Ellipticals. Ellipticals. Huge mass range:

Similar documents
Epicycles the short form.

Galaxy Luminosity Function. Galaxy Luminosity Function. Schechter Function. Schechter Function by environment. Schechter (1976) found that

1.4 Galaxy Light Distributions

12.1 Elliptical Galaxies

An Introduction to Galaxies and Cosmology. Jun 29, 2005 Chap.2.1~2.3

ASTRON 449: Stellar (Galactic) Dynamics. Fall 2014

This week at Astro Lecture 06, Sep 13, Pick up PE#6. Please turn in HW#2. HW#3 is posted

Normal Galaxies ASTR 2120 Sarazin

1 Shapes of elliptical galaxies

Spiral Structure. m ( Ω Ω gp ) = n κ. Closed orbits in non-inertial frames can explain the spiral pattern

Galaxy Morphology. - a description of the structure of galaxies

midterm exam thurs june 14 morning? evening? fri june 15 morning? evening? sat june 16 morning? afternoon? sun june 17 morning? afternoon?

GALACTIC DYNAMICS AND INTERSTELLAR MATTER

Galaxies. Hubble's measurement of distance to M31 Normal versus other galaxies Classification of galaxies Ellipticals Spirals Scaling relations

ASTR 200 : Lecture 25. Galaxies: internal and cluster dynamics

Surface Photometry Quantitative description of galaxy morphology. Hubble Sequence Qualitative description of galaxy morphology

Survey of Astrophysics A110

The Milky Way. Finding the Center. Milky Way Composite Photo. Finding the Center. Milky Way : A band of and a. Milky Way

Ch. 25 In-Class Notes: Beyond Our Solar System

Part two of a year-long introduction to astrophysics:

Galaxy photometry. The surface brightness of a galaxy I(x) is the amount of light on the sky at a particular point x on the image.

Dark Matter: Observational Constraints

Whittle : EXTRAGALACTIC ASTRONOMY 5. SPIRAL GALAXIES

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

Galaxies. With a touch of cosmology

HW#4 is due next Monday Part of it is to read a paper and answer questions about what you read If you have questions, ask me!

Epicyclic Orbits. Epicyclic motion produces a spiral pattern (see figure, Sparke & Gallagher, and

Lecture Two: Observed Properties of Galaxies

Hubble s Law. Tully-Fisher relation. The redshift. λ λ0. Are there other ways to estimate distances? Yes.

A100 Exploring the Universe: Evolution of Galaxies. Martin D. Weinberg UMass Astronomy

The visible constituents of the Universe: Non-relativistic particles ( baryons ): Relativistic particles: 1. radiation 2.

The Milky Way Galaxy

Galaxy clusters. Dept. of Physics of Complex Systems April 6, 2018

A100 Exploring the Universe: Evolution of Galaxies. Martin D. Weinberg UMass Astronomy

This Week in Astronomy

AS1001:Extra-Galactic Astronomy

A100H Exploring the Universe: Evolution of Galaxies. Martin D. Weinberg UMass Astronomy

Elliptical galaxies. But are they so simple? Detailed studies reveal great complexity:

View of the Galaxy from within. Lecture 12: Galaxies. Comparison to an external disk galaxy. Where do we lie in our Galaxy?

The Milky Way - Chapter 23

Lecture 19: Galaxies. Astronomy 111

Chapter 19 Reading Quiz Clickers. The Cosmic Perspective Seventh Edition. Our Galaxy Pearson Education, Inc.

Three Major Components

Lecture 30. The Galactic Center

Spatial distribution of stars in the Milky Way

The Classification of Galaxies

Dark Matter: Observational Constraints

This week at Astro 3303

A100H Exploring the Universe: Discovering Galaxies. Martin D. Weinberg UMass Astronomy

Stellar Dynamics and Structure of Galaxies

ASTRO504 Extragalactic Astronomy. 2. Classification

Gravitational Efects and the Motion of Stars

Chapter 15 Galaxies and the Foundation of Modern Cosmology

Tour of Galaxies. Sgr A* VLT in IR + adaptive optics. orbits. ASTR 1040 Accel Astro: Stars & Galaxies VLT IR+AO

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

Galaxies: Structure, formation and evolution

Spheroidal (Elliptical) Galaxies MBW chap 13, S+G ch 6!

