Untitled Flashcards Set

Formation of Planetary Systems

  • Theories of Solar System Origins: Theories summarize how the Solar System originated and are based on current observations and facts. They may change with new discoveries.

  • Planet Formation Process: Planets form as natural by-products of star formation. A solar nebula (a giant cloud of gas and dust) contracts under its gravity, forming a star at the center with leftover material creating planets and moons.

  • Differences Between Terrestrial and Jovian Planets:

    • Terrestrial Planets: High densities, few or no moons, moderate atmospheres.

    • Jovian Planets: Low densities, many moons, thick atmospheres, rapid spin rates.


Modeling the Origin of Our Solar System

  • Models are based on current observations in space.

  • Our solar system may or may not be unique.

  • Theories are built on known facts and may evolve with new discoveries.

  • Planetary distances roughly double as you move outward.

  • Orbits lie in the same plane and travel in the same direction as the Sun's rotation.


Condensation Theory

  • Solar Nebula: A giant cloud of gas and dust contracts under its gravity, becoming denser and hotter.

  • Formation of the Sun and Planets:

    • The Sun forms at the center.

    • Leftover mass creates planets and moons.

    • Planetesimals (small moon-like bodies) collide to form inner planets.

    • Jovian planets form farther out, where lighter materials are more abundant.

  • End of Formation: Strong solar winds blow away remaining gas, forming the Kuiper Belt and Oort Cloud.

  • Collisions: Many unusual aspects of the solar system may result from late-stage planetary collisions.


Extrasolar Planets

  • Thousands of planets have been detected around other stars, most being Jupiter-sized.

  • Orbits range from inside Mercury’s orbit to beyond our gas giants.

  • Improved technology will help discover smaller Earth-like worlds.

  • The Kepler Spacecraft (launched in 2009) is designed to find Earth-like worlds.


Our Solar System

  • Importance of Comparative Planetology: Comparing and contrasting planetary properties helps us understand their evolution and the solar system's structure.

  • Scale and Structure:

    • One star (the Sun), 8 major planets, 6 dwarf planets, 172 moons, countless asteroids, meteoroids, and comets.

  • Definitions:

    • Planet: Orbits the Sun, cleared its orbit of debris, and is round.

    • Dwarf Planet: Orbits the Sun, is round, but hasn’t cleared its orbit.

    • Moon: A natural satellite orbiting a larger body.

    • Asteroid: Small rocky/metallic debris left from the Solar System's formation.

    • Meteoroid: Smaller pieces of asteroids.

    • Meteor: A meteoroid burning up in Earth’s atmosphere.

    • Meteorite: A meteor that reaches Earth’s surface.

    • Comet: A small icy body with elongated orbits.


Solar System Layout

  • Order from the Sun: Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, Neptune.

  • Planetary Properties:

    • Jupiter is the largest; Mercury is the smallest.

    • Mercury is the densest planet.

  • Terrestrial Planets: Mercury, Venus, Earth, Mars.

    • Close to the Sun, small mass, solid surface, few/no moons, no rings.

  • Jovian Planets: Jupiter, Saturn, Uranus, Neptune.

    • Far from the Sun, large mass, no solid surface, many moons, rings.

  • Other Regions:

    • Asteroid Belt: Between Mars and Jupiter; likely a “failed planet.”

    • Kuiper Belt: Past Neptune’s orbit, containing icy objects like Pluto and Eris.

    • Oort Cloud: A spherical region extending 3 light-years from the Sun, with trillions of icy objects.


Solar System Explorers

  • Voyager 1 and 2:

    • Launched in 1977 to explore the solar system.

    • Used gravity assist to gain speed.

    • Voyager 1 visited Jupiter and Saturn; now the farthest man-made object.

    • Voyager 2 visited all four outer planets; now the second-farthest object.

    • Both are still transmitting data.