Deck 8: The Terrestrial Planets and Earths Moon

A) 1 billion years older.
B) 1 billion years younger.
C) 1 million years older.
D) 1 million years younger.
E) a few thousand years younger.

A) the leftover piece of the meteor.
B) a small volcano formed by the molten meteor.
C) rebounding material from the larger object.
D) the remains of a mountain that was hit by the meteor.
E) formed by later wind erosion.

A) Mercury should have more craters than Earth because it is closer to the Sun.
B) Geological features and the chemical composition of some rocks on Mars suggest liquid water flowed on the surface in the past, but not at the present time.
C) Venus should be cooler than Earth because it is smaller.
D) Jupiter's colored bands are evidence of tectonic activity.
E) The Moon has big, dark "seas," which are evidence of water having existed on its surface at one time.

A) A, B, C
B) A, C, B
C) B, A, C
D) B, C, A
E) C, B, A

A) the rate of cratering in the Solar System has changed dramatically over time.
B) the younger lunar surfaces are hundreds of billions of years younger than the oldest surfaces.
C) the Moon has never been geologically active at any point in its history.
D) most of the heavy cratering in the Solar System occurred before Earth formed.
E) cratering is no longer occurring in the Solar System.

A) meteorites
B) meteoroids
C) meteors
D) asteroids
E) comets

A) ejecta
B) water flows
C) lava flows
D) rebounding material
E) sunlight

A) A
B) B
C) C
D) A and C are probably about the same age and are older than B.
E) It is impossible to tell without radioactive dating.

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

A) rapidly decreased approximately 1 billion years ago.
B) rapidly decreased approximately 3 billion years ago.
C) were very rare in the last 4.6 billion years.
D) occurred at approximately a constant rate throughout most of the age of the Solar System.
E) never occur anymore.

A) the rate of cratering in the early Solar System was strongly dependent on location.
B) Mars, Venus, and Earth have thicker atmospheres.
C) Earth and Venus were shielded from impacts by the Moon, and Mars was protected by the asteroid belt.
D) Mars, Venus, and Earth were geologically active for a longer period of time than Mercury and the Moon.
E) Mars, Venus, and Earth are much larger in size than Mercury and the Moon.

A) wind erosion
B) distance from the Sun
C) higher-density interior
D) surface temperature
E) magnetic field strength

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

A) A
B) B
C) C
D) A and C are probably about the same age and are younger than B.
E) It is impossible to tell without radioactive dating.

A) craters formed by water impact.
B) craters formed by ejecta during another impact.
C) a crater that forms later, inside a larger crater.
D) craters formed on a new surface.
E) craters formed on planets other than Earth.

A) meteorites.
B) meteoroids.
C) meteors.
D) asteroids.
E) comets.

A) Earth, Venus, Mercury
B) Venus, Earth, Mercury
C) Mercury, Venus, Earth
D) Earth, Mercury, Venus
E) Venus, Mercury, Earth

A) at least 1 m in size.
B) at least 10 m in size.
C) at least 100 m in size.
D) at least 1 kilometer (km) in size.
E) at least 1,000 km in size.

A) volcanism in its interior.
B) the presence of water in surface rocks.
C) active plate tectonics at the time of impact.
D) a very thin crust.
E) the presence of ice.

A) decays of radioisotopes within the planet
B) thermal radiation into space
C) incident energy from the central star
D) tidal forces
E) asteroid impacts

A) A
B) B
C) C
D) D
E) none of these

A) 4.6 billion years
B) 4.6 million years
C) 13.7 trillion years
D) 13.7 billion years
E) 13.7 million years

A) 1/2
B) 1/4
C) 1/8
D) 1/16
E) 1/32

A) the decay of radioisotopes on the surface.
B) tidal forces from the Sun.
C) extreme volcanic activity.
D) an impact with a giant object.
E) magnetic field interactions.

A) the core temperature is too low to melt iron.
B) differentiation caused all of the heavy, solid material to sink to the bottom while Earth was forming.
C) all the liquid has moved up into the mantle via convection.
D) the pressure is too high for the material to be in a liquid state.
E) iron does not melt.

A) 1.4 billion years
B) 2.8 billion years
C) 4.0 million years
D) 10.5 billion years
E) 3.6 billion years

A) Earth will spin more slowly on its axis.
B) The interior of the planet will cool and solidify.
C) Volcanic activity will increase.
D) Continental drift will accelerate.
E) The surface will be too radioactive for life to exist.

A) albedo.
B) age.
C) volume.
D) density.
E) heat capacity.

A) A
B) B
C) C
D) D
E) none of these

A) measuring the number of craters per square meter on Mercury.
B) radioactive dating of rocks retrieved from the Moon.
C) carbon dating of rocks from mountains on Earth.
D) measurement of the magnetic field variations in rocks under Earth's oceans.
E) measuring the rate of energy production in the Sun.

A) it formed first from denser material and then afterward accreted lighter material.
B) it has both a liquid and solid core.
C) it was entirely liquid at some point in the past.
D) only the crust is solid; the rest of Earth's interior is liquid.
E) it formed first from lighter material and then afterward accreted heavier material.

A) 1.4 billion years
B) 2.8 billion years
C) 4.0 billion years
D) 10.5 billion years
E) 3.6 billion years

A) longitudinal.
B) transverse.
C) sound.
D) primary.
E) seismic.

A) tidal force of the Moon on Earth
B) seismic waves that travel through Earth's interior
C) decay of radioactive elements
D) convective motions in the mantle
E) pressure on the core from Earth's outer layers.

