Deck 5: Exoplanets and the Formation of Planetary Systems

A) star and planets slowly condensed to their present form from a gas and dust cloud.
B) star captured the planets as they drifted through space.
C) system was once a galaxy from which the star and planets are the remnants, after evolution.
D) planets were spun out of the star as smaller gas clouds and subsequently condensed.

A) the center of our own Sun, through fusion and later ejection as solar wind.
B) chemical reactions in planetary atmospheres.
C) the original Big Bang of the universe.
D) fusion reactions in the centers of earlier stars.

A) 10%
B) much less than 1%
C) 2%
D) 50%

A) about equal amounts of all elements up to iron but very little of any heavier elements.
B) hydrogen and helium, with small amounts of heavier elements.
C) nitrogen and oxygen, with smaller quantities of hydrogen, helium, and heavier elements.
D) heavy elements, with smaller quantities of hydrogen and helium.

A) about 70%
B) 2%
C) much less than 1%
D) 98%

A) nebula made mostly of heavy elements but enriched in hydrogen and helium from supernova explosions
B) debris from the explosion of a massive star
C) nebula made entirely of hydrogen and helium gas
D) nebula made mostly of hydrogen and helium gas but enriched in heavier elements from planetary nebulae and supernova explosions

A) our bodies have converted the original hydrogen and helium into heavier elements.
B) the Big Bang model of the universe must be wrong.
C) the solar system did not form directly from the material created by the Big Bang.
D) the Big Bang created elements unevenly because the Sun, unlike our bodies, is mostly hydrogen and helium.

A) hydrogen and helium.
B) nitrogen and oxygen.
C) iron and silicon.
D) hydrogen.

A) stellar winds
B) planetary nebula
C) supernovae
D) fusion

A) nitrogen.
B) carbon dioxide.
C) water.
D) hydrogen.

A) 90%
B) 98%
C) 75%
D) about 50%

A) nebula of gas and dust around a giant planet
B) nebula of gas and dust around any planet
C) clouds of matter ejected into space by a dying star
D) result of a stellar explosion in which the entire star is blown apart

A) in the central cores of stars
B) in the surface layers of stars
C) at the event horizons of massive black holes
D) in the dark clouds of dust and gas

A) All the known elements have been formed by the breakup (radioactivity) of the heavy elements formed in the initial Big Bang.
B) All the known elements were formed in the Big Bang.
C) Hydrogen and helium were formed in the Big Bang, whereas the heavier elements have been slowly forming by collisions in cold interstellar gas clouds.
D) Hydrogen and helium were formed in the Big Bang, whereas the heavier elements were made in the centers of stars.

A) 2.5 to 1
B) 10 to 1
C) 4 to 1
D) 1 to 4

A) stellar winds may compress nearby gas and dust clouds.
B) a nearby supernova can compress nearby gas and dust clouds.
C) clouds can collide and compress each other.
D) radiation pressure from the cosmic microwave background can compress clouds of gas and dust.

A) in nuclear reactions in the cores of stars
B) in supernovae (exploding stars)
C) in the dark clouds of dust and gas
D) in the Big Bang, at the very beginning of the universe

A) All but 2% of the mass of the universe is hydrogen and helium.
B) All but 2% of the mass of the universe is hydrogen.
C) Two percent of the mass of the universe is hydrogen and helium. The rest is of heavier elements.
D) About half of the mass of the universe is in the form of rocks, molecules, and planetary material.

A) cool gas and dust clouds.
B) the centers of supernova explosions.
C) black holes dotted about the universe.
D) the centers of galaxies.

A) such systems could not have formed planets.
B) their composition differs so much from their stars.
C) their instruments were not thought to be powerful enough to make such a measurement.
D) gas and dust should be rapidly ejected into space by the radiation from a hot star.

A) emission from gas evaporated when the comets pass close to their star.
B) impacts on the system's gas giants.
C) their gravitational effects on the system's small planets.
D) obscuration caused by dust evaporated from the comets' nuclei.

A) When a growing protoplanet becomes too large, it is more likely to be split apart by subsequent bombardment than to grow further.
B) If a solar nebula is too massive it will continue to collapse to become a black hole and will not form planets.
C) If the disk of matter surrounding a solar nebula becomes too hot, it will dissipate, and planets will not form.
D) If a cloud of gas and dust is sufficiently dense, it will collapse due to its own gravity.

