Deck 6: The Birth and Evolution of Planetary Systems

A) 1 million years
B) 600 years
C) 6 years
D) 4 months

A) The early Solar System must have been flat.
B) The material from which the planets formed must have been swirling about the Sun in the same direction.
C) The first fragments started out small and grew in size over time.
D) The composition of gases varied between the inner Solar System and the outer Solar System.

A) 10
B) 26 thousand
C) 36 million
D) 50 billion

A) 50 percent
B) 10 percent
C) 5 percent
D) < 1 percent

A) 70
B) 640
C) 25,000
D) 4 million

A) These gases were more abundant in the outer regions of the accretion disk where the outer planets formed.
B) The outer planets grew massive quickly enough to gravitationally hold on to these gases before the solar wind dispersed the accretion disk.
C) The inner planets were too close to the Sun,and solar winds blew away their original gaseous atmospheres.
D) Frequent early collisions by comets with the inner planets caused most of their original atmospheres to dissipate.

A) other names for moons of the planets.
B) primarily located within 1 AU of the Sun.
C) all more massive than Earth's moon.
D) material left over from the formation of the planets.

A) equally in all directions.
B) only when the cloud is not rotating initially.
C) mostly along directions perpendicular to the cloud's axis of rotation.
D) mostly at the poles that lie along the cloud's axis of rotation.

A) 4.5 billion years
B) 4.5 million years
C) 13.7 billion years
D) 13.7 million years

A) the giant planets are much larger.
B) only the terrestrial planets have iron cores.
C) the terrestrial planets are closer to the Sun.
D) the giant planets are made mostly of carbon.

A) Most of it
B) Roughly half of it
C) A small amount of it
D) Barely any at all

A) metal.
B) silicate.
C) rock.
D) ice.

A) It is converted into thermal energy,heating the disk.
B) It is converted into light energy,giving off a flash of light upon impact.
C) It is converted into potential energy as the gas plows through the disk and comes out the other side.
D) It simply dissipates.

A) out of a collision between the Earth and a Mars-sized object.
B) when the Earth's gravity captured a planetesimal.
C) when the accretion disk around the Earth fragmented.
D) when planetesimals collided to form a more massive object.

A) Uranus is "tipped over" so that it rotates on its side.
B) Valles Marineris on Mars is a huge scar,many times deeper than the Grand Canyon,which spans one-fourth the circumference of the planet.
C) Mercury has crust that has buckled on the opposite side of an impact crater.
D) Mimas has a crater whose diameter is roughly one-third of the moon's size.

A) its mass.
B) its temperature.
C) the distance from the star that it orbits.
D) All of the above

A) spin faster.
B) spin slower.
C) maintain a constant rate of spin.
D) fall over.

A) fragmentation of the accretion disk surrounding the protostar.
B) the merger of two large planetesimals.
C) an eruption of material from the protostar.
D) materials condensing out of the solar wind.

A) potential;thermal
B) kinetic;thermal
C) kinetic;potential
D) potential;total

A) Its distance from the forming star
B) How much kinetic energy was converted to heat
C) How much radiation from the forming star shines on the gas
D) All of the above

A) carbon and oxygen.
B) hydrogen and helium.
C) iron and nickel.
D) nitrogen and argon.

A) The forming protostar would be significantly less massive than it would have been otherwise.
B) The forming protostar would be rotating too fast to hold itself together.
C) Only Jovian planets would form around the protostar.
D) Only terrestrial planets would form around the protostar.

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

A) A sphere on the top shelf of a bookshelf.
B) A sphere rolling on the floor at the base of the bookshelf.
C) A sphere sitting at rest on the floor at the base of the bookshelf.
D) A sphere on the middle shelf of a bookshelf.

A) No,its composition is too different from stars for it to become one.
B) Yes,but it cooled off before it could become a star.
C) No,it would have to be at least 80 times more massive.
D) Yes,it is in the process of becoming a star in the near future.

A) Doppler shift
B) transit
C) direct imaging
D) microlensing

A) extra-solar planetary systems that are similar to our own solar system.
B) Earth-sized planets around other stars.
C) Earth-sized planets at distances of 10 AU from their parent stars.
D) extra-solar planetary systems that contain more than one planet.

A) 1 Jupiter mass.
B) 13 Jupiter masses.
C) 42 Jupiter masses.
D) 80 Jupiter masses.

A) These planets must have formed at larger radius where temperatures were cooler and then migrated inward.
B) Jupiter-sized,rocky planets were thought to be uncommon in other solar systems.
C) These planets must be the remnants of failed stars.
D) Earth-like planets must be rarer than Jupiter-sized planets in other solar systems.

A) It repeatedly collided with planetesimals.
B) It is too close to the Sun.
C) It is not massive enough.
D) It is tidally locked to Earth.

A) A Jupiter-sized planet occults a larger area than an Earth-sized planet.
B) A Jupiter-sized planet exerts a larger gravitational force on the star than an Earth-sized planet,and the Doppler shift of the star is larger.
C) A Jupiter-sized planet shines brighter than an Earth-sized planet.
D) Earth-sized planets are much rarer than Jupiter-sized planets.

A) Jupiter's gravitational pull.
B) Earth's gravitational pull.
C) convection on the Sun's surface.
D) the sunspot cycle.

A) Yes,although the ones detected lie much closer to their stars than we do to ours.
B) Yes,although the ones detected lie much farther from their stars than we do from ours.
C) No,we do not have the technology to detect such low-mass planets yet.
D) No.Although we have the technology to detect low-mass planets,we haven't found any others yet.

A) of rocky composition like the Earth.
B) comparable in mass to Neptune or more massive.
C) less massive than Mars.
D) located at distances much larger than Jupiter's distance from the Sun.

A) the planet must pass directly in front of the star.
B) the planet must have a rocky composition.
C) the star must be very dim.
D) the star must be moving with respect to us.

A) losing orbital angular momentum.
B) colliding with another planet.
C) slowly accreting large amounts of gas and increasing their gravitational pull.
D) losing their gas due to evaporation.

A) Over 330 extra-solar planets have been discovered to date from radial velocity surveys.
B) The most common type of extra-solar planet found to date has a few times the mass of Jupiter and lies within a few AU from its parent star.
C) No extra-solar planets have been imaged directly to date;all have all been found by indirect methods.
D) A star can brighten significantly due to gravitational lensing when a planet that orbits it passes directly in front of the star.