1. The Life Cycle of a Star

2. GLUE INTO NOTES!

3. What is a Star? A star is ball of plasma undergoing nuclear fusion.
Stars give off large amounts of energy in the form of electromagnetic radiation.
X-ray image of the Sun

4. X-ray
infrared

5. ALL STARS:

6. Nebula – Birth of Star Stars are formed in a nebula.
A Nebula is a very large cloud of gas and dust in space.

7. Protostars Gravity makes dense region of gas more compact
Soon take on a definite shape and are called protostars.

8. A new star!!
Once the core of a protostar reaches 10,000,000o C, nuclear fusion begins and the protostar ignites.
The bright spot is a new star igniting

9. Nuclear
Fusion
Nuclear Fusion is the process by which two nuclei combine to form a heavier element.
New stars initially will fuse hydrogen nuclei together to form helium.

10. Main Sequence Stars
Once the star has ignited, it becomes a main sequence star.
Main Sequence stars fuse hydrogen to form helium, releasing enormous amounts of energy.
It takes about 10 billion years to consume all the hydrogen in a Main Sequence star.
Our sun is currently in this stage, and will stay this way for another 5.5 billion years!

11. Balancing Act The core of a star is where the heat is generated. The
radiative and conductive
zones move energy out
from the center of the star.
The incredible weight of
of all the gas and gravity
try to collapse the star on
its core.

12. Unbalanced Forces As long as there is a nuclear
reaction taking place, the
internal forces will balance the
external forces.
When the hydrogen in a main
sequence star is consumed, fusion
stops and the forces suddenly
become unbalanced. Mass and
gravity cause the remaining gas
to collapse on the core.

13. AFTER MAIN SEQUENCE…
After the main sequence phase, what happens next depends on a star’s mass.
Low mass/average stars, like our sun, follow a different life cycle than high mass/massive stars.

14. LOW MASS STARS:
Like our Sun 

15. Red Giant
Collapsing outer layers cause core to heat up.
fusion of helium into carbon begins.
Forces regain balance.
Outer shell expands from 1 to at least 40 million miles across. ( 10 to 100 times larger than the Sun)
Red Giants last for about 100 million years.

16. Unbalanced Forces (again)
When the Red Giant has fused all of the helium into carbon, the forces acting on the star are again unbalanced.
The massive outer layers of the star again rush into the core and rebound, generating staggering amounts of energy.

17. Planetary Nebulas –Final stages
A cloud of gas that forms around low mass star that is dying
Made of the remains of the red giant

18. White Dwarfs Planetary nebula around a white dwarf star.
A small core remains.
The pressure exerted on the core by the outer layers does not produce enough energy to start carbon fusion.
The core is now very dense and very hot. (A tablespoon full would weigh 5 tons!)
A white dwarf is about 8,000 miles in diameter.
After 35,000 years, the core begins to cool.
Planetary nebula around a
white dwarf star.

19. Black Dwarfs
As the white dwarf cools, the light it gives off will fade through the visible light spectrum, blue to red to back (no light).
A black dwarf will continue to generate gravity and low energy transmissions (radio waves).
We can’t see them, but we know that they are there.

20. HIGH MASS STARS:
After nebula… protostar… main sequence…

21. Red Supergiants
If the mass of a star is 3 times that of our sun or greater, will become a Red Supergiant.
Fusion stops and the outer layers collapse on the core.
This time, there is enough mass to get the core hot enough to start the fusion of carbon into iron.

22. Red Supergiants
Once fusion begins, the star will expand to be between 10 and times larger than our sun. ( Out to the orbit of Uranus )

23. Supernova
When a Supergiant fuses all of the Carbon into Iron, there is no more fuel left to consume.
The core of the supergiant will then collapse in less than a second, causing a massive explosion called a supernova.
In a supernova, a massive shockwave is produced that blows away the outer layers of the star.
Gas ejected from a supernova explosion

24. Neutron Star Sometimes the core will survive the supernova.
If the surviving core has a mass of less than 3 solar masses, then the core becomes a neutron star.
composed predominantly of closely packed neutrons
6 miles in diameter

25. Black Holes
If the mass of the surviving core is greater than 3 solar masses, then a black hole forms.
A black hole is a core so dense and massive that it will generate so much gravity that not even light can escape it.
Since light cant escape a
black hole, it is hard to tell
what they look like or how
they work.

27. OUR SUN
Containing more than 99.8% of the total mass of the Solar System, the Sun is by far the largest object in the Solar System.
109 Earths would be required to even fit across the Sun's disk, and the Sun's interior could hold over 1.3 million Earths.
Within the core of the Sun, the temperature (15,000,000 K) and pressure (340 billion times Earth's air pressure at sea level) of it is so intense that nuclear reactions actually take place.
The Sun's energy output, produced by these nuclear fusion reactions, is approximately 3.86e33 ergs/second or 386 billion billion megawatts.
The process that takes this energy to the surface of the sun following complex stages is called convection.
This energy, released as heat and light, takes a million years to reach the surface.

28. The Sun consists of the core, photosphere, chromosphere and corona, each with differing temperatures and components.
**The layers of the sun are vocabulary words that YOU will look up and add to your notes. 

29. The Sun also emits low density streams of particles, also known as the solar wind. These winds blow through the solar system at km/sec and consist mostly of electrons and protons.
Existing for about 4 and a half billion years, it has burnt up about half of the hydrogen in its core. This leaves the Sun's life expectancy to 5 billion more years, at which time, the Sun's elements will "swell" up, swallow Earth, and eventually die off into a small white dwarf.