Deck 7: Earth and the Terrestrial Worlds

A) impact cratering
B) volcanism
C) tectonics
D) erosion
E) magnetism

A) when the substance is subjected to a strong magnetic field
B) when dense material is being added to the substance
C) when the substance is strongly shaken or disturbed by a strong wind
D) when the substance is strongly cooled from underneath
E) when the substance is strongly heated from underneath

A) The planet must have a rocky surface.
B) The planet must be made of both metal and rock.
C) The planet must have an atmosphere.
D) The planet must be geologically active, that is, have volcanoes, planetquakes, and erosion from weather.
E) The planet must have a molten interior.

A) its composition
B) its size
C) its magnetic field
D) its mass

A) pressure
B) composition
C) internal temperature
D) distance of planet from Sun

A) the same size
B) 10-20 percent larger
C) 10 times larger
D) 100 times larger
E) 1,000 times larger

A) the entire planets are made mostly of metal.
B) metals condensed first in the solar nebula and the rocks then accreted around them.
C) metals sank to the center during a time when the interiors were molten throughout.
D) radioactivity created metals in the core from the decay of uranium.
E) convection carried the metals to the core.

A) material above the crust.
B) material between the crust and the mantle.
C) the rigid rocky material of the crust and uppermost portion of the mantle.
D) the softer rocky material of the mantle.
E) the lava that comes out of volcanoes.

A) a molten metallic core only
B) fast rotation only
C) a rocky mantle only
D) both a molten metallic core and reasonably fast rotation
E) both a metal core and a rocky mantle

A) conduction, differentiation, and accretion.
B) accretion, differentiation, and radioactivity.
C) accretion, differentiation, and eruption.
D) convection, differentiation, and eruption.
E) conduction, convection, and eruption.

A) Mars
B) Earth
C) the Moon
D) Venus
E) Mercury

A) geological activity.
B) temperature.
C) strength.
D) density.

A) 1-10%
B) 10-20%
C) 30-40%
D) 50-100%
E) 100-200%

A) Mercury, Venus, Earth, Moon, Mars.
B) Mercury, Moon, Venus, Earth, Mars.
C) Moon, Mercury, Venus, Earth, Mars.
D) Moon, Mercury, Mars, Venus, Earth.
E) Mercury, Moon, Mars, Earth, Venus.

A) Earth and the Moon
B) Venus and the Moon
C) Mercury and Venus
D) Earth and Mars
E) Earth and Venus

A) accretion
B) differentiation
C) radioactivity
D) both A and B
E) all of the above

A) It does not have a metallic core.
B) Its rotation is too slow.
C) It is too close to the Sun.
D) It is too large.
E) It has too thick an atmosphere.

A) It is the process by which rocks sink in water.
B) It is the process in which warm material expands and rises while cool material contracts and falls.
C) It is the process in which warm material gets even warmer and cool material gets even cooler.
D) It is the process in which a liquid separates according to density, such as oil and water separating in a jar.
E) It is the process in which bubbles of gas move upward through a liquid.

A) It is the only one that has a metallic core.
B) It rotates much faster than any other terrestrial world.
C) It is the only one that has both a partially molten metallic core and reasonably rapid rotation.
D) It is by far the largest terrestrial world.
E) It is the most volcanically active world.

A) impacts of asteroids and planetesimals
B) internal temperature changes that caused the crust to expand and stretch
C) the circulation of convection cells in the mantle, which dragged against the lithosphere
D) cooling and contracting of the planet's interior, which caused the mantle and lithosphere to be compressed
E) volcanism, which produced heavy volcanoes that bent and cracked the lithosphere

A) is closer to the Sun.
B) is struck often by meteors and solar system debris.
C) has high internal temperatures.
D) doesn't have an atmosphere or oceans.

A) by studying Venus from Earth with powerful telescopes
B) by studying Venus with powerful telescopes on spacecraft that were sent to orbit Venus
C) By making computer models of geological processes on Venus
D) by using radar from spacecraft that were sent to orbit Venus
E) by landing spacecraft on the surface for close-up study

A) the excavation of bowl-shaped depressions by asteroids or comets striking a planet's surface
B) the eruption of molten rock from a planet's interior to its surface
C) The disruption of a planet's surface by internal stresses
D) the wearing down or building up of geological features by wind, water, ice, and other phenomena of planetary weather

A) large valley on the Moon.
B) extensive plain on Mars.
C) huge series of cliffs on Mercury.
D) large canyon on Mars.
E) large canyon on Venus.

A) there is little volcanic activity to create craters.
B) the planet is rotating very slowly and only one side was hit by impactors.
C) the planet formed after the age of bombardment and missed out on getting hit by leftover planetesimals.
D) the surface in the region is older than the surface in more heavily cratered regions.
E) the surface in the region is younger than the surface in more heavily cratered regions.

