Deck 5: The Solar System: Interplanetary Matter and the Birth of the Planets

A) are highly inclined to the ecliptic.
B) are evenly spaced throughout the solar system.
C) are almost circular, with low eccentricities.
D) have the Sun at their exact center.
E) are spaced more closely together as they get further from the Sun.

A) Saturn
B) Jupiter
C) Uranus
D) Earth
E) Venus

A) all lie less than 5 AU from the Sun.
B) all have rings around their equators.
C) have satellite systems with less than 4 moons.
D) all spin more slowly than the Earth.
E) are all much denser than any of the terrestrial planets.

A) everything past Mars and the asteroid belt
B) only Jupiter and Saturn
C) Jupiter, Saturn, Uranus, and Neptune only
D) Jupiter, Saturn, Uranus, Neptune, and Pluto
E) only Jupiter

A) comet nuclei
B) asteroids
C) the polar cap of Mars
D) Kuiper Belt Objects
E) most jovian satellites

A) Saturn has the same density as water.
B) In differentiated bodies, the denser materials lie near their surfaces.
C) The asteroids all have about the same density.
D) The denser planets lie closer to the Sun.
E) Planetary density increases with increasing distance from the Sun.

A) weight divided by the planet's radius.
B) size divided by weight.
C) mass per unit volume.
D) mass times weight.
E) weight per square inch.

A) they contain pristine material from the solar nebula.
B) some come from the Moon and Mars, as well as the asteroid belt.
C) large ones may cause mass extinctions.
D) All of the above are true.
E) None of the above is true.

A) the Kuiper belt.
B) the asteroid belt.
C) the interstellar medium.
D) the satellite system of Jupiter.
E) the Oort cloud.

A) Hayabusa.
B) Dawn.
C) Giotto.
D) Stardust.
E) NEAR.

A) comets
B) meteoroids
C) the surface of Mars
D) most asteroids
E) meteorites and most asteroids

A) in the Kuiper Belt.
B) short period comets.
C) the Trojan asteroids.
D) the jovians.
E) in the Oort Cloud.

A) the direction the comet is traveling.
B) the velocity of the comet.
C) the direction of the Sun.
D) where the ecliptic is.
E) where the comet came from.

A) in the direction of the comet's motion.
B) toward the Sun and disappears at perihelion.
C) away from the Sun and becomes longest and brightest at perihelion.
D) toward Earth and never varies.
E) away from the Sun and disappears at perihelion.

A) Mars.
B) the Moon.
C) the asteroid Gaspra.
D) Venus.
E) the asteroid Mathilde.

A) the circular disk of gas around the Sun's equator from which the planets formed.
B) a spherical cloud of cometary nuclei far beyond the Kuiper Belt.
C) the great nebula found just below the belt stars of Orion.
D) a grouping of asteroids and meteoroids between the orbits of Mars and Jupiter.
E) a flattened belt of cometary nuclei just beyond the orbit of Neptune.

A) comets
B) Trojan asteroids
C) meteoroids
D) Kuiper Belt bodies
E) rings around the jovian planets

A) Ida.
B) Gaspra.
C) Eros.
D) Vesta.
E) Ceres.

A) the asteroid Vesta.
B) the asteroid Ida.
C) the asteroid Gaspra.
D) the asteroid Ceres.
E) the comet Wild.

A) a streak of light in the atmosphere.
B) a chunk of space debris that has struck the ground.
C) an icy body with a long tail extending from it.
D) a chunk of space debris orbiting the Earth.
E) an irregularly shaped body, mostly found orbiting between Mars and Jupiter.

A) closer on average to the Sun than is the Earth.
B) sixty degrees ahead or behind Jupiter, sharing its orbit about the Sun.
C) beyond Neptune, with orbits similar to Pluto's.
D) orbiting around the Kuiper Belt body Hector.
E) with the others, between Mars and Jupiter; their red color gives them their name.

A) Their images become blurry due to outgassing as the Sun heats them up.
B) Most stay between the orbits of Mars and Jupiter.
C) Earthgrazers can cross not only our orbit, but even those of Venus and Mercury.
D) Some have satellites of their own.
E) They vary considerably in composition, reflectivity, and size.

A) between the orbits of Mars and Jupiter
B) sixty degrees ahead or behind Jupiter
C) beyond the orbit of Neptune
D) among the orbits of the terrestrial planets
E) between the orbits of Jupiter and Uranus

A) ground- based radar images.
B) Earth orbital X- ray images.
C) spacecraft sent to an asteroid.
D) high- altitude UV spectroscopy.
E) ground- based optical images.

A) interstellar space.
B) debris from the Kuiper Belt.
C) a broken up cometary nucleus.
D) the core of a differentiated asteroid, now broken up.
E) the crust of a differentiated asteroid, now broken up.

