(Astro)Physics 343 Lecture # 12: active galactic nuclei

Similar documents
Astr 2320 Thurs. April 27, 2017 Today s Topics. Chapter 21: Active Galaxies and Quasars

Guiding Questions. Active Galaxies. Quasars look like stars but have huge redshifts

Galaxies with Active Nuclei. Active Galactic Nuclei Seyfert Galaxies Radio Galaxies Quasars Supermassive Black Holes

Radio Galaxies High resolution observations of radio galaxies often show highly extended emission. Best known case: Cygnus A. Jet.

Active Galactic Nuclei

Black Holes and Active Galactic Nuclei

Vera Genten. AGN (Active Galactic Nuclei)

Active Galactic Nuclei

Active Galaxies & Quasars

A100H Exploring the Universe: Quasars, Dark Matter, Dark Energy. Martin D. Weinberg UMass Astronomy

Lecture 11 Quiz 2. AGN and You. A Brief History of AGN. This week's topics

Astronomy 422! Lecture 7: The Milky Way Galaxy III!

Chapter 19 Galaxies. Hubble Ultra Deep Field: Each dot is a galaxy of stars. More distant, further into the past. halo

Quasars and AGN. What are quasars and how do they differ from galaxies? What powers AGN s. Jets and outflows from QSOs and AGNs

Set 4: Active Galaxies

Active Galaxies & Emission Line Diagnostics

Dark Matter ASTR 2120 Sarazin. Bullet Cluster of Galaxies - Dark Matter Lab

2. Active Galaxies. 2.1 Taxonomy 2.2 The mass of the central engine 2.3 Models of AGNs 2.4 Quasars as cosmological probes.

Part two of a year-long introduction to astrophysics:

A Unified Model for AGN. Ryan Yamada Astro 671 March 27, 2006

Chapter 17. Active Galaxies and Supermassive Black Holes

TEMA 6. Continuum Emission

An Introduction to Radio Astronomy

Extragalactic Radio Sources. Joanne M. Attridge MIT Haystack Observatory

An Introduction to Radio Astronomy

X-ray data analysis. Andrea Marinucci. Università degli Studi Roma Tre

The Black Hole in the Galactic Center. Eliot Quataert (UC Berkeley)

Lecture 9. Quasars, Active Galaxies and AGN

High-Energy Astrophysics

GRB history. Discovered 1967 Vela satellites. classified! Published 1973! Ruderman 1974 Texas: More theories than bursts!

The Classification of Galaxies

Starbursts, AGN, and Interacting Galaxies 1 ST READER: ROBERT GLEISINGER 2 ND READER: WOLFGANG KLASSEN

Quasars ASTR 2120 Sarazin. Quintuple Gravitational Lens Quasar

Chapter 21 Galaxy Evolution. Agenda

Active Galactic Nuclei - Zoology

Schwarzchild Radius. Black Hole Event Horizon 30 km 9 km. Mass (solar) Object Star. Star. Rs = 3 x M (Rs in km; M in solar masses)

High-Energy Astrophysics Lecture 1: introduction and overview; synchrotron radiation. Timetable. Reading. Overview. What is high-energy astrophysics?

Chapter 15 2/19/2014. Lecture Outline Hubble s Galaxy Classification. Normal and Active Galaxies Hubble s Galaxy Classification

Introduction to AGN. General Characteristics History Components of AGN The AGN Zoo

Lecture Outlines. Chapter 24. Astronomy Today 8th Edition Chaisson/McMillan Pearson Education, Inc.

Active galactic nuclei (AGN)

Structure of nuclei of extragalactic radio sources and the link with GAIA

University of California, Santa Barbara Department of Physics

Star systems like our Milky Way. Galaxies

Active Galactic Nuclei-I. The paradigm

Active galaxies. Some History Classification scheme Building blocks Some important results

ASTR 1040 Recitation: Active Galactic Nucleii

Set 4: Active Galaxies

Active Galaxies and Quasars

Bright Quasar 3C 273 Thierry J-L Courvoisier. Encyclopedia of Astronomy & Astrophysics P. Murdin

Quasars and Active Galactic Nuclei (AGN)

The AGN / host galaxy connection in nearby galaxies.

