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Black Holes Astrophysics Lesson 14. Learning Objectives To know:-  How to define the event horizon for a black hole.  How to calculate the Schwarzschild.

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Presentation on theme: "Black Holes Astrophysics Lesson 14. Learning Objectives To know:-  How to define the event horizon for a black hole.  How to calculate the Schwarzschild."— Presentation transcript:

1 Black Holes Astrophysics Lesson 14

2 Learning Objectives To know:-  How to define the event horizon for a black hole.  How to calculate the Schwarzschild radius, R S, for the event horizon of a black hole.  To discuss the evidence for and the density of the super massive black hole at the centre of the Galaxy.

3 Homework  Collecting - the mock EMPA.  Reminder another mock EMPA on Monday.  Homework – Q6-8, p180-181  Read p173-180 if you have the time – it’s interesting stuff!

4 Recap What determines whether a black hole will form in the first place? What is the defining feature of a:- Supernova Neutron Stars Black Holes

5 How can they be observed? Either from material falling into the black hole:- Gravitational potential energy  electromagnetic radiation.

6 How can they be observed?  Stars orbiting an invisible centre of mass.  This is what we observe at the centre of the Milky Way galaxy.  Video clip…

7 Some definitions The Event Horizon:- This is defined as the boundary at which the escape velocity is equal to the speed of light. The Schwarzschild Radius, R S :- This is defined as the radius of the event horizon. Anything that is within the Event Horizon of the black hole cannot escape – not even light.

8 Energy Equations Supposed we have an object of mass, m on the surface of a more massive object of mass M. How do we calculate the kinetic energy and gravitational potential energy of mass m.

9 Energy Equations The kinetic energy of an object of mass, m:- It’s gravitational potential energy on the surface of a more massive object M is given by:- Think force x distance, where the force is Newton’s law of gravity. At inifinity GPE = 0.

10 The Escape Velocity This is the velocity required for a less massive object of mass, m, to completely escape the gravitational field (to infinity) of a more massive object of mass M. If m is taken to infinity, the difference in GPE is:- So the initial kinetic energy of m must be equal to:-  make v the subject

11 The Escape Velocity So the escape velocity is given by:- At the boundary of the event horizon of a black hole, R=R S, the Schwarzschild radius, and v = c, the speed of light:-  Rearrange this for R s

12 The Escape Velocity So the escape velocity is given by:- At the boundary of the event horizon of a black hole, R=R S, the Schwarzschild radius, and v = c, the speed of light:-  Rearrange this for R s

13 Schwarzschild Radius This is defined as the radius of the event horizon of a black hole.

14 Density of a Black Hole Recall the equation for density:- If we substitute our equation for R S into the equation:- We can derive an equation for the density of a black hole.

15 Density of a Black Hole I get:- Evaluate ρfor M= 10 solar masses. What value of M would give a density equal to that of water? (1,000 kg m -3 )

16 Density of a Black Hole Density is not constant, it is infinite at the centre.

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