STARS

1. STARS

2. Life Cycle of A Star 1. Stars begin their lives as clouds of dust and gas called a stellar nebula.

3. How A Protostar Is Formed The gravity of a passing star or the shock wave from a nearby supernova may cause the nebula to contract. 1. Matter in the gas cloud will begin to come together into a dense region called a protostar. 2. As the protostar continues to condense, it heats up. 3. Eventually, it reaches a critical mass and nuclear fusion begins. 4. This begins the main sequence phase of the star. Our Sun is a main sequence star.

4. PROTOSTAR

5. Main Sequence Stars 1. The life span of a star depends on its size. 2. Very massive stars will become blue giants during their main sequence. Their main sequence may last only a few hundred thousand years. 3. Smaller stars, like the Sun, will burn for several billion years during their main sequence stage. 4. Our Sun is in its main sequence.

6. Main Sequence • After a star forms, it enters its 2nd & longest part of its life—main sequence • Hydrogen fuses together to make helium, releasing large amounts of energy—much in the form of heat & light. • Stars that lose their gas slowly stay on the main sequence a long time. • Stars that lose their gas quickly stay on the main sequence a short time.

7. The main sequence is the longest part of a star’s life Average sized star like our Sun during main sequence. Massive star larger than our Sun during main sequence

8. 3rd stage of a star’s life = red giant • Goes to this after leaving the main sequence because it has used most of its hydrogen • The star continues to cool after leaving the main sequence, forming a red giant (10X sun) or red supergiant (10 to 100X the sun)

9. Red Giant and Red Supergiant 1. Eventually, the star's fuel will begin to run out. 2. Our Sun will expand into what is known as a red giant. 3. Massive stars will become red supergiants. 4. This phase will last until the star exhausts its remaining fuel. 5. At this point, the star will collapse.

11. Planetary Nebula Most average stars will blow away their outer atmospheres to form a planetary nebula. Shells of gas thrown out by some stars near the end of their lives

12. Planetary Nebula

13. White Dwarfs • Final stage of a star’s life cycle • Small, hot star made from the leftover core of a star • Can shine for billions of years before cooling completely

14. White Dwarf • Their cores will remain behind and burn as a white dwarf until they cool down. • From a planetary nebula an average star will become one of these, radiating into space

15. When Average Stars die • Average stars becomes red giants & then white dwarfs (stars like our sun)

16. White Dwarf

17. Dark Dwarf What will be left is a dark ball of matter known as a black dwarf. The last phase of an average star’s life

18. Life Cycle of our Sun • Stellar Nebula • Protostar • Main Sequence • Red Giant • Planetary Nebula • White Dwarf • Black Dwarf

19. Massive Stars 1. If the star is massive enough, the collapse will trigger a violent explosion known as a supernova. 2. If the remaining mass of the star is about 1.4 times that of our Sun, it will collapse further to become a neutron star. 3. If the remaining mass of the star is more than about three times that of the Sun, it will collapse and what is left behind is an intense region of gravity called a black hole.

20. Massive Stars (Larger than our Sun) Become Red Supergiants.

21. Red Supergiant becomes Supernova in a giant explosion,

22. OR It becomes a Black Hole This is an illustration, not an actual black hole!!

23. Supernova Becomes a Neutron Star

24. Life Cycle of a Massive Star • Stellar Nebula • Protostar • Blue Giant • Red Supergiant • Supernova • Neutron Star (Pulsar) OR 7. Black Hole

25. Interactive Website • http://aspire.cosmic-ray.org/labs/star_life/starlife_main.html