Please pick up problem set #3. Median score = 87. Recitation session: Today, 4:30 – 5:30 pm. 4054 McPherson (Prof subbing for TA)

Slides:

Advertisements

Similar presentations

Supernovae and nucleosynthesis of elements > Fe Death of low-mass star: White Dwarf White dwarfs are the remaining cores once fusion stops Electron degeneracy.

Advertisements

Gravitation Newton’s Law of Gravitation Superposition Gravitation Near the Surface of Earth Gravitation Inside the Earth Gravitational Potential Energy.

Slide 1 Andromeda galaxy M31Milky Way galaxy similar to M31.

March 15 & 18. Do Now: Take one and complete; take a clicker! Also, turn in your Ch 13 HW questions! Tonight’s HW: p. 181, #21 – 26, & 29; – Write.

Dark Matter, Dark Energy, and the Fate of the Universe.

The Fate of the Universe. The cosmological principle The simplest universes is: Homogenous – the same everywhere you go Isotropic – the same in all directions.

Chapter 20 Dark Matter, Dark Energy, and the Fate of the Universe.

Black Holes. Outline Escape velocity Definition of a black hole Sizes of black holes Effects on space and time Tidal forces Making black holes Evaporation.

Einstein’s Universe Tuesday, February 5. Einstein – Newton smackdown! gravityspace Two different ways of thinking about gravity and space.

Please pick up your corrected problem set and midterm. Problem Set #4: median score = 85 Midterm Exam: median score = 72.

The Expanding Universe Except for a few nearby galaxies (like Andromeda), all the galaxies are seen to be moving away from us Generally, the recession.

The Destiny of the Universe Friday, November 21. increasing The universe is expanding: that is, the scale factor a(t) is increasing with time.

How do we transform between accelerated frames? Consider Newton’s first and second laws: m i is the measure of the inertia of an object – its resistance.

1. White Dwarf If initial star mass < 8 M Sun or so. (and remember: Maximum WD mass is 1.4 M Sun, radius is about that of the Earth) 2. Neutron Star If.

Galaxies What is a galaxy? How many stars are there in an average galaxy? About how many galaxies are there in the universe? What is the name of our galaxy?

Chapter 10 – part 3 - Neutron stars and Black Holes Neutron stars.

Chapter 12 Gravitation. Theories of Gravity Newton’s Einstein’s.

Galaxies What is a galaxy? How many stars are there in an average galaxy? About how many galaxies are there in the universe? What is the name of our galaxy?

Cosmology Physics466 Olbers Paradox Cosmological principle Expansion of the Universe Big Bang Theory Steady State Model Dark Matter Dark Energy Structure.

Friday, October 24 Next planetarium show: Thurs, Nov. 6

Black Holes By Irina Plaks. What is a black hole? A black hole is a region in spacetime where the gravitational field is so strong that nothing, not even.

13.3 Black Holes: Gravity’s Ultimate Victory Our Goals for Learning What is a black hole? What would it be like to visit a black hole? Do black holes really.

Review for Exam 3.

Dark Matter Masses of Galaxies Gravity and Light Black Holes What is Dark Matter?

Stationary Elevator with gravity: Ball is accelerated down.

Dark Matter begin. Definition Dark Matter is matter that we cannot see. It neither emits nor reflects any light. If we can’t see it, how do we know it.

The Expanding Universe Wednesday, October 22 Next planetarium show: Thurs, Nov. 6.

Unit 06 “Circular Motion, Gravitation and Black Holes” “Gravitation and Black Holes”

$200 $300 $400 Final Jeopardy $100 $200 $300 $400 $500 $100 $200 $300 $400 $500 $100 $200 $300 $400 $500 $100 $200 $300 $400 $500 $100 Types of Black.

First possibility: Space is FLAT The two-dimensional analog for flat space is a plane (illustrated below). On a plane, and.

Announcements Exam 4 is Monday May 4. Tentatively will cover Chapters 9, 10, 11 & 12 (maybe) Sample questions will be posted soon Project Presentations.

Physics Mrs. Coyle -Gravitational Field -Satellites -Einstein’s View of Gravity.

Black Holes. Gravity is not a force – it is the curvature of space-time - Objects try and move in a straight line. When space is curved, they appear to.

Goal: To understand special stars. Objectives: 1)To learn the basics about Black holes 2)To examine the different sizes/masses of Black holes 3)To learn.

