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Week #1

Week #1. A Grand Tour of the Heavens. Introduction. A stronomy is in a golden age, filled with the excitement of new discoveries and a deeper understanding of the Universe, our home—and what an enthralling universe it is!. Peering through the Universe: A Time Machine.

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Week #1

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  1. Week #1 A Grand Tour of the Heavens

  2. Introduction • Astronomy is in a golden age, filled with the excitement of new discoveries and a deeper understanding of the Universe, our home—and what an enthralling universe it is!

  3. Peering through the Universe:A Time Machine • Astronomers have deduced that the Universe began almost 14 billion years ago.

  4. Speed of Light: A Time Machine • One fundamental fact allows astronomers to observe what happened in the Universe long ago: • Light travels at a finite speed, 300,000 km /sec (equal to 186,000 miles per second), or nearly 10 trillion km per year. • As a result, if something happens far away, we can’t know about it immediately.

  5. Speed of Light: • Light from the Moon takes about a second to reach us (1.3 seconds, more precisely), so we see the Moon as it was roughly one second ago. • Light from the Sun takes about eight minutes to reach us. • Light from the nearest of the other stars takes over four years to reach us; we say that it is over four “light-years” away. • Once we look beyond the nearest stars, we are seeing much farther back in time. • Even for the most nearby other galaxies, light has taken hundreds of thousands, or even millions, of years to reach us.

  6. Peering through the Universe:A Time Machine • When we observe these farthest objects, we see them as they were billions of years ago. • How have they changed in the billions of years since? • Are they still there? • The observations of distant objects that we make today show us how the Universe was a long, long time ago!

  7. 1.2 How Do We Study ThingsWe Can’t Touch? • In addition to taking photographs of celestial objects, astronomers break down an object’s light into its component colors to make a spectrum, much like a rainbow.

  8. 1.2 How Do We Study ThingsWe Can’t Touch? • Combining views in the visible part of the spectrum with studies of invisible radiation gives us a more complete idea of the astronomical object we are studying than we could otherwise have.

  9. How Do We Study ThingsWe Can’t Touch? • Giant telescopes on mountaintops collect visible light with mirrors as large as 10 meters across.

  10. How Do We Study ThingsWe Can’t Touch? • The Chandra X-ray Observatory produces clear images of a wide variety of objects using the x-rays they emit.

  11. Finding Constellations in the Sky: • The major star groups are called constellations. • These constellations were given names, occasionally because they resembled something • Scorpius, the Scorpion • honor a hero or other subject of a story.

  12. Finding Constellations in the Sky • The International Astronomical Union put the scheme of constellations on a definite system in 1930. • The sky was officially divided into 88 constellations with definite boundaries, and every star is now associated with one and only one constellation. • But the constellations give only the directions to the stars, and not the stars’ distances. • Individual stars in a given constellation generally have quite different distances from us. These stars aren’t physically associated with each other, and they were born at different times and locations.

  13. Finding Constellations in the Sky • Asterisms: • The Big Dipper, for example, is an asterism but isn’t a constellation, since it is but part of the constellation Ursa Major (the Big Bear).

  14. The Autumn Sky: • Polaris - Known as the “north star,” Polaris is not one of the brightest or nearest stars in the sky, but is well known because it is close to the direction of the celestial north pole.

  15. The Autumn Sky: • Almost an equal distance on the other side of Polaris is a “W”-shaped constellation named Cassiopeia.

  16. The Autumn Sky • Andromeda, who in Greek mythology was Cassiopeia’s daughter. • In Andromeda, on a very dark night you might see a faint, hazy patch of light; this is actually the center of the nearest large galaxy to our own, and is known as the Great Galaxy in Andromeda, or the Andromeda Galaxy.

  17. Andromeda Galaxy:

  18. The Autumn Sky: • Great Square of Pegasus. • One of the corners of this asterism is actually in the constellation Andromeda. • “The Milky Way” crossing the sky high overhead, passing right through Cassiopeia. • This dim band with ragged edges, which marks the plane of our disk-shaped galaxy has many dark patches that make rifts in its brightness.

  19. The Milky Way:

  20. The Autumn Sky: • Perseus: • “Open clusters,” a type of grouping of hundreds of stars • “Double cluster in Perseus,” also known as h and (the Greek letter “chi”) Persei, provides two of the open clusters that are easiest to see with small telescopes.

  21. The Autumn Sky: • In 1603, Johann Bayer assigned Greek letters to the brightest stars and lower-case Latin letters to less-bright stars but in this case the system was applied to name the two clusters as well.

  22. The Autumn Sky: • Along the Milky Way in the other direction from Cassiopeia (whose “W” is relatively easy to find), we come to a cross of bright stars directly overhead. • This “Northern Cross” is an asterism marking part of the constellation Cygnus, the Swan. • In this direction, spacecraft detect x-rays whose brightness varies with time, and astronomers have deduced in part from that information that a black hole is located there.

  23. The Winter Sky: • As winter approaches, the constellations appear closer and closer to the western horizon for the same hour of the night. • To the south of the Milky Way, near Perseus, we can now see a group of six stars close together in the sky. (Pleiades)

  24. The Winter Sky: • The Pleiades (pronounced “plee´a-deez”), traditionally the Seven Sisters of Greek mythology, the daughters of Atlas. • These stars are another example of an open cluster of stars.

  25. The Winter Sky: • Farther toward the east, rising earlier every evening, is the constellation Orion, the Hunter. • Orion is perhaps the easiest constellation of all to pick out in the sky, for three bright stars close together in a line make up its belt. • A reddish star, Betelgeuse (“bee´tl-juice”) marks Orion’s armpit, and symmetrically on the other side of his belt, the bright bluish star Rigel (“rye´jel”) marks his heel. • Betelgeuse is an example of a red supergiant star; it is hundreds of millions of kilometers across, far bigger itself than the Earth’s orbit around the Sun!

  26. The Winter Sky: • Orion’s sword extends down from his belt. • Great Nebula in Orion, or the Orion Nebula. • It is a site where new stars are forming right now, as you read these words.

  27. The Winter Sky: • Sirius - the brightest star in the sky. Orion’s belt points directly to it. • Sirius appears blue-white, which indicates that its surface is very hot. • Sirius is so much brighter than the other stars that it stands out to the naked eye. • It is part of the constellation Canis Major, the Big Dog.

  28. The Winter Sky: • Back toward the top of the sky, between the Pleiades and Orion’s belt, is a group of stars that forms the “V”-shaped head of Taurus. • This open cluster is known as the Hyades (“hy´a-deez”). • The stars of the Hyades mark the bull’s face, while the stars of the Pleiades ride on the bull’s shoulder.

  29. The Spring Sky: • We can tell that spring is approaching when the Hyades and Orion get closer and closer to the western horizon each evening, and finally are no longer visible shortly after sunset.

  30. The Spring : • The Big Bear (Ursa Major) is overhead, and anything in the Big Dipper—which is part of the Big Bear—would spill out. • Leo, the Lion, is just to the south of the overhead point, called the zenith (follow the Pointers backward). • Leo looks like a backward question mark, with the bright star Regulus, the lion’s heart, at its base.

  31. The Spring Sky: • If we follow the arc made by the stars in the handle of the Big Dipper, we come to a bright reddish star, Arcturus, another supergiant. • Hercules, with its notable globular cluster M13, is rising in the east in the evening at this time of year.

  32. The Summer Sky: • A bright reddish star, Antares, is in the constellation Scorpius, the Scorpion, to the south. (“Antares” means “compared with Ares,” another name for Mars, because Antares is also reddish.)

  33. The Summer Sky: • Perseid Meteor Shower (August) • The rate of meteors tends to be substantially higher after midnight than before midnight, since our part of Earth has then turned so that it is plowing through space, crossing through the paths of pebbles and ice chunks that streak through the sky as they heat up.

  34. The Summer Sky: • The “variable star,” Delta Cephei, appears in the constellation Cepheus, which is midway between Cassiopeia and Cygnus. • Delta Cephei varies in brightness with a 5.4-day period.

  35. How Do You Take a Tape Measure to the Stars? • The distance (d) travelled by light or by an object is equal to the constant rate of travel (its speed v) multiplied by the time (t) spent travelling (d = vt).

  36. How Do You Take a Tape Measure to the Stars? • For the nearest hundreds of thousands of stars, we have recent results from a spacecraft that showed how much their apparent position shifts when we look at them from slightly different angles. • For more distant stars, we find out how far away they are by comparing how bright they actually (intrinsically) are and how bright they appear to be. • We often tell their intrinsic brightness from looking at their spectra.

  37. How Do You Take a Tape Measure to the Galaxies? • For the nearest galaxies, we search for stars whose specific properties we recognize. • Some of these stars are thought to be identical in type to the same kinds of stars in our own Galaxy whose intrinsic brightnesses we know. • Compare intrinsic brightness with apparent brightness to give distance. • For the farthest galaxies, we find distances using the 1920s discovery that shifts in color of the spectrum of a galaxy reveal how far away it is.

  38. The Value of Astronomy • Dawn of mathematics may have stemmed from ancient observations of the sky, made in order to keep track of seasons and seasonal floods in the fertile areas of the Earth. • Gravity and Motion: Observations of the motions of the Moon and the planets, which are free of such complicating terrestrial forces as friction and which are massive enough so that gravity dominates their motions.

  39. The Grandest Laboratory of All • The regions of space studied by astronomers serve as a cosmic laboratory where we can investigate matter or radiation, often under conditions that we cannot duplicate on Earth. • These studies allow us to extend our understanding of the laws of physics, which govern the behavior and evolution of the Universe.

  40. The Grandest Laboratory of All • A new importance has been given to astronomy by the realization that large asteroids and comets have hit the Earth every few tens of millions of years with enough power to devastate our planet. • Considered in this sense, astronomy is an investment in our future. • Nuclear Fusion • New Sources of Energy

  41. The Grandest Laboratory of All • The impact of astronomy on our conception of the Universe. • Discoveries that the Earth is not at the center of the Universe, or that the Universe has been expanding for billions of years has changed our view of ourselves.

  42. What Is Science? • Science is not merely a body of facts; it is also a process of investigation. • Scientific Method: The standards that scientists use to assess their ideas and to decide which to accept. • Science is reproducible: • Other scientists should be able to get essentially the same result by repeating the same experiment or observation.

  43. What Is Science? • Scientific Method: • Hypothesis: An educated guess. • Theory: If the hypothesis passes its tests and is established in some basic framework or set of equations. • An explanation about something that happens in nature

  44. What Is Science? • Peer Review: If the hypothesis or theory survives test after test, it is accepted as being “true.” • Scientific Law: A Statement about something that happens in nature. • Kepler’s laws of planetary motion • Newton’s laws of motion • Newton’s law of gravitation

  45. Why Is Science Far Better Than Pseudoscience? • “Pseudo” means that something is not authentic or sincere, in spite of it looking somewhat real. • Beliefs that may seem related to science but either have no present verification or are false. • Astrology • UFOs (unidentified flying objects)

  46. Why Is Science Far Better Than Pseudoscience? • Astrology: • Astrologers claim to be using astronomical objects to make their predictions • Astrology is an attempt to predict or explain our actions and personalities on the basis of the positions of the stars and planets now and at the instants of our births. • Astrology has been around for a long time, but it has never definitively been shown to work.

  47. Why Is Science Far Better Than Pseudoscience? • In fact, even the traditional astrological alignments are not accurately calculated, for the Earth’s pole points in different directions in space as time passes over millennia. • In truth, stars are overhead at different times of year compared with the case millennia ago, when the astrological tables that are often still in current use were computed. • At a given time of year, the Sun is usually in a different sign of the zodiac from its traditional astrological one. • The constellations are illusions; they don’t even exist as physical objects. • They are merely projections of the positions of stars that are at very different distances from us.

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