A) 2
B) 4
C) 8
D) 15
E) 16

A) part of the planet's interior is liquid.
B) all of the planet's interior is solid.
C) the planet has an iron core.
D) the planet's interior consists entirely of rocky materials.
E) the planet's mantle is liquid.

A) a 1-kg asteroid traveling at 30 km/s
B) a 5-kg asteroid traveling at 10 km/s
C) a 100-kg comet traveling at 10 km/s
D) a 1,000-kg small car traveling at 100 miles/h, which is 0.05 km/s
E) a 3,000-kg truck traveling at 35 miles/h, which is 0.02 km/s

A) oceans
B) average density
C) core
D) atmosphere
E) mantle

A) a 1-m-diameter asteroid moving at 100 m/s
B) a 1-m-diameter comet moving at 100 m/s
C) a 10-m-diameter comet moving at 10 m/s
D) a 10-m-diameter asteroid moving at 10 m/s
E) a 1-m-diameter comet moving at 50 m/s

A) the metallic core of Earth.
B) the liquid mantle of Earth.
C) the magnetic dynamo effect.
D) the magnetic fields surrounding Earth.
E) Earth's ionosphere.

A) Mars; Olympus Mons
B) Venus; Valles Marineris
C) Venus; Olympus Mons
D) Mars; Valles Marineris
E) Mercury; Caloris Basin

A) Earth's core will solidify.
B) Continental drift will cease.
C) Earthquakes will cease.
D) The strength of Earth's magnetic field will decrease.
E) All of these will occur.

A) a spreading center on the sea floor
B) a volcano in the middle of a continental plate
C) a fault at the border between two plates
D) a subduction zone on the sea floor
E) the rate of motion of tectonic plates

A) planet A
B) planet B
C) planet C
D) They all have the same likelihood of having a liquid core.
E) None of these planets should have a liquid core because they all should have completely solidified.

A) a subduction zone.
B) a sliding plate.
C) converging plates.
D) separating plates.
E) a mountain range.

A) only Earth
B) only Earth, Venus, and Mars
C) only Earth and Venus
D) only Earth and Mercury
E) Earth, Venus, Mars, and Mercury

A) mm/yr.
B) cm/yr.
C) m/yr.
D) km/yr.
E) nm/yr.

A) The Moon's heating rate is 1/64 times that of Earth's.
B) The Moon's heating rate is 32 times that of Earth's.
C) The Moon's heating rate is 1/16 times that of Earth's.
D) The heating rates are about the same.
E) The Moon's heating rate is 8 times that of Earth's.

A) a permanently magnetized crust
B) a solid iron core
C) a liquid interior
D) polarized liquid water oceans.
E) a large moon

A) mountain ranges.
B) canyons.
C) volcanoes.
D) ocean trenches.
E) continental drift.

A) a conical volcano.
B) a lunar crater.
C) mantle turbulence.
D) a shield volcano.
E) a composite volcano.

A) fast rotation and a solid core.
B) slow rotation and a liquid core.
C) fast rotation and a liquid core.
D) slow rotation and a solid core.
E) fast rotation and a gaseous core.

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

A) an impact crater; an asteroid or comet
B) a dry riverbed; flowing water
C) a canyon; a rapid cooling of the crust
D) a canyon; flowing water
E) a highway; an extinct civilization

A) meteor crater
B) canyon
C) tidal bulge
D) local hot spot
E) inactive fault

A) 3 million years
B) 300,000 years
C) 20 million years
D) 20,000 years
E) 600 years

A) Mars's heating rate is 0.125 times that of Earth.
B) Mars's heating rate is 8 times that of Earth.
C) Mars's heating rate is 0.5 times that of Earth.
D) Mars's heating rate is 4 times that of Earth.
E) The heating rates are about the same.

A) 1,600 years
B) 160,000 years
C) 1.6 million years
D) 160 million years
E) 1.6 billion years

A) a rocky-core volcano.
B) a lunar crater.
C) mantle turbulence.
D) a shield volcano.
E) a composite volcano.

A) extreme tectonic activity
B) a thick atmosphere, therefore no asteroid impacts
C) less gravity than other terrestrial planets
D) fewer eruptions
E) strong tidal forces

A) an impact crater; Meteor Crater
B) a volcano; Olympus Mons
C) a canyon; Valles Marineris
D) a canyon; Caloris Basin
E) a mountain; Mount Everest

A) tiny streams of flowing water too small to be detected by orbiting satellites.
B) minerals that must have formed in an environment rich in liquid water.
C) dust storms that rapidly erode the surfaces of most geological formations.
D) the northern polar ice cap is made primarily of frozen water.
E) the presence of methane that arises from biological life.

A) Mapping satellites have detected dry riverbeds.
B) Rovers have detected minerals that must have formed in the presence of liquid water.
C) Mapping satellites have detected outflow channels coming from impact craters.
D) large canyons
E) all of these

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

A) impact crater; Mercury
B) mountain; Venus
C) mountain; Earth
D) volcano; Mars
E) impact crater; the Moon

A) Many dinosaur fossils are found below the K-Pg boundary, but none above it.
B) The impact created the Moon.
C) The radioactivity of Earth's crust increases significantly above the K-Pg boundary.
D) There are several medium-sized meteor craters created by secondary impacts.
E) The remaining meteorite has been identified on the bottom of the Gulf of Mexico.

A) plate tectonic activity
B) meteor impacts
C) decay of radioisotopes within the planet
D) a thick, active atmosphere
E) none of these

A) Mercury
B) Venus
C) Mars
D) Ganymede
E) Callisto

A) flowing water.
B) wind.
C) solar radiation.
D) dust storms.
E) tectonic shifts.

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