Deck 15: Exoplanets: Planetary Systems Beyond Our Own

A) a catastrophic theory.
B) a hot Jupiter theory.
C) a collision hypothesis.
D) an evolutionary theory.
E) a capture theory.

A) estimates of orbits and masses
B) complete composition
C) precise masses
D) All of the above
E) None of the above

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

A) noting the drop in the star's light as the planet transits its disk.
B) imaging them with the HST in the infrared, where they are easier to stop.
C) noting the Doppler shifts of the star as the planet orbits it from side to side.
D) receiving radio transmissions from them, much like Jupiter emits.
E) detecting the oxygen in their atmospheres spectroscopically.

A) They are irrelevant to models of planetary formation.
B) They help confirm models that lead to random encounters.
C) They help reject models that allow for moons to have retrograde orbits.
D) They help reject models that allow for hot Jupiters.
E) They indicate that the condensation model is the only possible explanation of how solar systems form.

A) planets whose orbits are along our line of sight.
B) planets whose orbits are perpendicular to our line of sight.
C) planets whose orbits are nearly circular.
D) planets whose orbits are very eccentric.

A) Direct imaging is only possible using military satellites.
B) Direct imaging only works if the planet is orbiting a brown dwarf.
C) Only a few attempts have been made to directly image an extrasolar planet.
D) Exoplanets are faint and are usually close to their parent stars.

A) shortly after the invention of the telescope, in the early 1600s
B) in prehistoric times
C) around 350 BC, by the Ancient Greeks
D) early in the 21st century
E) near the end of the 20ᵗʰ century

A) planets that are most earthlike, likely to harbor life.
B) planets that are a few times the mass of the Earth.
C) planets that have earthlike masses, but orbit much closer to their star than the Earth does to the Sun.
D) any rocky (or terrestrial) planet.
E) Earth-mass planets that are much lower in density than the Earth, giving them larger radii.

A) orbits very close to their parent stars, making them hot Neptunes and hot Jupiters.
B) orbits that are more eccentric than those of planets in our solar system, with eccentricities greater than 0.1.
C) orbits that are less eccentric than those of planets in our solar system, with eccentricities less than 0.01.
D) much larger orbits than the jovian planets in our solar system.

A) radial velocity measurements
B) direct imaging
C) measurements of transverse motion
D) planetary transits

A) All are terrestrials, comparable in size to Earth.
B) Few are found by Doppler shifts of their stars, due to their gravity.
C) All lie more than 2 A.U. from their star.
D) Most have orbital periods of more than a year.
E) Some are so close to their stars that their periods are just a few days.

A) the Moon's periods of rotation and revolution are equal
B) the orbital periods of Neptune and Pluto
C) the Kirkwood Gaps in the asteroid belt
D) Venus' cloud and surface rotation rates
E) Mercury's rotation and revolution around the Sun

A) it will cause the star to vanish for several hours.
B) we can find the planet's size, mass, and density by the drop in light.
C) we can determine what elements are in its atmosphere.
D) we can determine its shape.
E) we can be certain it is a terrestrial, not a jovian.

A) Venus' low rate of rotation
B) Mars' north-south asymmetry
C) the tilt of Uranus' rotation axis
D) binary Kuiper Belt objects
E) All of the above

A) are all rocky planets, like the terrestrial planets in our solar system.
B) are all jovian planets.
C) include some Earths and super-Earths.
D) include hot Jupiters.
E) have been demonstrated to be barren of all life.

A) Olympus Mons
B) its curious north-south asymmetry
C) Hellas Basin
D) the Marianas Trench
E) its exceptionally large nickel-iron core

A) large jovians orbiting solar-type stars about where our jovians are found.
B) large jovians with terrestrial-type orbits.
C) terrestrials very close to their star, and transiting its disk.
D) terrestrials with very elongated, distant orbits like comets.
E) brown dwarfs much more massive than Jupiter.

A) Kuiper Belt objects, far from the glare of their suns.
B) large jovians far from stars like our Sun.
C) large jovians with orbits more like terrestrial planets.
D) terrestrials very close to their star, and transiting its disk.
E) imaginary, with no present proof that they really exist.

A) less than 10%.
B) less than 1%.
C) less than 0.01%.
D) less than 0.0001%.
E) any size.

A) high mass star, high mass planet
B) high mass star, low mass planet
C) low mass star, high mass planet
D) low mass star, low mass planet
E) a high mass planet; the mass of the star is irrelevant

A) the exceptionally large nickel-iron core of Mercury.
B) the asteroid belt.
C) our Moon.
D) the tilt of Uranus.
E) the appearance of Miranda's surface.

A) a matter of months.
B) 4.4 years.
C) about a century.
D) about 40,000 years.
E) close to a million years.

A) planets with life have been found.
B) human beings could live.
C) the Greenhouse Effect is possible.
D) a planet could have an atmosphere.
E) temperatures are suitable for planets to have liquid water.

A) a brown dwarf.
B) a Jupiter.
C) a Neptune.
D) a super-Earth.
E) an Earth.

A) most orbits are less circular than the orbits of planets around our Sun.
B) jovians often lie much closer to their suns than ours do.
C) multiple planets are found in some systems.
D) hot Jupiters, even closer to their stars than Mercury is to our Sun.
E) All of the above

A) 5, all around stars within 20 light years of us.
B) 42, all much bigger than Jupiter, but orbiting red dwarf stars.
C) over 400, orbiting more than 300 stars.
D) about 900, mainly around stars much smaller and fainter than our Sun.
E) thousands, around every star we have closely examined to date.

A) gravitational interactions with the gas disk.
B) magnetic attraction to the parent star.
C) interactions with another star.
D) large impacts.
E) many small impacts.

A) shortly after all of the planets had finished forming
B) just after the system was cleared of the remaining gas
C) before these planets had grown to full size
D) after these planets had reached full size, but before terrestrial planets had finished forming
E) at least hundreds of millions of years after planetary formation ended

A) should be randomly oriented to their star's equator.
B) will revolve opposite the star's rotation.
C) should be a common result of star formation.
D) should be extremely rare.
E) should orbit perpendicular to their star's equator.

A) These small planets are very rare.
B) Low mass planets do not produce large enough radial velocity changes in their stars.
C) High mass planets are blocking our views of low mass planets.
D) Hot Jupiters have ejected most low mass planets from their solar systems.
E) Low mass planets are too far from their parent stars to receive enough light to make them visible from Earth.

A) brown dwarfs.
B) red dwarfs.
C) white dwarfs.
D) red giants.
E) blue giants.

A) that planetary orbits are relatively coplanar.
B) for the presence of hot Jupiters in some systems.
C) that planets orbit in the same direction that their parent star rotates.
D) that the systems contain interplanetary debris, such as comets or asteroids.
E) None of these are dissimilar to our solar system.

A) Hot Jupiters have fusion reactions; cold Jupiters do not.
B) Hot Jupiters orbit close to the parent stars; cold Jupiters do not.
C) Hot Jupiters radiate more energy than they receive from their star; cold Jupiters do not.
D) Hot Jupiters have observed volcanoes; cold Jupiters do not.
E) Hot Jupiters were an exciting discovery; cold Jupiters were not.

A) above 5 Earth radii.
B) between 2 and 5 Earth radii.
C) between 1.25 and 2 Earth radii.
D) between 0.75 and 1.25 Earth radii.
E) below 0.75 Earth radii.