1. Astronomy 1

2. Terms Astronomy – The study of the universe Universe – Everything known that exists, including space, time and matter Solar System – the Sun and its family of orbiting planets, moons, asteroids, meteoroids, and comets Star - A luminous ball of gas that produces energy through the nuclear fusion of hydrogen

3. Planet -A body that does not give off light, can be made of solids, liquids, or gases Moons - an object made mostly of rock that orbits a larger body, usually a planet (also called satellites)

4. Light year Light – the fastest thing in the universe. Light year (LY) – the distance light travels in one year –Speed - 186,282 miles per second –Distance light travels in one year 5,870,000,000,000 miles

5. Astronomical Unit Astronomical Unit (AU) - the average distance from the Earth to the Sun –1 AU = about 92,960,000 miles

6. Interesting Fact For every grain of sand on earth there are a million stars in our universe!

7. The Big Bang Theory The whole universe was believed to be packed into a very dense sphere of hydrogen called a singularity. About 13 billion years ago it formed a gigantic cloud of gas that expanded. It has been expanding and cooling ever since.

8. Some parts moved quicker than others. Parts of the cloud clumped into billions of stars forming galaxies. We live in one of those galaxies. Our galaxy is called the MILKY WAY.

9. More Interesting Facts The Universe is not expanding into something. Everything that is, is expanding. The further away from us a galaxy is, the faster it is moving.

10. Steady State Theory Alternate theory for the beginning of the Universe (not many people believe it now) Says Universe is expanding, but new matter is constantly being created so the overall density stays the same

11. Galaxies Galaxies - systems of millions or billions of stars Galaxies contain dust, gases, and stars The material (dust, asteroids, meteoroids, comets, planets, etc.) that orbits around a star is called a Solar System

12. 3 Types of Galaxies Spiral Galaxy Has a central lens-shaped, bright nucleus made of millions of stars (and possibly a super-massive black hole) Around the nucleus is a fainter, flat disk of stars, gas and dust This disk is in the shape of spiral arms

14. Elliptical galaxy System of stars made mainly of only stars, very little dust and gas –Thought to be older than spiral galaxies Lens-shaped or spherical No spiral arms Most of the stars are close to the center

16. Irregular galaxy Small, faint, and less common type of galaxy made up of stars Have an irregular shape

17. Irregular Galaxy NGC 1427A

18. Milky Way Our Galaxy Over 100 billion stars make up our galaxy Our sun lies in one of the arms of this galaxy. The diameter is about 140,000 light years across. It is about 20,000 light years thick. The sun is about 23,000 light years away from the center.

19. Top view

20. Top View Side view

21. What we see from Earth (with a good camera)

22. Andromeda Galaxy Spiral Galaxy Much larger than the Milky Way About 2 million light years away Much like our own Galaxy, that is why it is studied so greatly

23. Andromeda Galaxy

24. Magellanic Clouds Two irregular galaxies that satellite the Milky Way Can be seen from the southern hemisphere with the naked eye Looks like…a large cloud and a small cloud

25. Magellanic Clouds

26. Local Group The Milky Way belongs to a cluster of more than 17 galaxies called the Local Group. The Magellanic Clouds and the Andromeda are part of this Local Group. * Galaxies usually form in clumps such as our own Local Group.

27. Nebula Nebula - cloud of dust and gas A Nebular cloud is made up of: –99% gas (mostly hydrogen) –1% dust Most nebula are invisible. The only way we can see them is by light from a star. AKA: “Stellar Nurseries”

28. Nebulas Orion NebulaEagle Nebula Crab Nebula Horse head Nebula Bubble NebulaNorth American Nebula

30. How a star is born 1. A nebula contains star forming gases. 2. Something disturbs the gases (i.e. shockwave from a supernova) and the gases begin to come together and compress into a ball of hot gases. 3. The ball of gases starts to glow. It is now called a protostar (“baby star”).

