* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download History of Astronomy
Lunar theory wikipedia , lookup
Observational astronomy wikipedia , lookup
Theoretical astronomy wikipedia , lookup
Kepler (spacecraft) wikipedia , lookup
De revolutionibus orbium coelestium wikipedia , lookup
Aquarius (constellation) wikipedia , lookup
Planets beyond Neptune wikipedia , lookup
Tropical year wikipedia , lookup
Astrobiology wikipedia , lookup
IAU definition of planet wikipedia , lookup
Definition of planet wikipedia , lookup
Planets in astrology wikipedia , lookup
Rare Earth hypothesis wikipedia , lookup
Solar System wikipedia , lookup
History of astronomy wikipedia , lookup
Planetary habitability wikipedia , lookup
Late Heavy Bombardment wikipedia , lookup
History of Solar System formation and evolution hypotheses wikipedia , lookup
Satellite system (astronomy) wikipedia , lookup
Comparative planetary science wikipedia , lookup
Astronomical unit wikipedia , lookup
Formation and evolution of the Solar System wikipedia , lookup
Extraterrestrial life wikipedia , lookup
Hebrew astronomy wikipedia , lookup
Ancient Greek astronomy wikipedia , lookup
Copernican heliocentrism wikipedia , lookup
Dialogue Concerning the Two Chief World Systems wikipedia , lookup
History of Astronomy Stonehenge • Dates from Stone Age (2800 B.C.) • Construction spanned 17 centuries Sun Dagger Chaco Canyon, NM • Sliver of light passes through carved stone at noon on the summer solstice Ancient Chinese • Observed the heavens, records of comets • Historical data still used today Ancient Greek Astronomy Ionia – the birthplace of science Greek Models of the Universe • Geocentric (Earth Centered) or Ptolemaic, A.D. 140 Ptolemaic model • http://www.csit.fsu.edu/%7Edduke/nmoon6.html Retrograde Motion of Mars Jupiter and Saturn Retrograde motion • http://antwrp.gsfc.nasa.gov/apod/ap011220.html Heliocentric Model (Sun centered) • Aristarchus (290 B. C.), forgotten for 1800 years Great Library of Alexandria Hypatia of Alexandria Astronomy in the Middle Ages Muslim astronomy • Key link from ancient Greeks during Dark Ages • Examples of Muslim terms: Zenith and star names such as Vega, Betelgeuse Nicolaus Copernicus (Mikołaj Kopernik) • Rediscovered Aristarchus’s heliocentric model De revolutionibus orbium coelestium (On the Revolutions of the Celestial Spheres) • Published just before his death in 1543 • Starting point of modern astronomy • Placed on the Catholic Church’s Index of Prohibited Books in 1616 Galileo Galilei • Built a telescope in 1609 • His work supported Copernicus • Found 4 moons orbiting Jupiter • Published Sidereus Nuncius (The Starry Messenger) in 1610 • Banned in 1616 Johannes Kepler • Contemporary of Galileo Kepler’s First Law • The orbital paths of the planets are elliptical, not circular, with the Sun at one focus Kepler’s 1st Law 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 Kepler’s second law • http://www.youtube.com/watch?v=_3OOK8a 4l8Y&feature=related • http://www.astro.virginia.edu/class/oconnell/ astr121/im/kepler-2ndanim-NS.gif Kepler’s Third Law • The square of a planet’s orbital period is proportional to the cube of its semimajor axis P2 = a3 where P is in Earth years and a is in astronomical units • 1 astronomical unit (AU) = avg. distance from the Earth to the Sun • Pluto’s semimajor axis (average distance from the Sun) is approximately 40. AU. Calculate the period of Pluto • a = 40. AU And a3 = 64,000 • P2 = a3 • P2 = 64,000 • P = √64,000 • P = 250 years Issac Newton • Published Philosophiae Naturalis Principia Mathematica in 1687 • Possibly most influential physics book ever written • Newtonian mechanics WHY the planets move according to Kepler’s Laws Newton’s inverse square law • The acceleration due to gravity is inversely proportional to the square of the distance 2.8 Newtonian Mechanics Escape speed: the speed necessary for a projectile to completely escape a planet’s gravitational field. With a lesser speed, the projectile either returns to the planet or stays in orbit. Newton’s Cannon • http://galileoandeinstein.physics.virginia.edu/ more_stuff/Applets/newt/newtmtn.html 2.7 Newton’s Laws Newton’s first law: An object at rest will remain at rest, and an object moving in a straight line at constant speed will not change its motion, unless an external force acts on it. 2.7 Newton’s Laws Newton’s second law: When a force is exerted on an object, its acceleration is inversely proportional to its mass: a = F/m Newton’s third law: When object A exerts a force on object B, object B exerts an equal and opposite force on object A. 2.7 Newton’s Laws Gravity On