A) an irregularly shaped body, mostly found orbiting between Mars and Jupiter.
B) a streak of light in the atmosphere.
C) a chunk of space debris that has struck the ground.
D) an icy body with a long tail extending from it.
E) a chunk of space debris orbiting the Earth.

A) usually annual events, as the orbits again intersect.
B) caused by the Earth passing near the orbit of an Earthgrazing asteroid.
C) caused by the Earth passing near the orbit of an old short- period comet.
D) Both A and B are correct.
E) Both A and C are correct.

A) located between the orbits of Mars and Jupiter.
B) a few hundred kilometers across, and bright, shiny white from its ices.
C) very durable, made of iron.
D) a few meters in diameter.
E) a few kilometers in size, and very low in density.

A) was about 800 at the time of publication but is rising rapidly due to new observations by the Kepler spacecraft.
B) is about 600, and is not expected to rise very much.
C) is about 800, and is rising slowly, as observations are quite difficult.
D) has been decreasing as some observations thought to be planets have been disproven.
E) is zero; there are observations thought to be of extrasolar planets but none has yet been confirmed.

A) noting the drop in the star's light as the planet transits its disk.
B) detecting the oxygen in their atmospheres spectroscopically.
C) noting the Doppler shifts of the star as the planet orbits it from side to side.
D) receiving radio transmissions from them, much like Jupiter emits.
E) imaging them with the HST in the infrared, where they are easier to stop.

A) should be randomly oriented to their star's equator.
B) should orbit perpendicular to their star's equator.
C) will revolve opposite the star's rotation.
D) should be a common result of star formation.
E) should be extremely rare.

A) more rocky.
B) older.
C) more icy.
D) more cratered.
E) younger.

A) slower due to a decrease in angular momentum.
B) faster due to conservation of angular momentum.
C) faster due to an increase in angular momentum.
D) slower due to conservation of angular momentum.
E) at a constant rate.

A) Mars.
B) Venus.
C) Mercury.
D) Earth.
E) Pluto.

A) lie beyond the orbit of Neptune, and close to the ecliptic.
B) are the sources of long- period comets.
C) lie beyond the orbit of Neptune and perpendicular to the ecliptic.
D) are in random orbits at all inclinations to the ecliptic.
E) are dense, like the iron meteorites.

A) terrestrials with very elongated, distant orbits like comets.
B) large jovians orbiting solar- type stars about where our jovians are found.
C) large jovians very close to their star.
D) brown dwarfs much more massive than Jupiter.
E) terrestrials very close to their star, and transiting its disk.

A) Saturn.
B) Comet Halley.
C) the asteroid Ceres.
D) Mars.
E) the asteroid Gaspra.

A) jovian satellites
B) asteroids in the main belt
C) comet nuclei
D) Trojan asteroids
E) Kuiper Belt bodies

A) have masses comparable to that of Neptune.
B) orbit extremely massive stars.
C) have masses comparable to that of Jupiter.
D) have masses 2- 10 times that of Earth.
E) have yet to be observed.

A) loses angular momentum.
B) cools due to condensation.
C) flattens out into the ecliptic plane around the Sun's poles.
D) reverses its direction of rotation.
E) spins faster due to conservation of angular momentum.

A) most extrasolar systems are not seen edge- on.
B) our telescopes are not powerful enough to detect them.
C) most stars are too bright for us to detect a planetary transit.
D) the Earth's atmosphere interferes with our observations of transits.
E) most exoplanets are smaller than Pluto.

A) asteroid.
B) meteor.
C) comet.
D) meteoroid.
E) meteorite.

A) All lie more than 2 AU from their star.
B) Some are so close to their stars that their periods are just a few days.
C) Few are found by Doppler shifts of their stars, due to their gravity.
D) Most have orbital periods of more than a year.
E) All are terrestrials, comparable in size to Earth.

A) cometary debris.
B) Earth's interaction with a comet's dust tail.
C) a volcanic event.
D) a large meteorite impact.
E) a micrometeorite impact.

A) are like the planets, fairly circular and in the ecliptic plane.
B) have perihelions within the orbits of Mercury.
C) lie almost entirely beyond the orbit of Neptune.
D) go no farther out than Pluto, then return to the sun again.
E) are shorter than the 76- year period for Comet Halley.

A) all planets are condensed from the same nebula and have similar compositions.
B) the Sun is unique, made of nothing but hydrogen and helium.
C) the jovian planets are more like the Sun than are the terrestrials.
D) the jovian planets are made only of ice, and the terrestrials only of rock.
E) the terrestrials are more like the Sun, since they formed close to it.

A) moving closer to the Sun.
B) close to or at perihelion.
C) close to or at aphelion.
D) moving away from the Sun.
E) A comet's tail never points perpendicular to its motion.