31. Main sequence Star 4. A protostar becomes a star once it becomes hot enough to begin fusing hydrogen into helium. About 10,000,000 K 5. A main sequence star is an “adult star.” –A main sequence star is in a stable state. –This means that the energy produced by a star equals the gravity acting on the star.

32. Stable state Gravity Energy

33. H-R Diagram Hertzsprung - Russell Diagram –Shows how the Luminosity (brightness) and temperature of a star are related –When a star is on the Main Sequence: as temperature increases, so does luminosity as temperature decreases, so does luminosity

35. A good thing to remember Hot stars are blue in color. Cool stars are red in color. Our sun is a whitish/yellow color star. It’s temperature is somewhere in the middle of blue and red. Think of fire: the hottest part of a flame is the blue part, not the orange part!!!

36. Red Giants 6. A star’s core uses up its hydrogen. 7. The core collapses causing heavier elements to fuse together –Burning: helium, then carbon, oxygen, etc. 8. When it burns heavier elements the star expands to a large size and begins to cool off.

37. Red Giant

38. What will happen to a star after it dies? Prior to this point in the star life cycle, all stars behave the same way Depending on the star’s mass, when it was a main sequence star it will become one of the following: –White dwarf –White dwarf with a planetary nebula –Neutron star –Pulsar –BLACK HOLE

39. Important to know… The more mass a star has, the more gravity is acting upon it. A star must burn a lot of gases to keep it from collapsing in on itself. Therefore, it must exert a lot of energy. –However, gravity always wins! Massive stars: die quickly Less massive stars: live for a really long time Average Stars: (Our Sun): live about 10 billion years

40. White Dwarfs A low mass adult star turns into a red giant When it dies, it stops producing its own energy. (No longer being classified as a star) It collapses in on itself (to about the size of the Earth, but much more massive) It glows white hot until it cools off. (Never to be seen again - takes a really long time to do this!!!) A white dwarf is not a star since it is not doing fusion any more! One tsp. of a white dwarf would weigh several tons!

41. White Dwarf with a Planetary Nebula Medium-mass stars, like our Sun, will die the same way as low mass stars EXCEPT: During the last moments of being a star, it will shed its outer layer of gases (instead of exploding) and form a planetary nebula (has nothing to do with planets) The core will collapse into a white dwarf, illuminating the nebula This will be the fate of our own sun roughly 5 billion years from now.

42. White Dwarf with a Planetary Nebula

43. Supernova Is an exploding star Happens to stars that are at least 7 times more massive than our own sun right before they die. Is a result of a red giant burning up iron at its core. Iron is too heavy. When iron fusion occurs in the core, it will collapse at an incredible rate. It will then explode, releasing gas and dust, and begin to fuse the gases into heavier elements.

44. Supernovas viewed from Earth Supernovae are among the brightest events in the universe... the bright spot in the lower left is a supernova observed in 1994, and is almost as bright as all the other stars in the centre of the spiral galaxy. This galaxy and supernova are 52 million lights years from Earth.

45. What Supernovas form…

46. Neutron Stars These objects are not really stars at all. After a supernova occurs, half of the star’s material is ejected out into space. The remaining material collects into a small dense sphere. The object is made up of only neutrons. –Protons and electrons are forced together to form these neutrons.

47. These objects are extremely small and extremely dense. –It has a mass several times greater than our own sun –One tsp. of a neutron star would weigh about a million tons! it is about the size of a small city. It rotates very rapidly.

48. This is how the size of a neutron star matches with the size of the city of Chicago

49. Pulsars Are neutron stars that rotate very rapidly and give off light or radio waves When the waves reach the earth they come in as pulses of waves hence the name pulsars

50. Pulsar Diagram

51. Black Holes Very massive stars become SUPER RED GIANTS EXPLODE as supernovae And become Black holes! VERY DENSE but smaller than the point on your pencil!

52. Their gravity is so great that even light (the fastest moving thing in our universe) cannot escape it. Event horizon - the surface of a black hole –Objects won’t get “sucked” into a black hole unless they are within this boundary Singularity- central point of a black hole