Presentation is loading. Please wait.

Presentation is loading. Please wait.

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.

Published byMoses Hubbard Modified over 8 years ago

Similar presentations

Presentation on theme: "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."— Presentation transcript:

1 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 about the physics inside a black hole 4)To explore Kerr black holes. 5)To explore Hawking Radiation 6)To learn about some other black hole oddities

2 What is a black hole As we saw before an object dense enough or massive enough such that the escape velocity is the speed of light

3 Event Horizon = Goodbye Forever (takes infinite time to pass through it) Is the surface where the escape velocity is the speed of light Is the effective radius of the black hole Rs = 1.5 km * Mass of black hole (in solar masses)

4 However Black holes are very rare. They also come in many sizes/masses.

5 Solar Mass Black Holes These are black holes that are 5-50 times the mass of our sun. They are formed from the deaths of massive stars. If on their own they are very tough to find as we can only see black holes when they interact with other objects.

6 Black Holes in binaries Just like with Neutron stars and white dwarfs, black holes will create an accretion disk. However, you can see nothing from the actual accretion, so all you get to see is the accretion disk. On the plus side, the accretion disk goes down to a few km in size at which point the gas has been heated quite a bit (infalling gas is slowed by frictional heating and interactions with the magnetic field). The innermost parts will emit X-rays!

7 Black holes in Globular Clusters In the centers of Globular Clusters, where stars are very tightly packed we often find black holes These black holes can be a few thousand times the mass of our sun. There also seems to be a correlation between cluster mass and black hole mass.

8 Galactic Center Black Holes Every galaxy we can peer into its center has a black hole that is millions of solar masses to billions. Ours is 4 million. Andromeda is about a billion.

9 Astro-mercial But wait there’s more! JETS! Materials racing outward at close to the speed of light and going for up to millions of light Years! (NGC 5532)

10 Physics outside a black hole We have 4 known dimensions 3 real spatial 1 real time Real Distance = Real Velocity * Real Time Real Acceleration = Change in Real Velocity / Real Time

11 Inside a black hole: Tobject = Tuniversal / (1 – r s / r) 1/2 So, when r > Rs then we have the square root of a negative number. What does that give us?

12 Imaginary Time So, time is not real but in terms of i (i = square root of -1) In our 4 dimensional physics world this messes up everything… So how can the Laws of Physics not work and still be Laws?

13 Maybe not M-Theory (not really a “Theory” more a “Model”, but M-Model does not sound impressive) 11 dimensions So, what makes no sense in 4 dimensions might make sense in 11. (so might have 3 real spatial, 3 imaginary spatial, real time, imaginary time, and 3 more dimensions)

14 So Black Holes may have a key in unlocking the mysteries of the universe. However, we have no idea what happens to the stuff inside the black hole. Does it all collapse to center, or just get converted to energy?

15 Properties Even though the physics fail as we currently understand them in our 4 D worldview Black Holes still have properties They have magnetic fields Some have spin.

16 Kerr Black Holes Kerr Black Holes are black holes with spin. This gives them a different structure

17 Spin Energy In the distant future you can actually take the spin energy out of a Kerr Black Hole and use it! However the closest black hole is > 1000 light years away so…

18 Oddity Too much spin and the event horizons go away This would create a “naked singularity”

19 Hawking’s Radiation Space is NOT empty, it has energy! Everywhere in space you are constantly forming pairs of particles. One with + energy, one with -. They usually run into other particles and destroy themselves.

20 Near an event horizon There is a chance for the negative energy particle to quantum tunnel through the event horizon and end up inside the black hole The positive energy particle then escapes from the black hole (making it appear that the particle came from inside the black hole) Since energy is mass that means the black hole looses mass!

21 However This process for known black holes will not start (due to getting more energy from the universe and radiation from the universe than they would loose) for a long time The smaller black holes will last a google years. The bigger ones even longer.