the Earth’s surface, acceleration of gravity is approximately constant, and directed toward the center of Earth 2.7 Newton’s Laws Gravity For two massive objects, gravitational force is proportional to the product of their masses divided by the square of the distance between them 2.8 Newtonian Mechanics Kepler’s laws are a consequence of Newton’s laws; first law needs to be modified: The orbit of a planet around the Sun is an ellipse, with the center of mass of the planet–Sun system at one focus. William Hershel • Discovered Uranus (1781), • Key figure of The Age of Enlightenment Caroline Hershel • Discovered several comets Einstein • Annus mirabilis (1905) • Published 4 articles in the Annalen der Physik Changed views on space, time, and mattermatter Carl Sagan Steven Hawking • Gravitational singularities • Black holes History of Planetariums • Antikythera mechanism mechanical computer • ~ 100 BC, Greek Jena Planetarium Germany, 1926 Buhl Planetarium Hayden Planetarium New York Summary of a few important concepts from chapter 2 • First models of solar system were geocentric but couldn't easily explain retrograde motion • Heliocentric model does; also explains brightness variations • Galileo's observations supported heliocentric model • Kepler found three empirical laws of planetary motion from observations Question 1 Mars, Jupiter, and Saturn show retrograde motion because a) planets move on epicycles. b) planets orbit the Sun in the same direction. c) Earth moves faster in its orbit. d) they are closer than Uranus. e) they rotate quickly on their axes. Question 1 Mars, Jupiter, and Saturn show retrograde motion because a) planets move on epicycles. b) planets orbit the Sun in the same direction. c) Earth moves faster in its orbit. d) they are closer than Uranus. e) they rotate quickly on their axes. As Earth overtakes and “passes” the outer planets, they seem to slow down and reverse direction. Question 2 How did the geocentric model account for day and night on Earth? a) The Earth rotated. b) The Sun rotated. c) The geocentric model couldn’t account for day and night. d) The Earth revolved around the Sun. e) The Sun orbited Earth. Question 2 How did the geocentric model account for day and night on Earth? a) The Earth rotated. b) The Sun rotated. c) The geocentric model couldn’t account for day and night. d) The Earth revolved around the Sun. e) The Sun orbited Earth. The geocentric model held that the Earth was motionless in the center of the universe. Question 3 Epicycles were used in Ptolemy’s model to explain a) why planets moved in the sky. b) why Earth was at the center. c) why retrograde motion occurred. d) why Earth wobbled on its axis. e) why inner planets were always seen near the Sun. Question 3 Epicycles were used in Ptolemy’s model to explain a) why planets moved in the sky. b) why Earth was at the center. c) why retrograde motion occurred. d) why Earth wobbled on its axis. e) why inner planets were always seen near the Sun. . Planets were assumed to move uniformly on an epicycle, as it moved uniformly around Earth. Question 4 The geocentric model was supported by Aristotle because a) stars don’t seem to show any parallax. b) we don’t feel as though Earth moves. c) objects fall toward Earth, not the Sun. d) we don’t see an enormous wind. e) All of the above were valid reasons. Question 4 The geocentric model was supported by Aristotle because a) stars don’t seem to show any parallax. b) we don’t feel as though Earth moves. c) objects fall toward Earth, not the Sun. d) we don’t see an enormous wind. e) All of the above were valid reasons. If the Earth rotated and orbited, we would feel its motion. In Aristotle’s time, the size of the solar system and distances to stars were assumed to be much, much smaller. Parallax was expected to be seen. Question 5 The heliocentric model assumes a) planets move on epicycles. b) Earth is the center of the solar system. c) the stars move on the celestial sphere. d) the Sun is the center of the solar system. e) Earth’s axis wobbles over 26,000 years. Question 5 The heliocentric model assumes a) planets move on epicycles. b) Earth is the center of the solar system. c) the stars move on the celestial sphere. d) the Sun is the center of the solar system. e) Earth’s axis wobbles over 26,000 years. Heliocentric models proposed by Aristarchus and others were considered wrong by Aristotle and his followers. Question 6 Copernicus’ important contribution to astronomy was a) proving planets move around the Sun in elliptical orbits. b) the theory of gravity. c) proposing a simpler model for the motions of planets in the