Chapter 25: Galaxy Clusters and the Structure of the Universe

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

ASTR 101 Introduction to Astronomy: Stars & Galaxies

Our Galaxy. Milky Way Galaxy = Sun + ~100 billion other stars + gas and dust. Held together by gravity! The Milky Way with the Naked Eye

Galaxies: Structure, Dynamics, and Evolution. Elliptical Galaxies (II)

Dates of the courses. Sterrenstelsels en Cosmologie. Docent: M. Franx, kamer 425. Usually on Monday, 11:15-13:00, but also on Thursdays 13:45-15:30

Astronomy 113. Dr. Joseph E. Pesce, Ph.D. Distances & the Milky Way. The Curtis View. Our Galaxy. The Shapley View 3/27/18

Astronomy 113. Dr. Joseph E. Pesce, Ph.D. Dr. Joseph E. Pesce, Ph.D.

1. Overview. Theory lags behind and there are many unsolved problems, including the nature of dark matter and dark energy.

Dwarf Elliptical Galaxies Nelson Caldwell. Encyclopedia of Astronomy & Astrophysics P. Murdin

Our Galaxy. We are located in the disk of our galaxy and this is why the disk appears as a band of stars across the sky.

4/18/17. Our Schedule. Revisit Quasar 3C273. Dark Matter in the Universe. ASTR 1040: Stars & Galaxies

The Next 2-3 Weeks. Important to read through Chapter 17 (Relativity) before I start lecturing on it.

The Great Debate: The Size of the Universe (1920)

Large-Scale Structure

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

ASTR 101 Introduction to Astronomy: Stars & Galaxies

Peculiar (Interacting) Galaxies

Astro 242. The Physics of Galaxies and the Universe: Lecture Notes Wayne Hu

Chapter 14 The Milky Way Galaxy

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

Distance Measuring Techniques and The Milky Way Galaxy

ASTRO 310: Galactic & Extragalactic Astronomy Prof. Jeff Kenney

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

I. Basic Goals. Most galaxies are in approx. equilibrium in the present-day universe.

11/8/18. Tour of Galaxies. Our Schedule

Star systems like our Milky Way. Galaxies

Large Scale Structure

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

Extra Gal 9: Photometry & Dynamics

ASTR 200 : Lecture 22 Structure of our Galaxy

2 Galaxy morphology and classification

Black Holes in Hibernation

Astro 1050 Fri. Apr. 14, 2017

ASTR 1120 General Astronomy: Stars & Galaxies

Galaxies. The majority of known galaxies fall into one of three major classes: spirals (78 %), ellipticals (18 %) and irregulars (4 %).

Structure of the Milky Way. Structure of the Milky Way. The Milky Way

SKINAKAS OBSERVATORY. Astronomy Projects for University Students PROJECT GALAXIES

ASTR 1120 General Astronomy: Stars & Galaxies

Nature of Dark Matter

GALAXIES. I. Morphologies and classification 2. Successes of Hubble scheme 3. Problems with Hubble scheme 4. Galaxies in other wavelengths

Neutron Stars. Neutron Stars and Black Holes. The Crab Pulsar. Discovery of Pulsars. The Crab Pulsar. Light curves of the Crab Pulsar.

LECTURE 1: Introduction to Galaxies. The Milky Way on a clear night

Transcription:

Ellipticals Huge mass range: Dwarf spheroidal (Leo I) Dwarf spheroidals: 1 7-1 8 M Blue compact dwarfs: ~1 9 M Dwarf ellipticals: 1 7-1 9 M Normal (giant) ellipticals: 1 8-1 13 M cd galaxies in cluster centers: 1 13-1 1 M Dwarf ellipticals M3, NGC 5 cd (NGC 3311) Giant E (NGC 17) Ellipticals cd r 1/ Hubble s law Io R 1 Ro HST images Modified Hubble s law devaucouleurs R 1/ law usually fits radial surface brightness distribution + others o o 3/ 1 R Ro I e I 1 1/ R 3.33 R e 1 Diverges, but at least is projection of simple 3D distribution: I r) 1 r Ro 1

True shapes requires statistical analysis Oblate = pancakes Prolate = footballs [CO figs 5., 5.3] True shapes requires statistical analysis Lower luminosity rotationally supported (V rot / ) ~ /(1- ) Higher L pressure supported (V rot / ) << 1 Ellipticity = 1 b/a CO pgs. 988-989 Curve expected for galaxies that are flattened by rotation (i.e. have isotropic random velocity dispersions) = low L ellipticals x = spiral bulges high L ellipticals Rotationally Supported Observed Spectrum K star (V/) * =.7 E galaxy = K star convolved with Gaussian velocity distribution of stars. From Binney & Tremaine, Galactic Dynamics

