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The Copernican RevolutionThe Birth of Modern Science                              1B                              1B
What do we see in the sky?       The stars move in the sky but        not with respect to each other       The planets (...
Timeline        Galileo                1564-1642               Newton                                        1642-1727    ...
Geocentric(Ptolemaic) System  The  accepted model for   1400 years  The earth is at the center  The Sun, stars, and   p...
Heliocentric (Copernican) System              Sun at center (heliocentric)              Uniform, circular motion        ...
In the heliocentric model, apparent retrograde motion of the planets is a direct consequence of the Earth’s motion       ...
Geocentric vs. HeliocentricHow  do we decide between two theories?Use the Scientific method: ◦ These are both explanatio...
Phases of VenusHeliocentric predicts that Venus should show a full phase, geocentric does notUnfortunately, the phases o...
Geocentric vs. HeliocentricAgainst   heliocentric ◦ It predicted planetary motions and events no better   than the Geocen...
Stellar ParallaxParallax  caused by the motion of the earth orbiting the SunNot observed with the naked eyeThe heliocen...
Misconceptions1.   The Copernican model has a force between the sun and     the planets. Actually, the natural motion of t...
Galileo GalileiTurneda telescope toward the heavensMade observations that: ◦ contradicted the perfection of the heavens ...
Tycho Brahe Had  two sets of astronomical  tables: one based on Ptolemy’s  theory and one based on  Copernicus’. He foun...
The skies changeTycho observed 2 phenomena that showed the heavens DO change: ◦ In November 1572, Tycho noticed   a new s...
Johannes Kepler Kepler  succeeded Tycho as the Imperial mathematician (but at  only 1/3 the salary of the nobleman) Kepl...
Astronomia novaPublished    in 1609, The New Astronomy was just that, it revolutionized the fieldIt predicted planetary ...
Kepler’s first Law                     The   orbital                      paths of the                      planets are  ...
Kepler’s second law                An   imaginary                 line connecting                 the Sun to any         ...
Kepler’s Third LawThe  square of a planet’s orbital period is proportional to the cube of its semi-major axis.Kepler orb...
Planetary PropertiesPlanet    Orbital       Orbital semi-major     Orbital          eccentricity, axis, a                p...
Other Solar System BodiesKepler  derived his laws for the 6 planets known to him. The laws also apply to the 3 discovered...
A force for planetary motionNewton    proposes a force which controls the motion of the planets – GRAVITYThe larger the ...
Gravity          1B
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Astro101 1b

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Transcript of "Astro101 1b"

  1. 1. The Copernican RevolutionThe Birth of Modern Science 1B 1B
  2. 2. What do we see in the sky? The stars move in the sky but not with respect to each other The planets (or “wanderers”) move differently from stars ◦ They move with respect to the stars ◦ They exhibit strange retrograde motion What does all this mean? How can we explain these movements? What does the universe 1B look like?
  3. 3. Timeline Galileo 1564-1642 Newton 1642-1727 TychoCopernicus 1546-1601 Kepler1473-1543 1571-1630 1B
  4. 4. Geocentric(Ptolemaic) System  The accepted model for 1400 years  The earth is at the center  The Sun, stars, and planets on their spheres revolve around the earth: explains daily movement  To account for unusual planetary motion epicycles were introduced  Fit the Greek model of heavenly perfection – spheres are the perfect shape, circular the perfect motion 1B
  5. 5. Heliocentric (Copernican) System Sun at center (heliocentric) Uniform, circular motion ◦ No epicycles (almost)  Moon orbited the earth, the earth orbited the sun as another planet Planets and stars still on fixed spheres, stars don’t move The daily motion of the stars results from the Earth’s spin The annual motion of the stars results from the Earth’s orbit 1B
  6. 6. In the heliocentric model, apparent retrograde motion of the planets is a direct consequence of the Earth’s motion 1B
  7. 7. Geocentric vs. HeliocentricHow do we decide between two theories?Use the Scientific method: ◦ These are both explanations based on the observation of retrograde motion ◦ What predictions do the models make? ◦ How can these predictions be tested? 1B
  8. 8. Phases of VenusHeliocentric predicts that Venus should show a full phase, geocentric does notUnfortunately, the phases of Venus cannot be observed with the naked eye 1B
