THE RELATIONSHIP BETWEEN LUMINOSITY AND BLACK HOLE MASSES IN ACTIVE GALAXIES: USING NEAR-INFRARED LINE Do-hyeong Kim, Myungshin Im Astronomy Program, Department.

Slides:

Advertisements

Similar presentations

High Redshift Quasar Survey Survey Science Group Workshop, 2013 High1 Resort Yiseul Jeon, Myungshin Im, W.-K. Park, J. H. Kim, M. Karouzos, J.-W. Kim,

Advertisements

Marianne Vestergaard Dark Cosmology Centre, Copenhagen First Galaxies, Quasars, and GRBs, June Determining Black Hole Masses in Distant Quasars.

1 Reverberation Mapping of the Broad-Line Region Bradley M. Peterson The Ohio State University Collaborators: M. Bentz, S. Collin, K. Denney, L.-B. Desroches,

COEVOLUTION OF SUPERMASSIVE BLACK HOLES AND THEIR HOST GALAXIES...OR: CHICKEN, EGG OR BOTH? Jari Kotilainen Tuorla Observatory, University of Turku, Finland.

Motivation 40 orbits of UDF observations with the ACS grism Spectra for every source in the field. Good S/N continuum detections to I(AB) ~ 27; about 30%

UNCERTAINTIES ON THE BLACK HOLE MASSES AND CONSEQUENCES FOR THE EDDINGTON RATIOS Suzy Collin Observatoire de Paris-Meudon, France Collaborators: T. Kawaguchi.

Molecular gas in the z~6 quasar host galaxies Ran Wang National Radio Astronomy Observatory Steward Observatory, University of Atrizona Collaborators:

Supermassive Black Holes in Radio-loud AGNs

Weighing black holes in radio-loud AGNs

On the geometry of broad emission region in quasars Roberto Decarli Turin - May, 20 th, 2008 Università degli Studi dell’Insubria Dipartimento di Fisica.

The Size, Structure & Ionization of the Broad-Line Region in NGC 3227 and NGC 4051 Nick Devereux (ERAU) Emily Heaton (ERAU) May 22 nd, 2013 Naples, Italy.

Optimal Photometry of Faint Galaxies Kenneth M. Lanzetta Stony Brook University.

1 Black Hole Masses from Reverberation Mapping Bradley M. Peterson The Ohio State University Collaborators: M. Bentz, S. Collin, K. Dasyra, K. Denney,

The Dusty Torus of NGC1068 Literature Study for the Bachelor Research Project: Bas Nefs Maarten Zwetsloot.

Kovačević, J., Popovic, L. Č., Kollatschny, W., Saikia, P.

Jelena Kova č evi ć Astronomical Observatory Belgrade.

Quasars and Massive Black Holes Stephen Fine. Outline What is a quasar How do we study quasar black holes Why do we study quasar black holes What are.

Dust and Stellar Emission of Nearby Galaxies in the KINGFISH Herschel Survey Ramin A. Skibba Charles W. Engelbracht, et al. I.

M77 (NGC 1068) By: Ryan Desautels. Messier 77 A Brief History A Brief History General Information General Information Galactic Information Galactic Information.

Radio Astronomy And The Spiral Structure Of The Milky Way Jess Broderick Supervisor: Dr George Warr.

The Dwarf Starburst Galaxy NGC 1705 : New H II Region Element Abundances & Reddening Variations Near the Center NGC 1705 is a nearby dwarf starburst galaxy.

Characterizing activity in AGN with X-ray variability Rick Edelson.

The BH mass of nearby QSOs A comparison of the bulge luminosity and virial methods M. Labita, A. TrevesUniversità dell’Insubria, Como, Italy R. FalomoINAF,

On the inconsistency between the SMBH Mass Function from velocity dispersion and luminosity E. Tundo 1,2, M. Bernardi 2, R. K. Sheth 2 J. B. Hyde 2, A.

