Lecture 4 and 5, ASTA01

1. Lecture 4 and 5, ASTA01 Chapter 2User’s Guide to the Sky:Patterns and Cycles

2. On 13 Sept 2012, NASA Martian rover Curiosity doubles up as astronomer • Eclipse (or transit) of moon Phobos in front of the Sun in the sol 43 of robot (Martian day 43) Watch also the 2010 eclipse at http://www.youtube.com/watch?v=ViiriVhIhjE

3. Eclipses • Eclipses are due to a seemingly complicated combination of apparent motions of the Sun and Moon. • However, they are actually easy to predict once all the cycles are understood. • Watch a total eclipse of the sun seen from Turkey in 2006 on Youtube

4. Eclipses • For some, eclipses are alsoamong the mostspectacular of nature’ssights one can witness.

5. Solar Eclipses • From Earth, you can see a phenomenon that is not visible from most planets. • Because the Sun is 400 times larger than our Moon and, on the average, 390 times farther away, the Sun and Moon have nearly equal angular apparent diameters. • Thus, the Moon is just about the right size to cover the bright disk of the Sun and cause a solar eclipse. • In a solar eclipse, it is the Sun that is being hidden (eclipsed) and the Moon that is ‘in the way.’

6. Geometry of solar eclipses

7. Solar Eclipses • A shadow consists oftwo parts. • The umbra is the regionof total shadow. • For example, if you werein the umbra of theMoon’s shadow, you wouldsee no portion of the Sun. • The umbra of the Moon’sshadow usually just barelyreaches Earth’s surface andcovers a relatively small circular zone.

8. Solar Eclipses • Standing in that umbral zone, you would be in total shadow – unable to see any part of the Sun’s surface. • This is called a total eclipse.

9. Solar Eclipses • If you moved into the penumbra, you would be in partial shadow, but could also see part of the Sun peeking around the edge of the Moon. • This is called a partial eclipse.

10. Solar Eclipses • If you are outside the penumbra, you see no eclipse at all.

11. Solar Eclipses • Because of the Moon’s orbital motion and Earth’s rotation, the Moon’s shadow sweeps rapidly across Earth in a long, narrow path of totality. • If you want to see a total solar eclipse, you must be in the path of totality.

12. Solar Eclipses • When the umbra of the Moon’s shadow sweeps over you, you see one of the most dramatic sights in the sky – the totally eclipsed Sun.

13. Solar Eclipses • The eclipse begins as the Moon slowly crosses in front of the Sun. • It takes about an hour for the Moon to cover the solar disk.

14. Solar Eclipses • As the last sliver of Sun disappears, dark falls in a few seconds. • Automatic street lights come on, drivers of cars turn on their headlights, and birds go to roost. • The sky usually becomes so dark you can even see the brighter stars.

15. Solar Eclipses • The darkness lasts only a few minutes. • This is because the umbra is never more than 270 km in diameter on Earth’s surface and sweeps across the landscape at over 1600 km/hr. • The period of totality lasts on average only 2 or 3 minutes and never more than 7.5 minutes.

16. Solar Eclipses • During totality you can see subtle features of the Sun’s atmosphere. • These include red flame-like projections that are visible only during those moments when the brilliant disk of the Sun is completely covered by the Moon.

17. Solar eclipse 2012

18. Solar eclipse 2012

19. Solar eclipse – the active sun 1980

20. Solar eclipse - the active sun The white streamers are the upper layers of the solar atmosphere called Corona (that is, crown). It is a nonuniform, outflowing part of the sun, gradually becoming the rarified solar wind that flows past the Earth and planets (mainly, ionized hydrogen and helium, and the electrons) Streamers emanate from regions called coronal holes, where the magnetic field lines leave the sun & flow out into space

21. Solar eclipse - the active sun • How does the sun get its corona? • Hot temperature causing the • outflow – 1 mln degrees C, • Maybe due to shock waves • (ii) Magnetic fields, the so-called • Reconnection of loops. • Loops are regions where gas • flows along magnetic field tubes. Ultraviolet picture of the coronal loop

22. The sun is an active star Solar flare Ultraviolet picture of the coronal loop

23. The sun is an active star (here, in extreme UV) Solar Dynamics Observatory – satellite observatory http://www.youtube.com/watch?v=QrmUUcr4HXg

24. Coming back to….. Solar Eclipses • As soon as part of the Sun’s disk reappears, the fainter features vanish in the glare. • The period of totality is over. • The Moon moves on in its orbit and, in an hour the Sun, is completely visible again.

25. Solar Eclipses • Sometimes, when the Moon crosses in front of the Sun, it is too small to fully cover the Sun. • Then, you would witness an annular eclipse. • This is a solar eclipse in which an annulus (‘ring’) of the Sun’s disk is visible around the disk of the Moon. The eclipse never becomes “total”. It never quite gets totally dark.

26. Solar Eclipses • Annular eclipses occur because the Moon follows a slightly elliptical orbit around Earth. • If the Moon is in the farther part of its orbit during totality, its apparent diameter will be less than the apparent diameter of the Sun, and you see an annular eclipse. • Also, Earth’s orbit is slightly elliptical. • As a result, both the Earth-to-Sun distance and the apparent diameter of the solar disk vary slightly. • These contribute to the effect of the Moon's varying apparent size.

27. Solar Eclipses • Solar eclipses can be misleading – tempting you to look at the Sun in spite of its brilliance and thus risking your eyesight.

28. Solar Eclipses • During the few minutes of totality, the brilliant disk of the Sun is hidden, and it is safe to look at the eclipse. • However, the partial eclipse phases and annular eclipses can be dangerous, and people don’t necessarily know which type to expect.

29. Solar Eclipses • If you plan to observe a solar eclipse, remember that the Sun is bright enough to burn your eyes and cause permanent damage if you look at it directly. • This is true whether there is an eclipse or not.

30. Solar Eclipses • The figure demonstrates a safe way to observe the partially eclipsed Sun. • Or look through very much darkened glass like welders hood • Don’t look through sunglasses

31. Solar Eclipses • upcoming solar eclipses

32. Lunar Eclipses • Occasionally, you can see the Moon darken and turn copper-red in a lunar eclipse. • Time lapse video

33. Lunar Eclipses • A lunar eclipse occurs at full Moon when the Moon moves through Earth’s shadow. • As the Moon shines only by reflected sunlight, you see the Moon gradually darken as it enters the shadow.

34. Lunar Eclipses • If you were on the Moon and in the umbra of Earth’s shadow, you would see no portion of the Sun.

35. Lunar Eclipses • If you moved into the penumbra, you would be in partial shadow and would see part of the Sun peeking around the edge of Earth – so the sunlight would be dimmed but not extinguished.

36. Lunar Eclipses • In a lunar eclipse, it is the Moon that is being hidden in the Earth’s shadow and Earth that is ‘in the way’ of the sunlight.

37. Lunar Eclipses • If the orbit of the Moon carries it through the umbra of Earth’s shadow, you see a total lunar eclipse.

38. Lunar Eclipses • As you watch the Moon, it first moves into the penumbra and dims slightly, then more

39. Lunar Eclipses • In about an hour, the Moon reaches the umbra, and you see the umbral shadow darken part of the Moon. • It takes about an hour for the Moon to enter the umbra completely and become totally eclipsed.

40. Lunar Eclipses • The period of total eclipse may last as long as 1 hour 45 minutes; however, the timing of the eclipse depends on where the Moon crosses the shadow.

41. Lunar Eclipses • When the Moon is totally eclipsed, it does not disappear completely. • Though it receives no direct sunlight, the Moon in the umbra receives some sunlight that is refracted through Earth’s atmosphere.

42. Lunar Eclipses • If you were on the Moon during totality, you would not see any part of the Sun. • It would be entirely hidden behind Earth. • You would be able to see Earth’s atmosphere illuminated from behind by the Sun.

43. Lunar Eclipses • The red glow from this ring consisting of all the Earth’s simultaneous sunsets and sunrises illuminates the Moon during totality and makes it glow coppery red.

44. Lunar Eclipses • If the Moon passes a bit too far north or south of Earth’s shadow, it may only partially enter the umbra. • Then, you see a partial lunar eclipse.

45. Lunar Eclipses • The part of the Moon that remains outside the umbra in the penumbra receives some direct sunlight. • The glare is usually great enough to prevent you from seeing the faint coppery glow of the part of the Moon in the umbra.

46. Lunar Eclipses • Lunar eclipses always occur at full moon but not at every full moon. • The Moon's orbit is tipped about 5 degrees to the ecliptic. • So, most full moons cross the sky north or south of Earth’s shadow and there is no lunar eclipse that month. • For the same reason, solar eclipses always occur at new moon but not at every new moon.

47. Lunar Eclipses • Although there are usually no more than one or two lunar eclipses each year, it is not difficult to see one. • You need only be on the dark side of Earth when the Moon passes through Earth’s shadow. • That is, the eclipse must occur between sunset and sunrise at your location to be visible.

48. Lunar Eclipses • upcoming lunar eclipses

49. Lunar Eclipses • The orientation of the Moon's orbit in space varies slowly. • As a result, solar and lunar eclipses repeat in a pattern called the Saros cycle lasting 18 years 11 days 8 hours. Ancient people who understood the Saros cycle could predict eclipses without understanding what the Sun and Moon really were.

50. Eclipses in historical fiction • Bolesław Prus “Faraon” (1897) described a turbulent period of Egyptian history in the 9th century B.C., when the priests took power from the pharaohs. They used the knowledge of an upcoming solar eclipse to pretend only they are favored by gods & staged an uprising.