High Redshift QUASAR HOST Galaxies (Growing Galaxies with Monstrous Middles) Jill Bechtold, University of Arizona Kim K. McLeod, Wellesley College Undergraduates:

Slides:

Advertisements

Similar presentations

CDFS SA12 SA15 Morphologies & Star Formation Histories of Massive Galaxies at z > 1.3 P. McCarthy & The GDDS Team Venice 2006.

Advertisements

The W i d e s p r e a d Influence of Supermassive Black Holes Christopher Onken Herzberg Institute of Astrophysics Christopher Onken Herzberg Institute.

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

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

The History of Light: How Stars Formed in Galaxies Kai Noeske European Space Agency/ Space Telescope Science Institute Hubble Science Briefing, 1 Mar 2012.

February 9, 11:00 am. The unusually bright centers found in some galaxies are called 1.active galactic nuclei. 2.starbursts. 3.halos. 4.supermassive.

Spitzer Reveals Activities of Supermassive Black Holes in Elliptical Galaxies Qiusheng Gu Nanjing University in collaboration with J.-S. Huang (CfA), G.

QUASAR HOSTS ( Growing Galaxies with Monstrous Middles) Kim K. McLeod, Wellesley College “Hostesses” past and present: Frannie D’Arcangelo Melissa Rice.

Quasar Host Galaxies: Growing up with Monstrous Middles Kim K. McLeod, Wellesley College George Rieke, U. of Arizona Lisa Storrie-Lombardi, IPAC Brian.

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

Extragalactic AO Science James Larkin AOWG Strategic Planning Meeting September 19, 2004.

Alt.Aperturer 0 (m)FWHM(")  0 (")  0 (sec) 4 kmCFHT 3.8m km2.4 m~ ~600~5 35km10 m~ ~600~5 h (km)P (mbars)T (K)  (gm m.

Tidal Disruptions of Stars by Supermassive Black Holes Suvi Gezari (Caltech) Chris Martin & GALEX Team Bruno Milliard (GALEX) Stephane Basa (SNLS)

The Life History of Galaxies and Black Holes

QUASARS Monsters of the ancient Universe Professor Jill Bechtold Steward Observatory Tucson Amateur Astronomers, Dec. 6, 2002.

Weak-Lensing selected, X-ray confirmed Clusters and the AGN closest to them Dara Norman NOAO/CTIO 2006 November 6-8 Boston Collaborators: Deep Lens Survey.

Galaxies with Active Nuclei Chapter 17. You can imagine galaxies rotating slowly and quietly making new stars as the eons pass, but the nuclei of some.

Downsizing & Galaxy Formation 2 nd Mitchell Symposium - April 2006 P. McCarthy OCIW Gemini Deep Deep Survey Team.

AGN and Quasar Clustering at z= : Results from the DEEP2 + AEGIS Surveys Alison Coil Hubble Fellow University of Arizona Chandra Science Workshop.

THE MODERATELY LARGE SCALE STRUCTURE OF QUASARS

PX269 Galaxies Part 4: Galactic nuclei 4.1 Active galaxies.

Class 24 : Supermassive black holes Recap: What is a black hole? Case studies: M87. M106. MCG What’s at the center of the Milky Way? The demographics.

3C 186 A Luminous Quasar in the Center of a Strong Cooling Core Cluster at z>1 Aneta Siemiginowska CfA Tom Aldcroft (CfA) Steve Allen (Stanford) Jill Bechtold.

Class 25 : Active galactic nuclei Discovery of AGN (3C 273). What are AGN? Radio galaxies. AGN and colliding galaxies.

Hubble Space Telescope Images of Post-Starburst Quasars Michael S. Brotherton, S. Cales, R. Ganguly, Z. Shang (University of Wyoming) G. Canalizo (University.

Discovery of Galaxy Clusters Around Redshift 1 Deborah Haarsma, Calvin GLCW, June 1, 2007.