22 Wormholes + White Holes If you bend space time enough it makes it very easy to get to another place Black holes are one way to do that However, it is problematic White holes are the opposite. You go into a black hole, and shoot out a White hole. Warning: the white hole you exit would not be in our universe but would be in a negative space universe 2 nd warning: UNSTABLE! Just you entering might be enough to destablize

23 Conclusion We have learned a whole lot about black holes. They exist and are here and there, but are rare. They come in more than 1 flavor They might be pointing towards other areas/laws of Physics

Download ppt "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."

Similar presentations

Black Holes Devouring Monsters of the Universe. How are they made? Only the very largest stars, beginning with at least 50 solar masses, are able to form.

Black Holes Devouring Monsters of the Universe. How are they made? Only the very largest stars, beginning with at least 50 solar masses, are able to form.
Supernovae and nucleosynthesis of elements > Fe Death of low-mass star: White Dwarf White dwarfs are the remaining cores once fusion stops Electron degeneracy.

Supernovae and nucleosynthesis of elements > Fe Death of low-mass star: White Dwarf White dwarfs are the remaining cores once fusion stops Electron degeneracy.
Chapter 18: Relativity and Black Holes

Chapter 18: Relativity and Black Holes
Stellar Deaths II Neutron Stars and Black Holes 17.

Stellar Deaths II Neutron Stars and Black Holes 17.
Neutron Stars and Black Holes Please press “1” to test your transmitter.

Neutron Stars and Black Holes Please press “1” to test your transmitter.
Copyright © 2010 Pearson Education, Inc. Chapter 13 Black Holes.

Copyright © 2010 Pearson Education, Inc. Chapter 13 Black Holes.
Neutron Stars and Black Holes

Neutron Stars and Black Holes
The mass of a neutron star cannot exceed about 3 solar masses. If a core remnant is more massive than that, nothing will stop its collapse, and it will.

The mass of a neutron star cannot exceed about 3 solar masses. If a core remnant is more massive than that, nothing will stop its collapse, and it will.
AST101 The Evolution of Galaxies. Virgo Cluster Collisions of Galaxies Outside of Clusters (the field), most galaxies are spiral or irregular In dense.

AST101 The Evolution of Galaxies. Virgo Cluster Collisions of Galaxies Outside of Clusters (the field), most galaxies are spiral or irregular In dense.
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.

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.
Black Holes Written for Summer Honors 2009. Black Holes Massive stars greater than 10 M  upon collapse compress their cores so much that no pressure.

Black Holes Written for Summer Honors Black Holes Massive stars greater than 10 M  upon collapse compress their cores so much that no pressure.
The Stellar Graveyard.

The Stellar Graveyard.
Black Holes by Dalton, Connor, and Bryan. What is a black hole? The idea of black holes comes from the escape velocity. The escape velocity basically.

Black Holes by Dalton, Connor, and Bryan. What is a black hole? The idea of black holes comes from the escape velocity. The escape velocity basically.
Black Holes Dennis O’Malley. How is a Black Hole Created? A giant star (more than 25x the size of the sun) runs out of fuel –The outward pressure of the.

Black Holes Dennis O’Malley. How is a Black Hole Created? A giant star (more than 25x the size of the sun) runs out of fuel –The outward pressure of the.
Lecture 18 Black Holes (cont) ASTR 340 Fall 2006 Dennis Papadopoulos.

Lecture 18 Black Holes (cont) ASTR 340 Fall 2006 Dennis Papadopoulos.
Goal: To know the different types of galaxies and to understand their differences and similarities. Objectives: 1) To learn about Spirals 2) To learn about.

Goal: To know the different types of galaxies and to understand their differences and similarities. Objectives: 1) To learn about Spirals 2) To learn about.
Astronomy for beginners Black Holes Aashman Vyas.

Astronomy for beginners Black Holes Aashman Vyas.
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.

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.
Black Holes.

Black Holes.
Goal: To understand gravity Objectives: 1)To understand who discovered what about gravity. 2)To learn about the Universal nature of gravity 3)To explore.

Goal: To understand gravity Objectives: 1)To understand who discovered what about gravity. 2)To learn about the Universal nature of gravity 3)To explore.

Similar presentations

Ads by Google