1. TOPIC: Astronomy AIM: What are stars?

2. Ball of gases that gives off light and heat
Star

3. Universe began with a giant explosion 13 billion years ago
The Big
Bang
Theory

4. Matter  stars
It is still expanding
Most accepted theory

6. What
is the
Sun?
Nearest star to Earth

7. What
are
stars
made
of?
Hydrogen and helium gases

8. How do
stars
form?
1. Nebula (large cloud of gas, ice, and dust) forms

9. The Orion Nebula, a site of active star formation
The Orion Nebula, a site of active star formation. From the Hubble Space Telescope.

10. The above images show the Eagle Nebula star-forming region in the Infrared (left) compared with a visible light image by Hubble Space Telescope (right).

11. 2. Nebula contracts (due to gravity) & breaks up into smaller pieces

12. 3. Temperature increases (1 million K)
4. Center = protostar forms

14. 5. Temp reaches 10 million K
6. H fuses to make He  star

15. Hertzsprung-Russell Diagram Higher temp stars radiate more energy
H-R
Diagram
Hertzsprung-Russell Diagram
Higher temp stars radiate more energy

17. 90% of all stars fall on main sequence (line from upper left to lower right)

19. Our sun has been a main sequence star for 5 billion years and will stay a main sequence star for another 5 billion years.

20. How do
stars
change?
1. Shrinks
2. Increases in density
3. Temp increases
4. Moves into main sequence (when fusion starts)

21. Types Of stars 1. Giant = late stage (When H is used up)
Core contracts, temp increases
Outer layers expand & cool

22. a. Red Giant = large bright star, fairly cool

23. b. Super Giant = very large stars
Example: Betelgeuse

24. Betelgeuse is located in the constellation of Orion
Betelgeuse is located in the constellation of Orion. It’s diameter is larger than the diameter of Jupiter’s orbit around the Sun.

25. Can eventually collapse, outer portion explodes  SUPERNOVA (giant explosion)

26. Supernova can turn into a neutron star OR a black hole

27. A supernova is a giant explosion in which the temperature in the collapsing core reaches 10 billion K and atomic nuclei are split into neutrons and protons. Protons merge with electrons to form neutrons, and the collapsing core becomes a neutron star. A typical neutron star is the size of a major city on Earth, but has a mass greater than the Sun’s.

28. Hubble Space Telescope image of a neutron star (identified by the arrow) in the direction of the southern constellation Corona Australis. The star has a surface temperature of 1.2 million degrees Fahrenheit, which is far hotter than that of ordinary stars.

29. Black hole = object so dense that nothing can escape its gravity
Usually results from the supernova of a very massive star

32. 2. White dwarf = giant that lost outer layers
Very small, hot star, Hot dense core
Keeps contracting due to gravity

33. A giant’s core will continue to contract and become hotter
A giant’s core will continue to contract and become hotter. When it uses up all its helium, it contracts even more. When the temperature reaches 100 million K, helium fuses, forming carbon. Now the star is enormous and its surface is much cooler. Its outer layers escape into space leaving behind a hot, dense core that continues to contract and is now called a white dwarf which is about the size of Earth.

34. There are many white dwarfs in our galaxy, but most are too dim to be seen. One of the first to be discovered was Sirius B, the dense companion star to Sirius.

35. Nebula Black dwarf Protostar White dwarf Giant Super Giant
Life Cycle of a Star
Nebula
Black dwarf
Protostar
White dwarf
Giant
Super Giant
(SUPERNOVA)
Neutron Star
Black Hole

40. Star pattern that appears to form images
What is a
constellation?
Star pattern that appears to form images
Used by astronomers to locate and name stars

42. Instrument used to observe objects in outer space using lenses
Telescope