A black hole is a region of space with such a strong gravitational field that not even light can escape.

Lecture 40 Galaxies (continued). Evolution of the Universe. Characteristics of different galaxies Redshifts Unusual Galaxies Chapter 18.6  18.9.

BLACK HOLES. WHAT IS A BLACK HOLE? A few definitions from the dictionary: Region of space resulting from the collapse of a star Region of space with strong.

General Relativity and the Expanding Universe Allan Johnston 4/4/06.

Chapter 16 Dark Matter, Dark Energy, and the Fate of the Universe.

Dark Energy Wednesday, October 29 Midterm on Friday, October 31.

Lecture 27: Black Holes. Stellar Corpses: white dwarfs white dwarfs  collapsed cores of low-mass stars  supported by electron degeneracy  white dwarf.

The Milky Way Galaxy. HW #9 – MasteringAstro “Stars and Galaxies” Available now Tuesday April 17 th Due BEFORE CLASS Tuesday April 24 th Observing logs.

Principle of Equivalence: Einstein 1907 Box stationary in gravity field Box falling freely Box accelerates in empty space Box moves through space at constant.

By Katy O’Donohue. Black Holes Black Holes are a region of space from which nothing can escape, including light. Light is made up of massless particles.

Black Holes Chapter 14. Review What is the life cycle of a low mass star (

Stars & Galaxies in Motion 6:30 Wednesday, October 15 Next Planetarium Show: tonight, 6:30 pm.

Physics 55 Monday, December 5, Course evaluations. 2.General relativity with applications to black holes, dark matter, and cosmology. 3.Hubble’s.

General Relativity and Cosmology The End of Absolute Space Cosmological Principle Black Holes CBMR and Big Bang.

It was discovered in the early 1990’s that the pulse period of a millisecond pulsar 500 parsecs from earth varies in a regular way.

PowerPoint made by Sana Gill BLACK HOLES. WHAT IS A BLACK HOLE? A black hole is an area in space-time so compact that no matter, not even light can escape.

Lecture 20: Black Holes Astronomy Spring 2014.

Astronomy 1143 – Spring 2014 Lecture 21: The Evidence for Dark Matter.

The Expanding Universe

General Relativity and Grade-9 Astronomy. 0) Gravity causes time to slow down. Everyday Einstein: The GPS and Relativity OAPT Conference May 12 – 14 McMaster.

Lecture 27: The Shape of Space Astronomy Spring 2014.

A black hole: The ultimate space-time warp Ch. 5.4 A black hole is an accumulation of mass so dense that nothing can escape its gravitational force, not.

ASTR 113 – 003 Spring 2006 Lecture 12 April 19, 2006 Review (Ch4-5): the Foundation Galaxy (Ch 25-27) Cosmology (Ch28-29) Introduction To Modern Astronomy.

Black Holes. Escape Velocity The minimum velocity needed to leave the vicinity of a body without ever being pulled back by the body’s gravity is the escape.

The Shape and Fate of the Universe Assumptions in cosmology Olber’s paradox Expansion of the Universe Curvature of the Universe Fate of the Universe.

The Fate of the Universe. The fate depends on the rate of expansion and the density Density greater than critical value – gravity will halt expansion.

Black Holes A stellar mass black hole accreting material from a companion star 1.

Universal Gravitation Does the moon stay at a certain distance from the Earth or is it falling toward the Earth? - the moon is actually falling around.

Chapter 20 Cosmology. Hubble Ultra Deep Field Galaxies and Cosmology A galaxy’s age, its distance, and the age of the universe are all closely related.

Astronomy 1020 Stellar Astronomy Spring_2016 Day-38.

Dark Matter, Dark Energy

Astrophysics and Cosmology

Exam 3 average: 65%. You will have all of class time on Thursday to do the group review. The response “Exams” will be on Learning Suite by Wed noon. They.

Galaxies What is a galaxy?

General Relativity: Part II

Presentation transcript:

Please pick up problem set #3. Median score = 87. Recitation session: Today, 4:30 – 5:30 pm McPherson (Prof subbing for TA)

Is the Universe Infinite? Monday, October 27 Next Planetarium Show: Thurs, Nov 6

Newton’s Newton’s view of space: rectilinear & rigid (not expanding or contracting) Think of a bug crawling over stiff graph paper.

Einstein’s Einstein’s view of space: curved & wavy (can also expand or contract) Think of a bug crawling over a rumpled rubber sheet.