A) mountains
B) valleys
C) volcanos
D) cliffs
E) all of the above

A) They were probably carved in Mercury's early history by running water.
B) They were probably formed by tectonic stresses when the entire planet shrank as its core cooled.
C) They probably formed when a series of large impacts hit Mercury one after the other.
D) They are almost certainly volcanic in origin, carved by flowing lava.
E) They represent one of the greatest mysteries in the solar system, as no one has suggested a reasonable hypothesis for their formation.

A) the excavation of bowl-shaped depressions by asteroids or comets striking a planet's surface
B) the eruption of molten rock from a planet's interior to its surface
C) the disruption of a planet's surface by internal stresses
D) the wearing down or building up of geological features by wind, water, ice, and other phenomena of planetary weather

A) Large impacts fractured the Moon's lithosphere, allowing lava to fill the impact basins.
B) The early bombardment created heat that melted the lunar surface in the regions of the maria.
C) Volatiles escaping from the Moon's interior heated and eroded the surface in the regions of the maria.
D) The giant impact that created the Moon left smooth areas that we call the maria.
E) The maria are the result of gradual erosion by micrometeorites striking the Moon.

A) Mercury
B) Venus
C) the Moon
D) Mars
E) Earth

A) impacts and volcanoes
B) impacts and tectonics
C) tectonics and erosion
D) volcanoes and tectonics
E) volcanoes and erosion

A) Mercury.
B) Venus.
C) Moon.
D) Mars.

A) the excavation of bowl-shaped depressions by asteroids or comets striking a planet's surface
B) the eruption of molten rock from a planet's interior to its surface
C) the disruption of a planet's surface by internal stresses
D) the wearing down or building up of geological features by wind, water, ice, and other phenomena of planetary weather

A) It is made primarily of red clay.
B) Its surface rocks were rusted by oxygen.
C) Its atmosphere scatters blue light more effectively than red light.
D) Its surface is made of ices that absorb blue light.
E) Its surface is made of ices that absorb red light.

A) the excavation of bowl-shaped depressions by asteroids or comets striking a planet's surface
B) the eruption of molten rock from a planet's interior to its surface
C) the disruption of a planet's surface by internal stresses
D) the wearing down or building up of geological features by wind, water, ice, and other phenomena of planetary weather

A) the Moon
B) Mercury
C) Venus
D) Mars
E) all of the above

A) low surface gravity.
B) high surface gravity.
C) low internal temperature.
D) high internal temperature.
E) a dense atmosphere.

A) erosion destroyed the smaller craters that formed on the basin.
B) Mercury's atmosphere prevented smaller objects from hitting the surface.
C) only very large impactors hit Mercury's surface in the past.
D) the Caloris Basin formed toward the end of the solar system's period of heavy bombardment.
E) the Caloris Basin was formed by a volcano.

A) in its clouds
B) in its polar caps and subsurface ground ice
C) frozen on the peaks of its tall volcanoes
D) in deep underground deposits
E) distributed evenly throughout its atmosphere

A) impact cratering
B) volcanism
C) plate tectonics
D) wind erosion
E) acid rain

A) lacks atmospheric oxygen.
B) is too hot.
C) lacks a strong magnetic field.
D) lacks strong winds.

A) Continental crust is made from remelted seafloor crust and therefore only the lower-density material rises to form it.
B) Continental crust is made from volcanic rock called basalt, which is lower in density than what the seafloor crust is made from.
C) Continental crust is made of rock, while seafloor crust has more metals.
D) Seafloor crust is more compact due to the weight of the oceans, but it is made of the same material as the continental crust.
E) Continental crust is actually denser than seafloor crust.

A) because it is farther from the Sun
B) because it has a larger axis tilt
C) because it has a more eccentric orbit
D) Because it has more carbon dioxide in its atmosphere
E) all of the above

A) Without the naturally occurring greenhouse effect, Earth would be too cold to have liquid oceans.
B) A weak greenhouse effect operates on Mars.
C) The burning of fossil fuels increases the greenhouse effect on Earth because of the release of carbon dioxide.
D) One result of an increased greenhouse effect on Earth may be an increased number of severe storms.
E) All of the above are true.