Cosmological evolution of Black Hole Spins Nikos Fanidakis and C. Baugh, S. Cole, C. Frenk NEB-XIII, Thessaloniki, June 4-6, 2008.

Dusty star formation at high redshift Chris Willott, HIA/NRC 1. Introductory cosmology 2. Obscured galaxy formation: the view with current facilities,

Lecture 9: Quasars & “Active” Galaxies Astronomy 5: The Formation and Evolution of the Universe Sandra M. Faber Spring Quarter 2007 UC Santa Cruz.

Quasars and Other Active Galaxies

Galaxies Live in Clusters Hickson Fornax. Coma Virgo.

Black holes: do they exist?

This is the Local Group of galaxies, about 45 galaxies within about 1 Mpc of the Milky Way. Most are dwarf-elliptical or iregular. A distance of one million.

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

Wide Field Imagers in Space and the Cluster Forbidden Zone Megan Donahue Space Telescope Science Institute Acknowledgements to: Greg Aldering (LBL) and.

Quasars, black holes and galaxy evolution Clive Tadhunter University of Sheffield 3C273.

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

The Black-Hole – Halo Mass Relation and High Redshift Quasars Stuart Wyithe Avi Loeb (The University of Melbourne) (Harvard University) Fan et al. (2001)

Active Galaxies Definition – –Amount of Energy –Type of Energy Non-thermal Polarized Other characteristics –Emission spectra Hydrogen – Balmer series &

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

Local SMBH and Galaxy Correlations M bul / M BH  800 M BH -σ* relation (Gebhardt et al. 2000, Ferrarese & Merritt 2000) (e.g. Kormendy & Richstone 1995,

The Fundamental Plane of Quasars Timothy Scott Hamilton NASA/GSFC, National Research Council …Putting the “fun” back in “Fundamental Plane”!

Galaxies with Active Nuclei Chapter 14:. Active Galaxies Galaxies with extremely violent energy release in their nuclei (pl. of nucleus).  “active galactic.

Quasars and Active Galactic Nuclei

Z-FOURGE - the FourStar Galaxy Evolution Survey Status Report at the 1.3-year mark.

Active Galaxies and Supermassive Black Holes Chapter 17.

Discovery of a 12 Billion Solar Mass Black Hole at Redshift 6.3 and its Challenge to the Black Hole/Galaxy Coevolution at Cosmic Dawn Xue-Bing WU Kavli.

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

Quasars and Other Active Galaxies

USING LOW POWER RADIO GALAXIES AS BEACONS FOR CLUSTERS AT 1

Black Holes and the Evolution of Galaxies…. Summary Quasars and Evolution: the universe becomes interesting How we do it: things invisible to see. Demographics:

The History of Active Galaxies A.Barger, P. Capak, L. Cowie, RFM, A. Steffen, and Y. Yang Active Galaxies (AKA quasars, Seyfert galaxies etc) are radiating.

KASI Galaxy Evolution Journal Club A Massive Protocluster of Galaxies at a Redshift of z ~ P. L. Capak et al. 2011, Nature, in press (arXive: )

The GOOD NICMOS Survey (GNS): Observing Massive Galaxies at z > 2 Christopher J. Conselice (University of Nottingham) with Asa Bluck, Ruth Gruethbacher,

Star Formation History of the Hubble Ultra Deep Field Rodger Thompson Steward Observatory University of Arizona.

Black Holes in Globular Clusters Karl Gebhardt (UT)

Evolution of massive binary black holes Qingjuan Yu Princeton University July 21, 2002.

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.

Studies of QSO host galaxies

Chandra Science Highlight

NICMOS Measurements of the Near Infrared Background

서울대학교 물리천문학부 천문학전공 초기우주천체연구단 윤용민

Quasars, Active Galaxies, and super-massive black holes

Mike Brotherton: HST Images of Post-Starburst Quasars

Extra-galactic blank field surveys with CCAT

Note that the following lectures include animations and PowerPoint effects such as fly ins and transitions that require you to be in PowerPoint's Slide.