solar system. d) discovering the Sun was not at the center of the Milky Way. e) discovering the four moons of Jupiter. Question 6 Copernicus’ important contribution to astronomy was a) proving planets move around the Sun in elliptical orbits. b) the theory of gravity. c) proposing a simpler model for the motions of planets in the solar system. d) discovering the Sun was not at the center of the Milky Way. e) discovering the four moons of Jupiter. His heliocentric model easily explained retrograde motion because planets orbited the Sun at different speeds. Question 7 Copernicus’ heliocentric model was flawed because a) he assumed planets moved in ellipses. b) he didn’t know about Uranus and Neptune. c) he couldn’t account for gravity. d) he couldn’t explain retrograde motion. e) he assumed planets moved in circles. Question 7 Copernicus’ heliocentric model was flawed because a) he assumed planets moved in ellipses. b) he didn’t know about Uranus and Neptune. c) he couldn’t account for gravity. d) he couldn’t explain retrograde motion. e) he assumed planets moved in circles. Copernicus’ model still needed small epicycles to account for observed changes in planetary speeds. Question 8 Who published the first astronomical observations made with a telescope? a) Hipparchus b) Galileo c) Tycho d) Copernicus e) Kepler Question 8 Who published the first astronomical observations made with a telescope? a) Hipparchus b) Galileo c) Tycho d) Copernicus e) Kepler Galileo published the “Starry Messenger” in 1610, detailing his observations of the Moon, Jupiter’s moons, stars, and nebulae. Question 9 Which of Galileo’s initial observations was most challenging to established geocentric beliefs? a) craters on the Moon b) sunspots c) lunar maria d) satellites of Jupiter e) stars of the Milky Way Question 9 Which of Galileo’s initial observations was most challenging to established geocentric beliefs? a) craters on the Moon b) sunspots c) lunar maria d) satellites of Jupiter e) stars of the Milky Way Seeing four moons clearly move around Jupiter disproved that everything orbited Earth and showed Earth could orbit the Sun and not lose its moon, too. Question 10 Which hero of the Renaissance postulated three “laws” of planetary motion? a) Kepler b) Newton c) Galileo d) Tycho Brahe e) Copernicus Question 10 Which hero of the Renaissance postulated three “laws” of planetary motion? a) Kepler b) Newton c) Galileo d) Tycho Brahe e) Copernicus Note that Isaac Newton is also well known for three general laws of motion. But Kepler’s laws are about objects in orbits, such as planets orbiting a star. Question 11 Kepler’s 1st law of planetary orbits states that a) planets orbit the Sun. b) orbits are noncircular. c) orbits are elliptical in shape. d) all of the above are correct. Question 11 Kepler’s 1st law of planetary orbits states that a) planets orbit the Sun. b) orbits are noncircular. c) orbits are elliptical in shape. d) all of the above are correct. Kepler’s laws apply to all orbiting objects. The Moon orbits Earth in an ellipse, and the Space Shuttle orbits Earth in an ellipse, too. Question 12 Earth is closer to the Sun in January. From this fact, Kepler’s 2nd law tells us a) b) c) Earth orbits slower in January. Earth orbits faster in January. Earth’s orbital speed doesn’t d)change. Question 12 a) Earth is closer to the Sun in January. From this fact, Kepler’s 2nd law tells us b) c) Earth orbits slower in January. Earth orbits faster in January. Earth’s orbital speed doesn’t change. Kepler’s 2nd law means that a planet moves faster when closer to the star. Slower Faster Question 13 Kepler’s 3rd law relates a planet’s distance from the Sun and its orbital a. b. c. d. speed. period. shape. velocity. Question 13 Kepler’s 3rd law relates a planet’s distance from the Sun and its orbital a. b. c. d. speed. period. shape. velocity. Kepler’s 3rd law P2 = a3 means more distant planets orbit more slowly. Venus’ Period = 225 days Earth’s Period = 365 days Venus’ axis = 0.7 AU Earth’s axis = 1.0 AU Question 14 Newton’s law of gravity states that the force between two objects a) increases with distance. b) depends on the state of matter (solid, liquid, or gas). c) can be attractive or repulsive. d) increases with mass. Question 14 Newton’s law of gravity states that the force between two objects a) increases with distance. b) depends on the state of matter (solid, liquid, or gas). c) can be attractive or repulsive. d) increases with mass. The attractive force of gravity increases with greater mass, and decreases quickly with greater distance. The force doesn’t depend on the kind of matter.