A) carbon dioxide
B) nitrogen
C) oxygen
D) hydrogen
E) ozone

A) any fuel that releases CO₂ into the atmosphere upon burning
B) any fuel that is extracted from the interior of the Earth
C) mineral-rich deposits from ancient seabeds
D) the carbon-rich remains of plants that died millions of years ago
E) carbonate-rich deposits from ancient seabeds

A) photosynthesis from plant life and single-celled organisms
B) chemical reactions between gas in the upper atmosphere and the solar wind
C) outgassing from volcanoes
D) atmospheric bombardment
E) oxidation of surface rocks

A) only CO₂
B) CO₂ and H₂O
C) CO₂ and N₂
D) all except O₂
E) all four

A) Venus
B) Earth
C) Mars
D) Neptune
E) Mercury

A) one plate slides under another, returning older crust to the mantle.
B) hot mantle material rises upward, creating volcanic islands.
C) hot mantle material rises upward and spreads sideways, pushing the plates apart.
D) plates push together, creating ocean mountain chains.
E) plates slip sideways relative to one another.

A) gases that absorb visible light
B) gases that absorb ultraviolet light
C) gases that absorb infrared light
D) gases that transmit visible light
E) gases that transmit infrared light

A) a few centimeters per year
B) a few centimeters per century
C) a few kilometers per century
D) quite fast, but only during earthquakes
E) about 1 mile per hour

A) water
B) nitrogen
C) oxygen
D) carbon dioxide

A) Its lithosphere is broken into plates that move around.
B) It has oxygen in its atmosphere.
C) Most of its surface is covered with liquid water.
D) Life can be found almost everywhere.
E) All of the above are true.

A) The rotation rate determines how much atmosphere a planet has.
B) The rotation rate determines how long the planet is able to retain its atmosphere.
C) Faster rotation rates raise surface temperatures and thus determine how much material is gaseous versus icy or liquid.
D) Faster rotation rates raise the atmospheric temperature.
E) Faster rotation rates produce stronger winds.

A) the Sun emits more red light when it's setting.
B) sunlight must pass through more atmosphere, and this scatters even more light at bluer wavelengths, transmitting mostly red light.
C) sunlight must pass through more atmosphere, and this scatters more light at red wavelengths than bluer wavelengths.
D) the cooler atmosphere in the evening absorbs more blue light.
E) none of the above

A) convection cells in the mantle
B) rotation of the liquid core
C) lava flows in trenches along the sea floor
D) Earth's magnetic field
E) tidal forces

A) -16°C, which is well below freezing.
B) 0°C, or about the freezing point for water.
C) 10°C or about 5°C cooler than it is now.
D) 15°C, or about the same as it is now.
E) 20°C, or about 5°C warmer than it is now.

A) one plate slides under another, returning older crust to the mantle.
B) plates pull apart, leaving great rifts in the crust.
C) hot mantle material rises upward and spreads sideways, pushing the plates apart.
D) plates push together, creating ocean mountain chains.
E) plates slip sideways relative to one another.

A) the earth's volcanoes did not outgas as much carbon dioxide as those on Venus and Mars.
B) most of the carbon dioxide was lost during the age of bombardment.
C) chemical reactions with other gases destroyed the carbon dioxide and replaced it with the nitrogen that is in the atmosphere now.
D) carbon dioxide dissolves in water, and most of it is now contained in the oceans and carbonate rocks.
E) Earth doesn't have as strong a greenhouse effect as is present on Venus.

A) Carbonate materials would form in the oceans more rapidly, the atmospheric CO₂ content would decrease, and the greenhouse effect would weaken.
B) Carbonate materials would form in the oceans more slowly, the atmospheric CO₂ content would increase, and the greenhouse effect would strengthen.
C) Carbonate materials would form in the oceans more rapidly, the atmospheric CO₂ content would decrease, and the greenhouse effect would strengthen.
D) There would be a runaway greenhouse effect, with the Earth becoming ever hotter until the oceans evaporated (as may have happened on Venus).
E) The ice caps would melt and cool the Earth back to its normal temperature.

A) Burning fuel warms the planet.
B) Burning releases carbon dioxide into the atmosphere.
C) Burning depletes the amount of ozone, thereby warming the planet.
D) Burning produces infrared light, which is then trapped by existing greenhouse gases.
E) All of the above are true.

A) Warming would increase the evaporation of the oceans, leading to more water in the atmosphere and more frequent and severe storms.
B) Warming of the planet would lead to terrible droughts and reduce the amount of water on the Earth.
C) Warming would dry out the atmosphere and the crust, leading to devastation of the Earth through more meteor bombardment and volcanism.
D) The depleted ozone layer would let in more particles from the solar wind.
E) all of the above

A) 0°C
B) 0-3°C
C) 3-5°C
D) 5-7°C
E) 7-10°C

A) Radioactive elements trapped in the Earth's mantle.
B) Heat stored in the Earth's magnetosphere.
C) Heat stored in the Earth's liquid core.
D) The carbon dioxide cycle.
E) The Milankovitch cycles.