1 High-z galaxy masses from spectroastrometry Alessio Gnerucci Department of Physics and Astronomy University of Florence 13/12/2009- Obergurgl Collaborators:

An Accretion Disc Model for Quasar Optical Variability An Accretion Disc Model for Quasar Optical Variability Li Shuang-Liang Li Shuang-Liang Shanghai.

1 Reverberation Mapping of Active Galactic Nuclei Planets To Cosmology: Essential Science In Hubble's Final Years 4 May 2004 Bradley M. Peterson The Ohio.

1 The Fundamental Plane Relationship of Astrophysical Black Holes Ran Wang Supervisor: Xuebing Wu Peking University Ran Wang Supervisor: Xuebing Wu Peking.

The Evolution of Quasars and Massive Black Holes “Quasar Hosts and the Black Hole-Spheroid Connection”: Dunlop 2004 “The Evolution of Quasars”: Osmer 2004.

A spectroscopic survey of the 3CR sample of radio galaxies Authors: Sara Buttiglione (SISSA - Trieste), Alessandro Capetti (INAF – Osservatorio Astronomico.

Modern Quasar SEDs Zhaohui Shang （ Tianjin Normal University ） Kunming, Feb

W.Kollatschny, Zetzl, Z.Alvi.  Information about the Structure and the Kinematics of the inner most region surrounding an AGN can be revealed by analyzing.

A New Cosmological Distance Measure Using AGN X-Ray Variability Stefano Bianchi The X-ray Universe June, 2014, Dublin, Ireland Fabio La Franca,

Results from AGN multiple wavelength observations and the importance of monitoring campaigns 24 – 28 April 2012, Andrevlje, Republic of Serbia G. La Mura.

The Fundamental Plane of Astrophysical Black Holes WU Xue-Bing (Peking University) Collaborators: WANG Ran (PKU) KONG Minzhi (NAOC)

Central Engine of AGN Xi’ian October 2006 Black Hole Mass Measurements with Adaptive Optic Assisted 3D-Spectroscopy Courtesy ESO Guia Pastorini Osservatorio.

Scaling relations of spheroids over cosmic time: Tommaso Treu (UCSB)

IAU Jong-Hak Woo Univ. California Santa Barbara Collaborators: Tommaso Treu (UCSB), Matt Malkan (UCLA), & Roger Blandford (Stanford) Cosmic Evolution.

The Fe II lines in AGN spectra Jelena Kovačević 1, Luka Č. Popović 1 and Milan S. Dimitrijević 1 1 Astronomical Observatory Volgina 7, Belgrade,

Super-massive Black Holes of Quasars at World’s End Myungshin Im (Seoul National University) Youichi Ohyama (ISAS & ASIAA) Minjin Kim, Induk Lee, H. M.

Jelena Kovačević 1, Luka Č. Popović 1, Milan S. Dimitrijević 1, Payaswini Saikia 1 1 Astronomical Observatory Belgrade, Serbia.

Extreme soft X-ray emission from the broad-line quasar REJ R.L.C. Starling 1*, E.M. Puchnarewicz 1, K.O. Mason 1 & E. Romero- Colmenero 2 1 Mullard.

University of Leicester, UK X-ray and Observational Astronomy (XROA) Group Estelle Pons - The X-ray Universe June 2014.

Galactic Astronomy 銀河物理学特論 I Lecture 2-1: Active galaxies and super massive black holes in the local universe Seminar: Gultekin et al. 2009, ApJ, 698,

Deborah Dultzin-Hacyan

The Differences in the SEDs of Type 1 and Type 2 AGNs: Contributions from starbursts Xue-Bing Wu Collaborator: Ran Wang (Astronomy Department, Peking University)

Joint formation and evolution of SMBHs and their host galaxies: How do the Quasar-Spheroid correlations change with the Cosmic Time? A. Treves Università.

Active Galactic Nuclei Chapter 25 Revised Active Galactic Nuclei Come in several varieties; Starburst Nuclei – Nearby normal galaxies with unusually.

Astrophysics from Space Lecture 6: Supermassive black holes Prof. Dr. M. Baes (UGent) Prof. Dr. C. Waelkens (KUL) Academic year

Radio Galaxies part 4. Apart from the radio the thin accretion disk around the AGN produces optical, UV, X-ray radiation The optical spectrum emitted.

