Deck 12: The Origin of the Solar System

A)the adding of material to an object an atom or molecule at a time
B)the adding of material to an object by collection of solid particles
C)the release of gas from rocks as they are heated
D)the removal of material from asteroids by the bombardment of the solar wind

A)a planet that orbits our Sun that we have not yet discovered
B)a planet found orbiting around a star other than the Sun
C)a planet just outside the edge of the solar system
D)a planet just outside the surface of our Sun

A)the high speed at which the Jovian planets rotate on their axes and the consequent flattening of their shapes
B)the existence of rings around the Jovian planets
C)the excess heat radiated by the larger of the Jovian planets
D)the apparently short period of time that disks exist around stars from which Jovian planets can form

A)precipitation
B)differentiation
C)condensation
D)sublimation

A)sublimation
B)accretion
C)hydration
D)condensation

A)comets
B)asteroids
C)terrestrial planets
D)Jovian planets

A)asteroid
B)meteor
C)comet
D)meteoroid

A)the solar wind
B)outgassing
C)the Sun's magnetic field
D)differentiation

A)our Sun
B)Jupiter
C)the Big Bang
D)supernovae

A)They grew in size primarily by accretion.
B)They grew in size primarily by condensation.
C)They grew in size by collecting the particles in the solar wind.
D)They grew in size by the collision and coalescing of planetesimals.

A)high average density
B)orbits outside the asteroid belt
C)large diameters
D)many satellites

A)our Sun
B)Jupiter
C)the Big Bang
D)supernovae

A)the adding of material to an object an atom or molecule at a time
B)the adding of material to an object by collection of solid particles
C)the release of gas from rocks as they are heated
D)the removal of hydrogen via nuclear fusion

A)water ice; rock; iron
B)rock; iron; water ice
C)water ice; iron; rock
D)iron; rock; water ice

A)14 billion years old
B)10.5 billion years old
C)7.0 billion years old
D)4.4 billion years old

A)sublimation
B)decay of radioactive element isotopes
C)differentiation
D)ignition of hydrogen fusion

A)orbits inside the asteroids
B)low average density
C)craters in old surfaces
D)very few satellites

A)accretion
B)sublimation
C)hydration
D)condensation

A)The planet will probably have about the same radius as the Earth
B)The planet will probably have a mean density of around 5 g/cm³.
C)The planet will probably have a composition that is mostly hydrogen and helium.
D)The planet will probably have liquid water oceans.

A)heat from the Sun
B)radioactivity of light elements, such as hydrogen and helium
C)the in-falling of material at high velocity
D)collisions with large planetesimals

A)Jupiter
B)Pluto
C)Venus
D)an asteroid

A)samples of proto-solar nebula
B)samples of the solar wind
C)crater counts on Earth
D)isotope ratios in meteorites

A)Vesta
B)Earth
C)Saturn
D)Venus

A)It was recovered only days after it fell to Earth.
B)It was the first meteorite recovered in Canada.
C)Signs of life were discovered deep inside it.
D)Its large crater showed that cratering still occurs on Earth.

A)They were initially molten, forming an iron core first, then they accreted a silicate crust later.
B)They were initially molten, forming a silicate core first, then they accreted an iron crust later.
C)They were initially collections of solid particles, which melted, then differentiated into a high density iron metal core and low density silicate crust.
D)They were initially collections of solid particles, which melted, then differentiated into a high density silicate core and low density iron metal crust.

A)They were moving faster in their orbits than the smaller planetesimals.
B)Their stronger gravity would pull in more material.
C)There was more material located near them that could be accreted.
D)The smaller planetesimals were covered by a layer of material that was lost during collisions.

A)the remnants of the original hydrogen and helium gas from the solar nebula attracted by the protoplanet
B)the result of the melting and vaporizing of the glaciers from the last ice age
C)gases that were outgassed from the heated rocks sometime after the planet formed
D)hydrogen and helium from a collision between the Sun and another star

A)hydrogen and helium
B)metals and metal oxides
C)silicates
D)ices of water, methane, and ammonia

A)Kepler can detect signs of life on planets.
B)Kepler can detect planets outside the Milky Way.
C)Kepler can detect many more planets.
D)Kepler can detect much smaller planets.

A)higher density core and lower density mantle
B)lower density core and higher density mantle
C)there is no way to measure changes in interior density
D)there is no separation according to density

A)2.6 billion years
B)3.9 billion years
C)5.2 billion years
D)6.5 billion years

A)the one farthest from the star
B)the one with the greatest mass
C)the one with the greatest radius
D)the one closest to the star

A)because it is a pulsar with planets orbiting around it
B)because it is a star with a planet that is known to support intelligent life
C)because it is the largest satellite of Jupiter and is suspected to have liquid oceans
D)because it is the first star similar to our Sun that was found to have a planet orbiting it

A)icy grains near the present orbit of Mercury
B)metallic grains near the present orbit of the Earth
C)icy grains beyond the present orbit of Jupiter
D)metallic grains beyond the present orbit of Jupiter

A)about 67 particles per second
B)about 100 million particles per second
C)about 100 billion particles per second
D)about 3.3×10²¹ particles per second

A)Debris disks have higher density than planet-forming disks.
B)Debris disks contain larger amounts of gas than planet-forming disks.
C)Debris disks are found around older stars than those with planet-forming disks.
D)Only debris disks are expected to be affected by the gravity of planets within them.

A)Uncompressed density is greatest for the Jovian planets.
B)Uncompressed density is greatest for the planets closest to the Sun.
C)Uncompressed density is greatest for the planets farthest from the Sun.
D)Uncompressed density is greatest for the planets with the largest mass.

A)The solar nebula from which the planets formed collapsed into a disk-like structure.
B)The bipolar flow from the young Sun cleared all material out of the nebula except the material in the disk.
C)Jupiter's gravity was great enough to pull all of the other planets to the plane of its orbit.
D)The Milky Way galaxy from which the planets condensed has a disk-like structure.

A)about 12 km
B)about 120 km
C)about 350 km
D)about 1738 km

A)Both the amounts of radioactive and decay material are measured. Using these with the radioactive material's half-life, the age can be estimated.
B)The amount of radioactive material is measured. Using this with the radioactive material's half-life, the age can be estimated.
C)The amount of decay material is measured. Using this with the radioactive material's half-life, the age can be estimated.
D)The amount of heat generated by radioactive dating is measured to determine age.

A)They are more dense.
B)They have fewer moons.
C)They have much larger diameters.
D)They are much hotter.

A)Space debris is left over material from the early solar system that never formed into a planet.
B)Space debris was formed when another solar system passed through ours.
C)Space debris is material that existed in our region of space before the Sun formed.
D)Space debris was formed when a planet crashed into the Sun.

A)common direction of rotation of the planets
B)number of satellites of each planet
C)the formation of hydrogen atoms in the solar system from subatomic particles
D)number of planets of each type

A)Earth and Mars
B)Mars and Jupiter
C)Jupiter and Saturn
D)Venus and Earth

A)Stars are found to exist more often in binaries than by themselves.
B)Protostars are seen to radiate much of their light at infrared wavelengths.
C)Nearby stars tend to be low mass red dwarfs.
D)Young stars are found to have hot disks that surround them.