Statistics of = (1- b/a) Oblate, prolate spheroids can t fit the observed distribution. Summing over wide range of true values of would fill in the dip at obs =. Triaxial spheroids can fit. Nearly oblate triaxial spheroids seem best. Oblate, true =.7 Prolate, true =.5 observed 3 P ( obs ) 1...6.8 1. Triaxial, Axis ratios 1:.8:.3 3 P ( obs ) 1 From Binney & Merrifield, Galactic Astronomy...6.8 1. Other evidence for triaxial systems Isophotal twists Kinematics (star motions) From Binney & Merrifield, Galactic Astronomy 3

Orbits in E galaxies From Binney & Tremaine, Galactic Dynamics Some families of non-closed orbits in a mildly triaxial potential. E galaxies are transparent, but % still have some dust lanes Even if complete star formation at t=, stars must subsequently have lost gas. Detected by: X-rays (Brehmsstrahlung): 1 8-1 1 M H I emission lines: 1 7-1 9 M H II emission lines: 1-1 5 M But gas can be lost by Supernova-driven winds Ram pressure stripping

The Virial Theorem [CO.] For gravitationally bound systems in equilibrium Time-averaged kinetic energy = - ½ time-averaged potential energy. E = total energy U = potential energy. K = kinetic energy. E = K + U Can show from Newton s 3 laws + law of gravity: ½ (d I/dt ) -K= U where I = m i r i = moment of inertia. Time average < d I/dt > =, or at least ~. Virial theorem -<K> = <U> <K> = - ½ <U> <E> = <K> + <U> <E> = ½ <U> Sorry I had left out the ½ when I showed this slide in class. Virial Theorem K = -U 3 GM U 5 R K = ½ M<v > = 3/ M < r > Mass determinations from absorption line widths [CO 5.1] M virial 5R r G See pp. 959-96, + Sect.. Applied to nuclei of spirals presence of massive black holes Also often applied to E galaxies Galaxy clusters M3 5

Virial Theorem K = -U <v > = 3 <v r > K = ½ M<v > = 3/ M < r > 5R r M virial G See pp. 959-96, + Sect.. Applied to nuclei of spirals presence of massive black holes Also often applied to E galaxies Galaxy clusters Mass determinations from absorption line widths 3 GM U 5 R Observed Spectrum Fourier Transforms K star E galaxy = K star convolved with Gaussian velocity distribution of stars. Star Galaxy Ratio Gaussian fit: Convolution turns into multiplication in F.T. space. F.T. of a Gaussian is a Gaussian. I e 1 3.33 I e = surface brightness at R e L e = luminosity within R e 1/ 1 Faber-Jackson relation: L e ~ R R e (Absolute magnitude) 6

Mass-Luminosity relationships Faber-Jackson relation: L e ~ mag/arcsec D n - correlation. D n = diameter within which <I> =.75 B Fundamental plane in log R e, <I> e, log space R e = scale factor in R 1/ law <I> e = mean surface brightness within R e Different from I e! Intro. to Principle Component Analysis: astro-ph/99579 I e 1 1/ R 3.33 R e 1 CO give different coefficients??? r e 1. I -.8 e L.65 r.65 e From Binney & Merrifield, Galactic Astronomy Distribution of galaxy types Total number of galaxies Dense regions (cluster centers) predominantly ellipticals. Field galaxies predominantly spirals. On average, roughly even split between E and S. Fraction of population S S E Dressler 198 Log (Projected surface density of galaxies) 7

Schechter Luminosity Function (L)dL = L e -L/L* dl (M)dM = 1.(+1)M e 1.(M * -M) dm The Milky Way is an L * galaxy. [CO 5.36] Log (galaxies/mpc 3 ) [BM.1] -1-3 -5-7 - - -18-16 more M luminous B more luminous Problem.15: Assuming that the highest velocity stars are near the escape speed, estimate the mass of the M.W. Correct: v esc = v circ + max v pec = + 65 ~ 3 km s -1. K.E. = Potential Energy mv esc GmM R Wrong: follow example.3.1 and calculate mass required to hold star in circular orbit with v = 3 km s -1 Rvesc M G Problem.36: Point mass M at center of MW + mass distributed with density (r) 1/r. (a) Show that M r = kr+m. Correct: r r C M r M ( r) dvol( r) M r dr M C r Black Hole Wrong: anything that does not show that you realized that you need to integrate over ( r) dvol( r) Rv M G esc r 8

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