  9. 9. Geocentric vs. HeliocentricAgainst heliocentric ◦ It predicted planetary motions and events no better than the Geocentric system ◦ The earth does not move (things do not fly off) ◦ The earth is different from the heavens (from Aristotle – the heavens are perfect and unchanging) and cannot be part of the heavensFor heliocentric ◦ Simplified retrograde motion, but epicycles were necessary to account for the planets’ changing speed ◦ The distances to the planets could be measured. These distances were ordered, and therefore 1B aesthetically pleasing to the philosophy of the day
  10. 10. Stellar ParallaxParallax caused by the motion of the earth orbiting the SunNot observed with the naked eyeThe heliocentric model predicts stellar parallax, but Copernicus hypothesizes that the stars are too far away (much farther than the earth from the Sun) for the parallax to be measurable 1B with the naked eye
  11. 11. Misconceptions1. The Copernican model has a force between the sun and the planets. Actually, the natural motion of the celestial spheres drove the planetary motions.2. The Copernican model was simpler than the Ptolemaic one. In fact, though Copernicus eliminated circles to explain retrograde motion, he added more smaller ones to account for nonuniformities of planetary motions.3. The Copernican model predicted the planetary motions better. Because both models demanded uniform motion around the centers of circles, both worked just about as well – with errors as large as a few degrees at times. 1B
  12. 12. Galileo GalileiTurneda telescope toward the heavensMade observations that: ◦ contradicted the perfection of the heavens  Mountains, valleys, and craters on the Moon  Imperfections on the Sun (sunspots) ◦ Supported the heliocentric universe  Moons of Jupiter  Phases of Venus – shows a full phase 1B
  13. 13. Tycho Brahe Had two sets of astronomical tables: one based on Ptolemy’s theory and one based on Copernicus’. He found that both tables’ predictions were off by days to a month. He believed that much better tables could be constructed just by more accurate observations. Tycho’s homemade instruments improved measurement precision from ten minutes of arc (which had held since Ptolemy) to less than one 1B
  14. 14. The skies changeTycho observed 2 phenomena that showed the heavens DO change: ◦ In November 1572, Tycho noticed a new star in the constellation Cassiopeia ◦ Comet of 1577  Prior to this sighting, comets were thought to be atmospheric phenomena because of the immutability of the heavens  But neither the star nor the comet changed position as the observer moved, as expected for atmospheric phenomena 1B
  15. 15. Johannes Kepler Kepler succeeded Tycho as the Imperial mathematician (but at only 1/3 the salary of the nobleman) Kepler worked for four years trying to derive the motions of Mars from Brahe’s observations In the process, he discovered that the plane of the earth’s orbit and the plane of Mars’ (and eventually the other planets) passed through the sun Suspecting the sun had a force over the planets, he investigated magnetism While this is not true, it did lead him to the idea of elliptical orbits “With reasoning derived from physical principles agreeing with experience, there is no figure left for the orbit of the planet except a perfect ellipse.” 1B
  16. 16. Astronomia novaPublished in 1609, The New Astronomy was just that, it revolutionized the fieldIt predicted planetary positions as much as ten times better than previous modelsIt included physical causes for the movement of the planetsThe ideas of the Greeks were gone – the heavens no longer were perfect, immutable, or different from the earth 1B
  17. 17. Kepler’s first Law The orbital paths of the planets are elliptical (not circular), with the Sun at one focus. 1B
  18. 18. Kepler’s second law An imaginary line connecting the Sun to any planet sweeps out equal areas of the ellipse in equal intervals of time. 1B
  19. 19. Kepler’s Third LawThe square of a planet’s orbital period is proportional to the cube of its semi-major axis.Kepler orbit demonstration: http://csep10.phys.utk.edu/guidry/java/kepler/kep 1B
  20. 20. Planetary PropertiesPlanet Orbital Orbital semi-major Orbital eccentricity, axis, a period,P e (Astronomical units) (Earth years)Mercury 0.206 0.387 0.241Venus 0.007 0.723 0.615Earth 0.017 1.000 1.000Mars 0.093 1.524 1.881Jupiter 0.048 5.203 11.86Saturn 0.054 9.537 29.42Uranus 0.047 19.19 83.75Neptune 0.009 30.07 163.7Pluto 0.249 39.48 248.0 1B
  21. 21. Other Solar System BodiesKepler derived his laws for the 6 planets known to him. The laws also apply to the 3 discovered planets and any other body orbiting the Sun (asteroids, comets, etc.) 1B
  22. 22. A force for planetary motionNewton proposes a force which controls the motion of the planets – GRAVITYThe larger the mass, the larger the force of gravityThe further the distance, the smaller the force of gravityKepler’s third law can be derived from Newton’s law of gravityF = GMm/r2 = mg 1B
  23. 23. Gravity 1B
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