1. C13 : Stars and Galaxies

2. Section 1 : Stars Demo : expanding universe (p. 369) Q: What is a star ? A: large, massive, hot ball of gas held together by gravity and gives off light. Q: What is a Constellation? A : a number of stars that appear to form a pattern.

3. Constellations

4. Constellations are not real The purpose is to help to locate stars.

6. Stars in a constellation often have no relationship to each other. Modern astronomy divides the sky into 88 constellations.

7. Circumpolar Constellations As Earth rotates, Ursa Major & Ursa Minor and other constellations in the northern sky circle around Polaris. They appear to move because Earth is rotating. The stars appear to complete one full circle about 24 hours. Visible all year long due to their unique position.

8. As Earth orbits the Sun, different constellations come into view while others disappear.

9. Absolute & Apparent Magnitudes When you refer to the brightness of a star, you can refer to its absolute magnitude or its apparent magnitude. Absolute magnitude – actual brightness of a star Apparent magnitude – brightness of a star that we see

10. Parallax It can be used to determine the distance of the star from the Earth. Parallax is the apparent shift in the position of an object when viewed from 2 different positions. Demo The nearer an object is to the observer, the greater its parallax.

11. Good to cal. distance for near star. The parallax angle of the closer object is greater than that of the farther object.

12. Properties of Stars Color: depends on temperature from coolest to hottest : red, orange, yellow, white, blue Size : depends on original mass of gas cloud and age/lifestage of star from smallest to biggest : white dwarf, main- sequence, giants, supergiants

13. Brightness : depends on surface temp, size, dist from Earth The light from a star comes from nuclear reactions in center of a star A star must have a balance between : 1.press due to temp in core 2.Gravity Study the composition of stars by observing their spectra.

14. Section 2 : The Sun

15. It is the closest star to Earth. Center of the solar system. It is an enormous ball of gas. It is yellow in color. It is in the main sequence. Brightness : medium The size of the core ~ the size of Jupiter. 92 % hydrogen.

16. The Sun has enough hydrogen to last 5 billion years. It produces energy by nuclear fusion Energy is transferred by convection and radiation.

17. The Sun’s Atmosphere Photosphere – lowest layer of the Sun’s atm. The layer from which light is given off. 6000 K ~ 5700 ºC. Chromosphere – the layer on top of photosphere. About 2000 km thick.

18. Transition Zone – 2000 km to 10 000km thick. Corona – largest layer of the Sun’s atm. - extends millions of km into space. - 2 million K - charged ptles escape here as solar wind.

19. Surface Features Sunspots – dark color spots on the surface becoz they are cooler than surrounding areas. - they are caused by intense magnetic storms on the Sun. - sunspots move because Sun rotates. Faster at equator (25 days/rotation) and slower at poles (35 days/rotation).

20. - sunspots are not permanent. - sunspot max : times when many large sunspots occur. Every 10 to 11 years. - sunspot min : occur in between sunspot max.

21. Prominences and Flares

22. Prominence : the intensive magnetic fields associated with sunspots causes prominences. They are huge, arching columns of gas.

23. Solar flares : gases near a sunspot shooting outward at high speed. CMEs (Coronal mass ejections) - occur when large amts of electrically- charged gas are ejected suddenly from corona. - 2 or 3 times each day during a sunspot max.

24. It can damage satellites in orbits. Interfere radio equipment. It causes auroras. - high energy ptles contained in CMEs and solar wind are carried past Earth’s magnetic field → g enerates electric current toward Earth’s poles → i onized gases in atm → ions recombine with electrons → produce ight → aurora.

25. Aurora

26. The Sun – An Average Star Middle-aged Brightness is average Yellow light Light reaches Earth ~ 8 mins Not close to any other stars Closest star system to the Sun – The Alpha Centauri System (triple star system)

27. Section 3 : Evolution of Stars (I) Classifying Stars High temps → brighter absolute magnitude Hertzsprung – Russell (H-R) diag.

