1. Temperature = Color H-R diagram graph

2. Astronomers classify stars in spectral classes by color/temperature

3. 30,000 Color (RED)blue yellow Temperature ºC 0 Rige l Sirius Sun

4. Luminosity- Brightness 3 factors control brightness of a star: –How big (size) it is –How hot (temperature)it is –How far away (distance)it is

5. Apparent Magnitude Hipparchus, 2 nd century B.C. Classified all the 1000 stars visible to the naked eye on a scale of 1 to 6. 1 = brightest Relative: ranking of brightness Brightness of a star as it appears when viewed from Earth Brightness of a star as it appears when viewed from Earth

6. Absolute Magnitude The “true” brightness (LUMINOSITY) Measurable: the amount of energy/sec Distance: if the stars were the same distance from Earth. (32.6 ly or 10 pc)

7. Hertzsprung-Russell Diagram (pg.626) Luminosity / absolute brightness dim bright 1- Surface temperature / color Cooler (RED) Hotter /blue 3000 K 30,000 K Cool and bright = red giant Hot and dim = blue dwarf

8. The Hertzsprung-Russell diagram isn’t just an orginazational chart for the the stars, but the life cycle of the stars!

9. The Life Cycle of the Stars! (pg 626-630)

10. Birth and Death of Stars The Life Cycle of Stars 28.3 page 628 : http://outreach.physics.utah.edu/Labs/StarLife/starlife_main.htmlhttp://outreach.physics.utah.edu/Labs/StarLife/starlife_main.html

11. Life Cycle of Stars

12. http://mail.colonial.net/~hkai ter/life_cycle_of_a_star.htm

13. Stellar Careers The lives of the stars seem to be “predestined” The MASS of a star determines … –what type of star it will be, –where it will be on the main sequence, and –how long it will live for. –What it will end up as at its death Each type of star has a particular series of events during their lifetime. Deaths can be spectacular!

14. The MASS of a star determines … what it will be

15. Stage 1 Nebula The space between stars is filled with gas and dust. called a nebula 99% of interstellar matter is hydrogen. Temperature: Cool Eventually gas “clumps” and compress

16. Life Cycle of a Star nebula young Death/old

17. Whatever the cause, the nebula begins to contract. As the nebula collapses, the temperature and density increase. As it contracts, it breaks into many clumps, which forms hundreds of stars of various masses. The size of each clump determines the mass of the star that will form.

18. Joseph Howard

19. Clumps / fragmentation These will become STARS

20. Stage 2 Protostar Still shrinking, getting denser Temperatures increase Core is contracting Recognizable as a ‘star’ Has a photosphere surface

21. Life Cycle of a Star nebula young Death/old protostar

22. “Duds” or Failed Stars Clumps without enough mass are too small to become stars They just cool and compact to become orbiting in space They just cool and compact to become brown dwarfs orbiting in space Gas Giant planet Jupiter is a failed star.

23. Life Cycle of a Star nebula young Death/old protostar Not enough mass to reach temps to fuse hydrogen Brown dwarf “dud” Gas giant planet: Jupiter

24. IF the protostar has enough temperature and luminosity to make it onto the H-R scale. IF the protostar has enough temperature and luminosity to make it onto the H-R scale. Its mass determines where it jumps on. http://outreach.physics.utah.edu/labs/star_life/s upport/HR_animated_real.html

25. Stage 3 A Star is Born! When the core reaches 10,000,000 K Nuclear FUSION begins Hydrogen fuel is fusing into helium A true star

26. Main Sequence, Hydrogen is fusing into helium A star spends 90% of it’s life as a main sequence star. This is it’s mature, adult stage. Our Sun will be here for 10 billion years

27. Main Sequence at Last Main Sequence at Last It reaches Equilibrium: its stable The heat & pressure of the gas expanding outward balances the GRAVITY that is pulling the matter inward

28. Life Cycle of a Star nebula young Death/old protostar Not enough mass to reach temps for fusion of hydrogen Brown dwarf Gas giant planet: Jupiter Main sequence star fuse hydrogen fuel 100 billion yrs.

29. Death of a Star Death of a Star

30. Life Cycle of a Star nebula young Death/old protostar Not enough mass to reach temps for fusion of hydrogen Brown dwarf Gas giant planet: Jupiter” Main sequence star 100 billion yrs. white dwarf black dwarf Fusing hydrogen for fuel

31. Life Span Massive stars use up their fuel faster, so they spend less than a 1 billion years as a main sequence The smaller mass stars spend 100 billions years as a main sequence star!