Piecing Together the X-ray Background: The Bolometric Output of AGN Ranjan Vasudevan Supervisor: Prof. A. C. Fabian.

Unification -- 2 Where next?. Recap of current status Emission from nuclear relativistic jets is important in all radio-loud objects. Axisymmetric dust.

Spectral Energy Distributions of obscured AGN E. Lusso, A. Comastri, E. Treister, D. Sanders, H. Hao, M. Elvis, C. Vignali, R. Gilli, G.Zamorani, M. Brusa,

YOUR LOGO The FUS(FIRST-UKIDSS-SDSS) RED Quasar Survey Dohyeong Kim 서울대학교 천문학과 김도형

AKARI Spectroscopic Study of the Rest-frame Optical Spectra of Quasars at 3.5 < z < 6.5 Hyunsung Jun¹, Myungshin Im¹, Hyung Mok Lee², and the QSONG team.

Nature of Broad Line Region in AGNs Xinwen Shu Department of Astronomy University of Science and Technology of China Collaborators: Junxian Wang (USTC)

Lecture 16 Measurement of masses of SMBHs: Sphere of influence of a SMBH Gas and stellar dynamics, maser disks Stellar proper motions Mass vs velocity.

Black Holes in the Universe Myungshin Im Astronomy Program, CEOU/Department of Physics & Astronomy, Seoul National University.

How to Better Weigh a Black Hole and Other Adventures in Quasar Physics Michael Brotherton.

The black hole fundamental plane: revisit with a larger sample of radio and X-ray emitting broad line AGNs Zhao-Yu Li Astronomy Department, Peking University.

Biases in Virial Black Hole Masses: an SDSS Perspective

Xiaohui Fan University of Arizona June 21, 2004

Refining the Radius–Luminosity Relationship for Active Galactic Nuclei

The Stellar Population of Metal−Poor Galaxies at z~1

Jelena Kovačević Dojčinović, Luka Č. Popović

Demographics of SDSS Quasars in Two-Dimension

Black Hole Winds: the case of PDS 456

Balmer Lines as a Probe of Physical Processes in the Broad Line Region

Center for Astrophysics

Janie K. Hoormann University of Queensland 23 April 2019

Presentation transcript:

THE RELATIONSHIP BETWEEN LUMINOSITY AND BLACK HOLE MASSES IN ACTIVE GALAXIES: USING NEAR-INFRARED LINE Do-hyeong Kim, Myungshin Im Astronomy Program, Department of Physics and Astronomy, Seoul National University Do-hyeong Kim, Myungshin Im Astronomy Program, Department of Physics and Astronomy, Seoul National University INTRODUCTION Mass of the supermassive black hole is a key quantity in understanding the evolution of active galactic nuclei and their host galaxies. The FWHM of a broad line gives the velocity of the broad line region, the mass of the SMBHs within the BLR can be derived from the combination of the size and the velocity. The single epoch(Greene Ho 2005: using Halpha& Hbeta) mass measurment technique is very powerful, but it is not without any disadvantage. About 70% of AGNs are found to be dusty(Refs), and in such systems, inaccurate measurement of dust extinction can easily lead to the underestimate of the black hole mass. For example, a red AGNs can easily have E(B-V) = 2 (Glickman et al.), in which case the Hbeta and Halpha line fluxes are suppressed by a factor of 1000 and 100 respectively. NIR Hydrogen lines such as the Paalpha and Pabeta are much less affected by the dust, with the suppression in line flux by a factor of only 2.3 and 4.7 respectively. In this paper, we will derive the mass estimators based on the NIR Hydrogen lines, in the hopes that such a relation can provide a way to estimate Mblack in dusty, red AGNs, in a more robust way. DATA To derive the BH mass estimators based on NIR Hydrogen lines, we will use the data compiled by Landt et al. (2008). Landt et al. (2008) obtained NIR spectra, well-known, nearby AGNs, providing a measured quantities such as the line fluxes and the line widths of various NIR Hydrogen lines at wavelength < 2 μm. In this wavelength range, the most notable lines are Paalpha and Pabeta, and we will use these lines to construct the mass estimators. The Landt et al. (20008) sample is sorted to several subsets for which (i) reveberation mapping Mbh are available; (ii) single epoch Mbh are available in the literatures; and (iii) Halpha or Hbeta single epoch line luminosity and widths are available so that Mbh measurements is possible. DATA To derive the BH mass estimators based on NIR Hydrogen lines, we will use the data compiled by Landt et al. (2008). Landt et al. (2008) obtained NIR spectra, well-known, nearby AGNs, providing a measured quantities such as the line fluxes and the line widths of various NIR Hydrogen lines at wavelength < 2 μm. In this wavelength range, the most notable lines are Paalpha and Pabeta, and we will use these lines to construct the mass estimators. The Landt et al. (20008) sample is sorted to several subsets for which (i) reveberation mapping Mbh are available; (ii) single epoch Mbh are available in the literatures; and (iii) Halpha or Hbeta single epoch line luminosity and widths are available so that Mbh measurements is possible. WHY PASCHEN LINE? We have some standard basis for decide emission line. 1. Strong emission 2. Don’t have near by other strong emission 3. Near-infrared line The results of this standard basis are Paschen line. WHY PASCHEN LINE? We have some standard basis for decide emission line. 1. Strong emission 2. Don’t have near by other strong emission 3. Near-infrared line The results of this standard basis are Paschen line. RESULT The correlation Paschen line emission with mass of black hole make next equation. The correlation Balmer line emission with Paschen line emission make next equation. RESULT The correlation Paschen line emission with mass of black hole make next equation. The correlation Balmer line emission with Paschen line emission make next equation. < SUMMARY & FUTURE WORKS >  We present the equation that correlation mass of black hole with Paschen line emission.  For more reliable equation, we need more sample. So recently, we estimate other FWHM& Flux of Paschen line by using data of Glikman.2005 < SUMMARY & FUTURE WORKS >  We present the equation that correlation mass of black hole with Paschen line emission.  For more reliable equation, we need more sample. So recently, we estimate other FWHM& Flux of Paschen line by using data of Glikman.2005 EXISTING RESULT The mass of the SMBHs within the BLR can be derived from the combination of the size and the velocity. The reverberation mapping method, however, requires a long term spectrophotometric monitoring which is very time-consuming. Typical time scale for the variability of AGNs is of oder of years, and for a massive SMBHs, the time scale can be longer than 10 years (Kaspi et al. 2004). For this reason, single-epoch mass measurement methods have been commonly used as an alternative way, which use the empirical relation between the broad line region size from the reveberation mapping and the spectral properties such as the 5100 continuum flux (Kaspi et al 2000) and the Halpha and Hbeta luminositis (Greene Ho 2005). EXISTING RESULT The mass of the SMBHs within the BLR can be derived from the combination of the size and the velocity. The reverberation mapping method, however, requires a long term spectrophotometric monitoring which is very time-consuming. Typical time scale for the variability of AGNs is of oder of years, and for a massive SMBHs, the time scale can be longer than 10 years (Kaspi et al. 2004). For this reason, single-epoch mass measurement methods have been commonly used as an alternative way, which use the empirical relation between the broad line region size from the reveberation mapping and the spectral properties such as the 5100 continuum flux (Kaspi et al 2000) and the Halpha and Hbeta luminositis (Greene Ho 2005). CORRELATION A good correlation between the Balmer line widths and Paschen line widths are already shown in Landt et al. (2008). A good correlations between the Paschen lines and the Balmer lines is a good indication that the construction of the mass estimator based on the Paschen lines is feasible. CORRELATION A good correlation between the Balmer line widths and Paschen line widths are already shown in Landt et al. (2008). A good correlations between the Paschen lines and the Balmer lines is a good indication that the construction of the mass estimator based on the Paschen lines is feasible. (Green& Ho 2005)