28. Most stars (abt 90% of all stars) fit into a diagonal band → main sequence Bigger, hot, blue, bright stars → upper left Smaller, cool, red, dim stars → lower right (most stars found here) Remaining 10% stars not found in main sequence :

29. 1.White dwarfs – hot but not bright - small - lower left of H-F diag 2.Red Giants – large - bright but not hot - upper right - supergiants (largest giants)

30. Antares Supergiant 400 light years from Earth 3 500 K 16th brightest star in the sky 300 x diameter of Sun 11 000 times brighter than Sun

31. How do stars shine/generate energy? Core of Sun → high temp → H atoms fuse into He → releases huge amt of energy 4 H nuclei combine to create 1 He nucleus Mass of 1 He nucleus < 4 H nuclei → mass is lost → energy is produced E = mc 2 Eg: m=1 kg E = 1 x (3x10 8 ) 2 = 9 x 10 16 J → 2.8 million US hours / year

33. Demo P. 382 “make a model”

34. Evolution of Stars When hydrogen nuclei (protons) depleted → star loses its main sequence status Brightest stars → less than 1 million years to deplete Dimmest stars → many billions of years Sun – main sequence - life span ~ 10 billion years - 5 billion years left

35. What is a Nebula? large and massive cloud of gas and dust particles

36. How a star is formed? Due to supernova or collisions of 2 clouds of nebula → ptles of gas and dust exert gravitational force on each other → nebula contracts → instability within nebula → nebula breaks apart into smaller pieces → ptles in smaller pieces of nebula move closer → T increases (ptles collide more as they are closer) → protostar → core reaches 10 million K → fusion begins → star is formed and is stable → stars in main sequence

37. Star is stable in main sequence becoz heat from fusion causes Press increases → Press balances the gravity → when hydrogen in the core is depleted → gravity > press → core contracts → T inc in core → outer layer expands (more He) → outerlayer temp dec → core temp reaches 100 million K → He nuclei fuse to form Carbon → giant

38. How a white dwarf is formed? After the star’s core uses much of its helium (this stage is after giant. The hydrogen fuel has used up → does not produce any new helium nuclei → helium combine to form carbon) → contracts even more (no more fusion → gravity pulls in) → outer layers escape into space → leaves behind the hot, dense core.

39. Size of Earth Eventually the white dwarf will cool and stop giving light

40. Supergiants and Supernovas Stars more than 8x massive than Sun → evolution occurs more quickly and more violently Massive stars → core heats up to higher temps → heavier elements form by fusion (becoz higher temp is needed to fuse bigger elements. Eg : He → C needs higher temp) → star expands into supergiant → iron forms in the core → iron atomic structure does not release energy through fusion → core collapses (exploded) → shock wave

41. Neutron Stars If the collapsed core of a supernova (after the explosion) is ~ 1.4 → 3 times the mass of Sun → shrink to ~ 20 km in diameter → only neutrons can exist in the dense core → neutron star

42. Black Holes If the collapsed core of a supernova is > 3 times the mass of Sun → continue to collapse → until it becomes a point → gravity near this mass is so strong that nothing can escape from it, not even light → black hole Black hole is not like a giant vacuum cleaner sucking in distance objects Only if the object crosses it → pulled into the hole Stars and planets can orbit around a black hole

43. Section 4 : Galaxies and the Universe Galaxy : a large group of stars, gas, and dust held together by gravity. (also includes planets) Milky Way Galaxy : our galaxy Galaxies are separated by huge distances – millions of light years apart. Galaxies are grouped together into clusters Stars (gp) → galaxies(gp) → clusters Milky Way belongs to Local Group Cluster (~45 galaxies)

44. 3 Major types of Galaxies 1. Spiral Galaxies Whirlpool – like Lots of dust in spirals Closer to center → faster it orbits Milky Way

45. 2. Elliptical Galaxies 3-D ellipses : football Round : soccer ball No spirals Very little dust

46. 3. Irregular Galaxies No recognizable shape Smallest type of galaxy 2 irregular galaxies orbit the Milky Way → Clouds of Magellan

47. The Milky Way Galaxy ~ 1 trillion stars Stars (including Sun) orbit around the core. It takes 225 million years for the Sun to make 1 round around the core. Has a supermassive black hole at its center. It is about 2.5 million times as massive as the Sun.

48. Origin of the Universe 1.Steady State Theory – the universe always has been the same as it is now. The universe always existed and always will. Evidence indicates that the universe was different in the past.

49. 2. Oscillating Model – universe began with expansion → expansion slowed → universe contracted → process began → oscillating back and forth. 3. Big Band Theory – started with a big band → expanding ever since.

50. Doppler Shift If a star is moving toward Earth, its wavelength of light are compressed → light from the star is shifted to the blue end of the spectrum. If a star is moving away from Earth, its wavelength stretched → light from the star is shifted to the red end of the spectrum.

53. Red Shift → Universe is expanding Quick Demo (p.389)