. Calibration of the Black Hole Mass-Velocity Dispersion Relationship for Active Galactic Nuclei , 2004 .

[58]  David Mouillet,et al.  AMBER : Instrument description and first astrophysical results Special feature AMBER , the near-infrared spectro-interferometric three-telescope VLTI instrument , 2007 .

[59]  G. Weigelt,et al.  Probing the innermost dusty structure in AGN with mid-IR and near-IR interferometers , 2012, 1204.4871.