Black Holes in the Deepest Extragalactic X-ray Surveys

Galaxies With Active Nuclei

Galaxies With Active Nuclei

Presentation transcript:

High Redshift QUASAR HOST Galaxies (Growing Galaxies with Monstrous Middles) Jill Bechtold, University of Arizona Kim K. McLeod, Wellesley College Undergraduates: Frannie D’Arcangelo Melissa Rice Rebecca Stoll Angela Bivens (Thanks to K. Luhman, E. Olszewski, M. Mateo for telescope time and observing)

QUASAR EVOLUTION Quasar activity peaked about 10 – 12 billion years ago

Black hole v. Spheroid Mass The “Kormendy Relation” M bh = M Gal Kormendy & Richstone 1995 Magorrian et al 1998 Haring & Rix 2004

QUASAR EVOLUTION Kormendy Relation only feasible for the very closest quasars

Hubble Space Telescope NICMOS images Quasar host galaxies McLeod et al

QUASAR EVOLUTION Quasar host galaxies studied out to z~1

QUASAR EVOLUTION What about these guys? What about these guys?

Taking the big step to high-z: PANIC! (Persson’s Auxilliary Nasmyth Infrared Camera) Bechtold and McLeod have been using Magellan (6.5m) to image z=4 quasars in the near-IR Also used Magellan + Classicam; Gemini-N + NIRI

Why PANIC at Magellan? Observing Strategy: Require deep observations large sample (10’s of quasars minimum; radio loud/radio quiet etc) near-IR or longward to sample rest frame optical for host galaxy excellent image quality well-defined PSF for PSF subtraction (1) What observing band? > For z=5-6, Ks is short of the 4000A break in the host galaxy  Need space telescope to observe longward of Ks, but Spitzer is too small (IRAC: 1.2 arcsec/pixel) > For z=4, Ks and H straddle the 4000A break K-H  photo-z of candidate hosts

Observing Strategy, continued (2)Why not use NICMOS on HST? At K-band PANIC beats NICMOS on HST, with better image quality PANIC: arcsec/pixel NICMOS: arcsec/pixel PANIC has bigger FOV  comparison PSF stars simultaneously 6.5m telescope  deeper faster HST time oversubscribed; hard to get big sample e.g. Ridgeway ApJ 550, z~2-3 hosts Kukula MNRAS 326, z~2 hosts Suggested result: hosts of radio-quiet quasars are 2-4 times less massive at z=2 than z= 0.2

Observing Strategy, continued (3)Why not use AO? e.g. Croom ApJ 606, quasars observed with Gemini-N, z~2 FWHM ~ 0.12 – 0.25 arcsec; PANIC: FWHM at Ks, routine Z=4 quasars are rare; hard to find ones near natural guide stars FOV small, variable PSF across the field

Z=4 quasars are all very luminous, so have huge black holes compared to black holes studied locally. If they follow the Kormendy Relation, then the host galaxies should be HUGE, and easy to see.

Growing up with a monster in the middle Kauffmann & Haehnelt 2000 Hierarchical structure formation: black holes are fueled, and galaxies grow, through mergers Z=0.4 Z=3

How do we know the black hole mass? Observed spectrum depends on M bh and m accretion (1)FWHM of emission lines (assume Keplerian velocity; radius scaled from reverberation mapping ) + L(UV continuum) (2) Fit IR to X-ray continuum spectral energy distributions from Sobolewska ApJ,

from Bechtold ApJ, 588, 119

PANIC Observations 1024^2 Rockwell Near-IR HgCdTe Camera So far, 23 Quasars observed with z=4 at Ks ½ night per image follow up H band on 3 host candidates More time end of January Extend to quasar environment study

PANIC at z=4: Stay tuned

For now… The End