Einstein’s view of space is mathematically complicated. However, it gives better results when gravity is strong (close to massive objects). Einstein’s triumphs: Gravitational lensing by the Sun Orbit of Mercury (closest planet to Sun)

massenergy Space is curved by the presence of mass and energy.

General rule: high density (of either mass or energy) leads to highly curved space. Black holes Black holes cause extreme curvature.

What’s a black hole? escape velocity Newton: a black hole is an object whose escape velocity is greater than the speed of light. Earth: escape velocity = 11 kilometers/sec Sun: escape velocity = 600 km/sec black hole: escape velocity > 300,000 km/sec

What’s a black hole? event horizon Einstein: a black hole is an object smaller than its event horizon. What’s an “event horizon”?

inside outside Event horizon = a mathematically defined surface around a black hole. Photons (& other particles) inside the event horizon can’t ever move outside. “What happens inside the event horizon stays inside the event horizon.”

Black hole as lobster trap: once an object enters the event horizon, it can’t exit. mass Size of event horizon is proportional to mass of black hole: for Sun’s mass, it’s 3 kilometers (about 2 miles).

If black holes are compact and (by definition) black, how do we see them against the blackness of the sky? We can detect their gravitational influence on glow-in-the-dark matter – like stars.

Stars near the Galactic Center (8000 parsecs away) orbit a massive, compact, dark object. Mass = 2 million times the Sun’s mass

simplest The simplest explanation of the massive object at our galaxy’s center is that it is a supermassive black hole (SMBH). Other galaxies have supermassive black holes, too. quasiar As gas falls toward the black hole, it heats up & emits light. “Quasars” (quasi-stellar objects) are black holes that accrete lots of gas.

Locally, dense knots of mass (& energy), such as black holes, cause strong curvature. average average Globally, the average density of mass & energy in the universe causes an average curvature. On large scales, the homogeneous, isotropic distribution of mass (& energy) causes homogeneous, isotropic curvature.

There are 3 possible examples of homogeneous, isotropic curvature: (Asserted without proof: find a 4 th case, win a Nobel Prize…) (“flat”)

Is the universe infinite? positively finite If space is positively curved, space is finite, but without a boundary. negatively flat infinite If space is negatively curved or flat, space is infinite (unless a boundary or edge is imposed).

Measuring curvature is easy, in principle. Flat: angles of triangle add to 180° >180° Positive: angles add to >180° <180° Negative: angles add to <180°

Curvature is hard to detect on scales smaller than the radius of curvature. good Flat = good approximation bad Flat = bad approximation

Measuring parallax (flat space) October April p p a = 1 AU p in arcseconds, d in parsecs p = 1/d d

Parallax (positive curvature) October April p p p < 1/d

Parallax (negative curvature) October April p p p > 1/d As d →infinity, p→1/R radius of curvature

Bright idea: The smallest parallax you measure puts a lower limit on the radius of curvature of negatively curved space. at least Hipparcos measured p as small as arcsec; radius of curvature is at least 1000 parsecs.

Bigger We need Bigger triangles to measure the curvature accurately!  L d  =L/d (flat)  >L/d (positive)  <L/d (negative)

Positively magnifying large Positively curved universe: curved space is a magnifying lens; distant galaxies appear anomalously large. Negatively demagnifying small Negatively curved universe: curved space is a demagnifying lens; distant galaxies appear anomalously small. magnifying demagnifying

And the answer is… Distant galaxies are neither absurdly small in angle nor absurdly large. If If the universe is curved, radius of curvature is bigger than the Hubble distance (c/H 0 = 4300 Mpc).

Horizons horizon The Earth has a horizon: we can’t see beyond it because of the Earth’s curved surface. event horizon A black hole has an event horizon: we can’t see into it because photons can’t escape.

The Ultimate Horizon cosmological horizon The universe has a cosmological horizon: we can’t see beyond it because photons from beyond haven’t had time to reach us. Distance to cosmological horizon is approximately equal to the Hubble distance (c/H 0 = 4300 Mpc).

Suggestion:positively Suggestion: space is positively curved, but with a radius of curvature much larger than the Hubble distance (4300 Mpc). finite This gives the universe a huge (but finite) volume. The part I can see looks flat!

Wednesday’s Lecture: Reading: Chapter 7 Dark Energy Problem Set #4 due.