32. Stage 4: Running on Empty Star is aging, hydrogen fuel is used up, and helium is building up in the core. There is no heat to push out so gravity pushes in, the core becomes unbalanced and begins to collapse There is no heat to push out so gravity pushes in, the core becomes unbalanced and begins to collapse As it collapses, temperature increase until it reaches 100,000,000 K! Helium begins to fuse. Heat generated in the core, It EXPANDS

33. The outer layers are expanding and The outer layers are expanding and COOL It is now a It is now a RED GIANT Star begins leaving the main sequence It starts to become UNSTABLE

34. Leaving the Main Sequence Leaving the Main Sequence It’s a It’s a RED GIANT It is cooler, It is cooler, but bigger, but bigger, so it’s brighter so it’s brighter

35. Stage 5 Planetary Nebula Core continues fusion of helium. When helium fuel is gone, the core shrinks Outer gas layers are thrown-off as a Planetary Nebula Example: Planetary Nebula IC 418

36. Stage 6: The End All that is left is the core White Dwarf Red Giant

37. White Dwarf All that’s left is the core: very small (earth size), very dense (200 x’s more dense than Earth!), very HOT (100,000 K) core It will slowly cool over a billion years.

38. Life Cycle of a Star nebula young Death/old protostar Not enough mass to reach temps for fusion of hydrogen Brown dwarf “dud” Main sequence white dwarf black dwarf Fusing hydrogen for fuel Main sequence Red giant planetary white dwarf Black 10 billion yrs nebula dwarf Hydrogen fuel fusing helium fusing

39. Red Super Giants When the helium is fusing, temps increase, it expands, and becomes a and cools When the helium is fusing, temps increase, it expands, and becomes a SUPER RED GIANT and cools Gravity contracts the core until its heated enough to begin burning the next element, carbon. This process continues through the fusing of oxygen, neon, nickel, and silicon with the high mass star alternating between the blue giant phase and the red giant phase throughout. Large stars repeat this expansion and contraction cycle up to 7 times as their core elements keep fusing until they reach iron. Large stars repeat this expansion and contraction cycle up to 7 times as their core elements keep fusing until they reach iron. When the core becomes iron fusion ends Example: Betelgeuse

40. Supernova Supernova remnant Crab Nebula, remnant of a supernova that exploded in 1054 A.D. VERY MASSIVE stars: > 8 M When core collapses, density reaches astonishing 400,000,000,000,000 g/cm3 The core ‘overshoots’ its equilibrium point and rapidly ‘rebounds’ Core explodes in a high speed shockwave, blasting everything into space! http://www.maniacworld.com/Crab-Supernova-Explosion.html https://www.youtube.com/watch?v=9D05ej8u-gU most astounding fact

41. Final Stage for Massive Stars (Neutron Star or Black Hole) Stars less than 8 solar masses become dwarf stars (cool, dim, burnt out) Stars 8 solar masses or greater become neutron stars or black holes Neutron Star Black Hole Neutron Star Black Hole

42. Neutron Star When the iron core of a MASSIVE STAR is collapsing, it might stop. Leaving behind an extremely small, dense neutron star. When the iron core of a MASSIVE STAR is collapsing, it might stop. Leaving behind an extremely small, dense neutron star. Extreme density 10 18 kg/m3 Extreme density 10 18 kg/m3 Extremely small: size of a city Extremely small: size of a city Spin! Can emit a beam and pulse: Pulsar Spin! Can emit a beam and pulse: Pulsar

43. Life Cycle of a Star nebula young Death/old protostar Not enough mass to reach temps for fusion of hydrogen Brown dwarf Gas planet Jupiter Main sequence 100 billion yrs white dwarf black dwarf Fusing hydrogen for fuel Main sequence Red giant planetary white dwarf black 10 billion yrs nebula dwarf Hydrogen fuel fusing helium fusing Main sequence Super red Supernova! 2-100 million yrs. Giant explosion Neutron Star Black hole Hydrogen – helium – carbon- neon – oxygen - silicon …iron

44. The Universe http://www.youtube.com/watch ?v=3pAnRKD4raY http://www.youtube.com/watch ?v=3pAnRKD4raY At the 8:20 min. mark

45. The Expanding Universe Hubble discovered that the galaxies are moving in an ordered way Everywhere we look, galaxies are moving AWAY from us. Distance between galaxies is increasing. All galaxies receding away from each other in a universal recession

46. Hubble's Law. "The More Distant an Object is, the Greater is its Recessional Velocity."

47. The END - Death Stars iMovie Name of final object Starting Mass Time / Age / years Description Picture / Image Name of a familiar star as an example