AGN in hierarchical galaxy formation models

The Phenomenon of Active Galactic Nuclei: an Introduction

A. Thermal radiation from a massive star cluster. B. Emission lines from hot gas C. 21 cm from hydrogen D. Synchrotron radiation from a black hole

Observational Evidence of AGN Feedback

Chapter 21 Galaxy Evolution. How do we observe the life histories of galaxies?

Black Holes in Hibernation

ACTIVE GALACTIC NUCLEI: FROM THE CENTRAL BLACK HOLE TO THE GALACTIC ENVIRONMENT

High-Energy Astrophysics Lecture 6: Black holes in galaxies and the fundamentals of accretion. Overview

Active Galactic Nuclei (AGNs): A type of AGNs: Quasars. Whatever is powering these QSO s must be very small!!

An introduction to Active Galactic Nuclei. 1.

Active Galaxies. Lecture Topics. Lecture 24. Active Galaxies. Potential exam topics. What powers these things? Lec. 24: Active Galaxies

Active Galactic Nuclei

(Astro)Physics 343 Lecture # 5: Sun, Stars, and Planets; Fourier Transforms

Physics 343 Lecture # 5: Sun, Stars, and Planets; Bayesian analysis

Powering Active Galaxies

Astronomy 114. Lecture 27: The Galaxy. Martin D. Weinberg. UMass/Astronomy Department

Powering the Universe with Supermassive Black Holes. Steve Ehlert and Paul Simeon

A zoo of transient sources. (c)2017 van Putten 1

Black holes as central engines

Lecture 19: Galaxies. Astronomy 111

Energy Source for Active Galactic Nuclei

Other Galaxy Types. Active Galaxies. A diagram of an active galaxy, showing the primary components. Active Galaxies

BH Astrophys Ch1~2.2. h"p:// h"p://abyss.uoregon.edu/~js/ast123/lectures/lec12.

Radio Loud Black Holes. An observational perspective

Reminders! Observing Projects: Both due Monday. They will NOT be accepted late!!!

Chapter 11 The Formation and Structure of Stars

Today in Astronomy 102: the Galactic center

Physics 343 Lecture # 5: Sun, stars, and planets; (more) statistics

Supermassive Black Holes

Radio emission in clusters of galaxies. An observational perspective

Galaxies and Cosmology

Radio sources. P. Charlot Laboratoire d Astrophysique de Bordeaux

Quasars are supermassive black holes, found in the centers of galaxies Mass of quasar black holes = solar masses

High-Energy Astrophysics

Feeding the Beast. Chris Impey (University of Arizona)

Astronomy 182: Origin and Evolution of the Universe

Evidence for BH: Active Galaxies

Astronomy 210 Final. Astronomy: The Big Picture. Outline

Supermassive Black Holes

Radiative Processes in Astrophysics

CONTENTS AIM OF THE PROJECT. INTRODUCTION: AGNs, XMM-Newton, ROSAT. TECHNIQUES: IDL, SQL, Catalogues RESULTS SUMMARY DESIRED OUTPUTS QUESTIONS

Question 1. Question 2. Correct. Chapter 16 Homework. Part A

Accretion Disks. 1. Accretion Efficiency. 2. Eddington Luminosity. 3. Bondi-Hoyle Accretion. 4. Temperature profile and spectrum of accretion disk

Multi-wavelength Surveys for AGN & AGN Variability. Vicki Sarajedini University of Florida

Osservatorio Astronomico di Bologna, 27 Ottobre 2011

Polarization Studies of Extragalactic Relativistic Jets from Supermassive Black Holes. Iván Agudo

Radio Galaxies. D.Maino. Radio Astronomy II. Physics Dept., University of Milano. D.Maino Radio Galaxies 1/47

Thus Far. Intro / Some Definitions Hubble Classification Components of Galaxies. Specific Galaxy Types Star Formation Clusters of Galaxies

Transcription:

(Astro)Physics 343 Lecture # 12: active galactic nuclei

Schedule for this week Monday & Tuesday 4/21 22: ad hoc office hours for Lab # 5 (you can use the computer in my office if necessary; Sections A and E should let me and Ross know in advance) Thursday 4/24: Lab # 5 due (mailbox, office, or email) Friday 4/25: drive NJ WV

Black holes are (nearly) ubiquitous Elliptical galaxies and spiral galaxies with massive bulges all seem to have massive central black holes, whose masses follow a tight proportionality with velocity dispersion. (Bulgeless disk galaxies do not follow the same relation.) Tremaine et al. (2002)

The Schwarzschild radius As a reminder: a black hole is an object so massive that there is a Schwarzschild radius R S from within with not even light can escape. (This is an example of an event horizon, although not the only example.) R S can be derived by setting the escape velocity equal to c: R S = 2GM/c 2 (This is not a valid relativistic derivation, but it happens to yield the right answer!)

What happens to gas near a black hole? Conservation of angular momentum means gas doesn't fall straight into the Schwarzschild radius. Instead, potential energy ( GMm/r for a particle with mass m and distance r from the black hole) is slowly converted into thermal energy (i.e., heat) due to particle collisions. This is a process known as accretion. What happens next? Broadly speaking, there are two options...

Option # 1: radiatively inefficient accretion The thermal energy can remain in the form of thermal energy (i.e., the accreting gas remains hot), or be converted into kinetic energy (i.e., turbulence/outflow). In either case, little radiation emerges; astronomers refer to these situations as RIAFs (radiatively inefficient accretion flows). The black hole at the center of the Milky Way drives a RIAF!

Option # 1: radiatively efficient accretion The alternative scenario is that a large fraction of the thermal energy is converted to radiation. In this case, we have a radiatively efficient accretion flow, and can observe one or more consequences that mark the center of a galaxy as an active galactic nucleus (AGN; plural = AGN or [ugh...] AGNs ).

AGN in the optical High energy photons emerging from an AGN accretion flow (typically, an accretion disk) can ionize atoms in the surrounding gas. Optically bright AGN are identified as Seyfert nuclei or QSOs (quasistellar objects) depending on L. Courtesy W. Keel.

AGN in the optical: type 1 vs. type 2 Some optically bright AGN show broad lines (> 1000 km/s in width) from ionized gas; others do not. Astronomers refer to these as type 1 and type 2 AGN. Which we see depends on our viewing angle relative to a torus (i.e., doughnut) of cold, dusty molecular gas that can hide a broad line region. Courtesy M. Urry.

AGN in the X ray Sometimes the optical emission from ionized gas is so deeply enshrouded by dust (along all sightlines) that we can't detect an AGN in the optical at all! In such cases, detecting high energy photons directly in the X ray may work better.

AGN in the radio Independent of whether an AGN is type 1 or type 2 in the optical, or whether it shows X ray emission or not, it may be either radio loud or radio quiet. Radio emission is continuum emission due to synchrotron radiation (particles spiralling in a strong magnetic field... although precisely which particles is not always clear!).

Two categories of radio galaxies Among radio loud objects, we have (1) Fanaroff Riley type I ( FRI ) objects that are core dominated (2) Fanaroff Riley type II ( FRII ) objects that are lobe dominated

VLBI mapping of radio galaxies Very long baseline interferometry (VLBI) can be used to study the central parts of AGN: the emission is so strong on small scales that even intercontinental baselines can detect it!

We can watch jets evolve in real time! Example: VLBI observations of 3C279 reveal that blobs of radio emitting plasma move 25 light years in projection on the sky over the course of seven years of observations.

Superluminal motion: an optical illusion Motion along the line of sight accounts for the apparent velocity > c.

Galaxy clusters Galaxy clusters have most of their (ordinary, baryonic) mass in the form of hot intracluster gas. Why doesn't this cool, flow to the center, and form stars in the central elliptical?

AGN feedback Deep X ray imaging of many clusters (here, the Perseus Cluster) shows shells and bubbles. We think these were produced in past radio loud events: a jet in the central elliptical turns on when the black hole is fed, driving away further fuel until it shuts itself off.

Quiz

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback