Deck 15: Asteroids, Comets, and Impacts

A)the asteroid Ceres.
B)Pluto.
C)Halley's Comet.
D)Mercury.

A)are dark and spherical in shape, with many craters on their surfaces.
B)are spherical and ice coated, and hence light colored and shiny.
C)are irregularly shaped and covered with very light-colored dust that reflects sunlight well.
D)are dark, irregular in shape, and heavily cratered.

A)Ceres is much larger than Mare Imbrium.
B)Ceres is much smaller, because asteroids are very small objects (1 km diameter), whereas maria are large (100-1000 km diameter).
C)The Mare Imbrium is much larger than Ceres.
D)Their size is very similar-about 1000 km across.

A)They are very much smaller (less than 1/10).
B)They are between 1/10 and 1/2 as large.
C)They are about the same size.
D)They are very much larger (greater than 5×).

A)about 1500 km in diameter-significantly smaller than the Moon
B)about the size of Earth
C)only a few kilometers in diameter-similar to an average mountain on Earth
D)about the size of Mercury

A)1.99 years
B)2.8 years
C)4.56 years
D)46.8 years

A)fourth asteroid to be discovered in the month of February 1987.
B)sixth asteroid to be discovered in the month of April 1987.
C)1987th asteroid ever to be discovered, named after Frances Draibre.
D)fourth asteroid to be discovered during the second half of March 1987.

A)Newton's laws of motion.
B)the conservation of energy and angular momentum.
C)Kepler's third law.
D)None of the above is correct. The Titus-Bode "law" is more of a coincidence than a fundamental law of nature.

A)Kepler's third law predicts a planet within this distance.
B)The Titus-Bode law predicts a planet within this distance.
C)The discrepancies in Uranus's orbit suggested a planet around this radius.
D)The telescope, newly invented in 1781, was not powerful enough to detect anything beyond this range.

A)Neither the Ceres/Mars ratio nor the Jupiter/Ceres ratio falls into the range suggested by the Titus-Bode rule.
B)The Ceres/Mars ratio fits the Titus-Bode rule but the Jupiter/Ceres ratio does not.
C)The Ceres/Mars ratio does not fit the Titus-Bode rule but the Jupiter/Ceres ratio does.
D)Both the Ceres/Mars ratio and the Jupiter/Ceres ratio fall into the range suggested by the Titus-Bode rule.

A)Asteroids are "small" objects, and they formed with the kinds of orbits they now have.
B)The orbits were stirred up when the Sun passed within the Oort cloud of another star.
C)Jupiter's gravitational pull has stirred up the asteroid orbits.
D)One or more Mars-sized planets formed in the asteroid belt, and their gravitational influence stirred up the orbits of the rest of the asteroids.

A)equatorial region of the Sun.
B)rings of Saturn.
C)spectrum of hydrogen gas.
D)asteroid belt.

A)the gravitational tug of Jupiter nudging asteroids into new orbits.
B)shepherd satellites controlling the orbits of ring particles.
C)orbits of material being disturbed because Jupiter's gravitational field balances the Sun at this distance, and objects can escape from the solar system.
D)large asteroids sweeping parts of the asteroid belt clear of smaller asteroids.

A)Both are caused by large objects passing through swarms of smaller objects, sweeping out gaps in the swarms.
B)Both were discovered by observers from the same group; Kirkwood and Enke worked at the Cassini Observatory.
C)Both are caused by selective melting of material at these specific locations from the central radiating body, the Sun and Saturn respectively.
D)Both are caused by disruptions of orbits of small objects by a larger object whose orbital period is a simple ratio of that of the small objects.

A)We have watched other solar systems in their early stages of formation. They show Jupiter-size planets clearing out much of their asteroid belts.
B)Computer simulations have shown that in the absence of a Jupiter-size planet, an Earth-size planet would have formed in the asteroid belt.
C)Computer simulations have shown that a Jupiter-size planet has no influence on the formation of the asteroid belt.
D)We have watched other solar systems in their early stages of formation. They show that Jupiter-size planets have no influence on the formation of an asteroid belt.

A)1.0 au
B)7.86 au
C)3.28 au
D)2.5 au

A)The gravitational influence of Jupiter deflected most of them out of the solar system.
B)Mars-sized objects moving through the asteroid belt disrupted the orbits and deflected most of them out of the solar system.
C)The majority of the original asteroids coalesced to form a series of Mars-sized objects, one of which struck Earth and caused the formation of the Moon.
D)A passing star pulled most of the original asteroids out of the solar system.

A)radar signals reflected from the asteroid's surface.
B)direct photography from spacecraft.
C)optical and infrared Doppler shift measurements as the asteroid rotates.
D)CCD photography using large, Earth-based telescopes.

A)double lobed, as though two asteroids had stuck together.
B)perfectly spherical.
C)oblong but smooth.
D)irregular.

A)Ceres.
B)Icarus.
C)Gaspra.
D)Vesta.

A)sending radar pulses to reflect off the surface and analyzing the result
B)watching the variations in the sunlight reflecting off the asteroids
C)sending a spacecraft to orbit an asteroid
D)landing a robotic rover to survey an asteroid

A)a flyby mission to take close-up images of an asteroid.
B)a spacecraft that went into orbit around an asteroid.
C)a soft robotic landing to gather materials and return them to Earth.
D)a crewed landing to explore the asteroid and then return to Earth.

A)Vesta is unusually dense, so that, despite its small size, it has pulled itself gravitationally into a sphere.
B)Vesta was heated by a massive collision.
C)Vesta was heated by radioactivity soon after its formation.
D)Vesta was initially formed hot in the solar nebula and has managed to avoid large collisions ever since.

A)The gravity of the asteroid pulled virtually all of it back to Vesta, where it created a "rubble pile" resting in the crater.
B)It now exists as a small satellite orbiting Vesta.
C)The Dawn spacecraft imaged the crater on Vesta in infrared. The chemical composition was found to match that of many of the meteorites that have landed on Earth.
D)It was pulverized into a fine white dust that blankets much of Vesta.

A)It has almost no craters visible anywhere on its surface.
B)It has a much higher mass for its volume than any other known asteroid.
C)It is not much denser than water.
D)It has a very bright surface, possibly caused by fresh material thrown out by impacts.

A)Mathilde is a "rubble pile," having been shattered by collisions with other asteroids.
B)Mathilde is a binary asteroid that is too far away for us to see the individual components; the low density is an illusion created by the space between the two rocky components.
C)Mathilde is composed of about 1/4 rock and 3/4 ice.
D)Mathilde is a primitive asteroid, composed of loosely aggregated dust grains from the early solar nebula.

A)icy surfaces crisscrossed with cracks and systems of parallel grooves.
B)young, sharp, jagged surfaces, due to fragmentation by collision with other asteroids, and few craters.
C)irregular, somewhat rounded and moderately cratered surfaces.
D)ancient surfaces densely covered with large and small overlapping craters, like the surface of the highland areas of the Moon.

A)Ceres
B)Vesta
C)Gaspra
D)Mathilde

A)Their trajectories match the orbit of Vespa.
B)The ages of the meteorites match the age of the asteroid.
C)The chemical composition of the asteroids matches the chemical composition of a large crater on Vespa where the Dawn spacecraft obtained infrared spectra.
D)The meteors are all about the same size, indicating that they came from the same impact crater on Vespa.

A)Adenoids.
B)Apollo asteroids.
C)Trojan asteroids.
D)Jupitoids.

A)the main asteroid belt.
B)Jupiter.
C)Mars.
D)Earth.

A)circular orbits at the same distance from the Sun as Jupiter
B)circular orbits at about 2.8 au from the Sun
C)long, elliptical orbits that cross that of Earth
D)long, elliptical orbits ranging from Neptune's orbital distance to Jupiter's orbital distance

A)The period is 1.88 years.
B)It is difficult to be specific because they all have different orbital periods, depending on their masses.
C)The period is 5.9 years, the same as most asteroids in the asteroid belt.
D)The period is 11.86 years.

A)1/18 as strong.
B)18 times stronger.
C)12 times stronger.
D)76 times stronger.

A)the Sun
B)Earth
C)Jupiter
D)Neptune

A)Kirkwood objects, or KOs.
B)near-Earth objects, or NEOs.
C)Hirayama family asteroids, or HFAs.
D)Mars-crossing asteroids, or MCAs.

A)DA 14 asteroid.
B)Moon.
C)asteroid Ceres.
D)Trojan asteroid Hector.

A)a small comet nucleus about 150 m across suddenly vaporizing in the atmosphere.
B)the impact and annihilation of a very small amount of antimatter from somewhere else in the universe.
C)a small natural nuclear explosion in uranium deposits.
D)a small stony asteroid about 80 m across disintegrating explosively in the atmosphere before hitting the ground.

A)shatter Earth into fragments.
B)create havoc near the impact site but have relatively little lasting effect elsewhere.
C)shatter the global ecology and cause the extinction of a large percentage of all species living on Earth.
D)completely destroy all life on Earth.

A)20 m
B)100 m
C)2000 m
D)4 km

A)during an interval of 80 years-roughly a human lifetime.
B)once every 10,000 years.
C)once every 500,000 years.
D)never.

A)are composed of rocks similar to terrestrial rocks.
B)contain large quantities of carbon and H₂O, and even hydrocarbons and amino acids.
C)have solid iron cores and rocky silicate shells.
D)are made of solid iron and nickel.

A)are normally composed almost entirely of iron and nickel.
B)are normally composed almost entirely of iron.
C)normally contain between 3 and 5 times as much iron as terrestrial rocks, in the form of pure grains embedded a rocky matrix.
D)are normally composed almost entirely of iron, nickel, and carbon.

A)is larger than 1 cm across.
B)is larger than 1 m across.
C)is larger than 2 km across.
D)has a mass larger than 1% the mass of Earth.

A)Ceres
B)Moon
C)Vesta
D)Mars

A)layered rock, consisting of limestone
B)solid iron, with a distinctive crystal structure throughout its interior
C)rough-surfaced rock with small inclusions of coal
D)large transparent crystals of common salt embedded in sandstone

A)fracture lines, created by the impact that knocked the meteoroid off the parent asteroid.
B)large crystals, formed as the iron cooled slowly over many millions of years.
C)small holes and bubbles, created by partial melting of the meteorite as it entered Earth's atmosphere.
D)minute crystals, formed when the iron cooled quickly in the vacuum of space.

A)It was blasted from the surface of the planet Mars by an impact.
B)It is a fragment of a shattered asteroid that was at least 200 km in diameter.
C)It is a primitive (unaltered) piece of the early solar nebula.
D)It is a fragment of a shattered asteroid that was no more than about 25 km in diameter.

A)partial melting during the impact that ejected the meteorite from its parent asteroid, with subsequent rapid cooling in space
B)rapid crystal growth as molten iron cooled and solidified in the interior of a small asteroid
C)slow crystal growth as iron condensed from gas directly to solid form in the early solar nebula
D)slow crystal growth as molten iron cooled and solidified in the interior of a large asteroid

A)iron-nickel object that has existed unheated from the beginning of the solar system.
B)fragment of an undifferentiated (primitive) asteroid.
C)fragment from the core of a differentiated asteroid.
D)fragment from the crust of a differentiated asteroid.

A)preferential accretion of iron particles to other iron particles because of their magnetic properties, leaving stony particles to accrete separately.
B)fragmentation of asteroids that had become differentiated in a similar fashion to Earth (with the heavier iron sinking to the center).
C)different amounts of heating and "erosion" of the outer layers of meteorites as they pass through Earth's atmosphere.
D)formation in different parts of the early solar nebula, with stones condensing closer to the Sun and irons farther out.

A)These patterns require iridium, which is common in iron meteorites but is rare on Earth.
B)Widmanstätten patterns are radioactive.
C)These patterns involve crystals, which only form after millions of years of slow cooling.
D)These patterns are actually cracks in the structure of the meteorite that form only when an iron meteorite becomes heated during its passage through Earth's atmosphere.

A)a meteoroid or asteroid.
B)a comet.
C)the Van Allen radiation belt.
D)Mars or the Moon.

A)Evidence of a large impact like this one is highly radioactive. But during the two decades between the event and the investigation, the radioactivity had subsided.
B)The stony contents were all incinerated high in the atmosphere.
C)The stony contents all vaporized on impact, like those in the Barringer Crater in Arizona.
D)The stony contents were distributed widely over the ground. But after a few years of weathering, they became indistinguishable from ordinary rocks.

A)carbonaceous chondrites
B)fusion crust
C)high abundance of ²⁶Mg
D)Widmanstätten pattern

A)viruses
B)living cells
C)lichens and mosses
D)amino acids

A)almost all of its original amount
B)half of its original amount
C)1/6389 of its original amount
D)almost none

A)Radioactivity occurs naturally in normal matter and so this finding is not surprising.
B)An energetic nuclear event, possibly a supernova, occurred near the Sun and produced ²⁶Al at about the time that this meteorite was formed.
C)The meteorite became so hot on its descent through Earth's atmosphere, that it became radioactive.
D)The meteorite had probably passed through radioactive clouds in space before hitting Earth.

A)the detection of pure iron in many meteorites
B)the measurement of a fusion crust around most meteorites, indicating intense heating at some time
C)the discovery of amino acids in some meteorites
D)the discovery of the decay products of short-lived radioactive elements within some meteorites

A)nucleus.
B)coma.
C)envelope.
D)tail.

A)10⁶ km.
B)10⁷ km.
C)10 km.
D)100 m.

A)about the density of iron.
B)about the density of ordinary rock.
C)less than the density of water.
D)so small as to suggest that the nucleus is hollow.

A)flying past a comet with a spacecraft
B)collecting dust near the nucleus of a comet
C)smashing a projectile onto a comet's surface
D)landing on the surface of a comet

A)Hubble Space Telescope IR photography
B)ground-based photography, at the hydrogen Balmer $\alpha$ wavelength
C)radio measurements at 21 cm wavelength
D)rocketborne ultraviolet photography

A)1/2 au.
B)2 au.
C)1 million km.
D)10 million km.

A)visible to the naked eye from Earth's surface.
B)not visible from Earth's surface because of atmospheric absorption, but it is visible to the naked eye from a spacecraft above the atmosphere.
C)created from water molecules that are broken apart by infrared radiation from the Sun.
D)visible in an ultraviolet telescope above Earth's atmosphere.

A)sunlight glinting on and reflecting from the icy nucleus of a comet.
B)dust collected by the comet as it moves in its orbit.
C)solar wind particles being guided and excited to emit light by the comet's magnetic field.
D)melting and evaporation of ices from the comet's nucleus.

A)always lies in the ecliptic plane, because a comet is a part of the solar system.
B)lies between the comet and the Sun, because of gravitational attraction.
C)always trails along the orbital path, because of the comet's motion.
D)is always blown away from the comet in the anti-Sun direction by the solar wind.

A)its direction of motion, because the tail simply trails behind it in its orbit
B)the gravitational attraction of the Sun for the tail material
C)the gravitational attraction of Earth for the tail material
D)the flow of solar wind past the comet's nucleus

A)dust tail
B)ion tail
C)coma
D)hydrogen envelope

A)in the inner solar system. Sunlight, and the solar wind acting over billions of years, have pushed them out past the orbit of Pluto.
B)in elliptical orbits extending out to tens of thousands of astronomical units, and gravitational interactions with the giant planets have circularized their orbits into a band beyond Pluto.
C)exactly where we see them now, in a band beyond the orbit of Pluto.
D)between the orbits of Jupiter and Neptune. They were flung out beyond Pluto by gravitational interactions with the giant planets.

A)They originally formed in circular orbits far from the Sun (> 500 au), and passing stars have perturbed them into long, elliptical orbits.
B)They are interstellar objects that have been captured in orbit by the Sun.
C)They formed so far from the Sun (e.g., 10,000 au) that their orbits naturally drop deeply into the inner solar system.
D)They originally formed outside the orbit of Pluto and were flung into highly elongated orbits by the giant planets.

A)1000 years
B)100,000 years
C)10,000 years
D)10,000,000 years

A)0.27
B)0.63
C)0.87
D)0.99

A)less than 0.001%
B)10%
C)0.1%
D)0.5% to 1%

A)10,000 and 50,000.
B)1 and 5.
C)10 and 25.
D)100 and 200.

A)Earth passes through the fringes of the asteroid belt at these times.
B)Earth is bombarded by material, including dust grains, ejected from the Sun during regular sunspot activity.
C)Earth runs into material within the spiral arm structure of the Milky Way at these times.
D)Earth passes through a cloud of remnant dust and rock fragments from an old comet that is circling the Sun in the comet's old orbit.

A)this year Earth passed through the orbit of a recently disintegrated comet, one for which the debris is not yet distributed along the entire orbit.
B)a small comet has passed through Earth's atmosphere.
C)the meteor shower is the remnant of a comet that had a semimajor axis larger than 1 au and a period longer than 1 year.
D)the debris along the orbit was mostly fine dust, which has been blown away by the solar wind.

A)They formed the Kuiper belt.
B)They formed the inner, doughnut-shaped part of the Oort cloud.
C)They formed the outer, spherical part of the Oort cloud.
D)They were expelled from the solar system by interaction with Jupiter's gravity.