A) asteroids.
B) a solar wind.
C) much higher luminosity than the Sun.
D) Kuiper belts.

A) reflected light from the planets.
B) periodic variability in the brightness of stars.
C) periodic variability in the positions of stars on the sky.
D) periodic variability in the radial velocities of stars.

A) kinetic energy.
B) friction.
C) gravity.
D) electrostatic repulsion.

A) composition
B) kinetic energy
C) temperature
D) rotational speed

A) Comets
B) Asteroids
C) terrestrial planets
D) All of these are correct.

A) It would begin fusion at a higher internal temperature.
B) It would most likely lack a protoplanetary disk.
C) It would take much longer to form.
D) It would use a different set of fusion reactions to power itself.

A) faint pinpoints of light slowly circling some stars, as seen through the new 8- and 10-meter telescopes
B) slightly wavy path of a star through space, as if the star were being tugged by an orbiting planet
C) cyclic Doppler shift variations in the spectra of several stars
D) warped disks of dust and gas around some young stars

A) low temperature.
B) rapid internal motion.
C) low pressure.
D) high density.

A) gas giants.
B) brown dwarfs.
C) disks of dust without gas.
D) disks of gas and dust.

A) star.
B) black hole.
C) white dwarf.
D) galactic bulge.

A) winds from the young star.
B) variability from an active young star.
C) the gravitational influence of massive planets in the system.
D) collisions between asteroids.

A) spectroscopic evidence of large quantities of molecules such as ammonia and methane, which can exist only in planetary atmospheres.
B) images and infrared observations of disks of dust.
C) detection of very regular pulses of radio energy from some stars.
D) direct photography of actual planets near other stars.

A) The asteroids were imaged directly by the Hubble Space Telescope.
B) A ring of hot dust was discovered around the star by spectroscopy, and collisions among asteroids were inferred as the cause.
C) The gravitational effects of the asteroids have created an off-center disk of dust and gas around the star.
D) The gravitational effects of the asteroids cause the star to wobble slightly in its proper motion.

A) planetary nebulae.
B) jets from the young star.
C) planets in the disk.
D) comets.

A) ripples observed in the protoplanetary disks around these stars.
B) hot dust generated by collisions amongst the asteroids.
C) reflected light from the star.
D) spectral lines from gas evaporated from the asteroids.

A) increasing its radius
B) increasing its mass
C) increasing its orbital period
D) All of these are correct.

A) No evidence of planets beyond our own solar system has been found.
B) Astronomers have seen disks of material around stars that resemble the solar nebula believed to be an early stage in the formation of our solar system.
C) Astronomers have seen asteroid belts around other stars.
D) Astronomers actually have images of other stars being orbited by planets.

A) We use Newton's law of gravity, using the measured distance of the planet from its star and the planet's gravitational pull on the star.
B) We cannot make any firm estimate of the mass of an extrasolar planet with present technology.
C) We use spectra to measure the planet's temperature and photometry to measure its brightness.
D) We measure the planet's angular diameter and hence its size and then use spectra to find its composition and hence density.

A) orbit its star with a component of its motion parallel to the line of sight to from the star to Earth.
B) orbit its star with a component of its motion perpendicular to the line of sight to from the star to Earth.
C) have a low albedo.
D) have a high albedo.

A) decreasing its orbital period
B) decreasing its mass
C) decreasing its radius
D) decreasing its albedo

A) decreasing its mass
B) increasing its mass
C) decreasing its albedo
D) increasing its albedo

A) brightness.
B) velocity.
C) position on the sky.
D) spectrum.

A) orbital periods.
B) masses.
C) orbital plane.
D) diameters.

A) have a large mass.
B) orbit its star with a component of its motion perpendicular to the line of sight to from the star to Earth.
C) be the only exoplanet in the system.
D) have a high albedo.

A) their effects on the spectra of the stars.
B) the slow increase in the orbital period of the stars, induced by the planet's gravity.
C) the slow decrease in the orbital period of the stars, induced by the planet's gravity.
D) their effects on the timing of eclipses of the stars.

A) astrometric method
B) radial velocity method
C) transit photometry method
D) transit timing method

A) searching for tiny "bumps" on images of a star, due to the light from a planet located close to the star
B) searching for tiny displacements of the infrared image of a star compared with its optical image, caused by the presence of planets that are cool and emit primarily in the infrared
C) searching for tiny wobbles in the position of a star, due to the gravitational pull of a planet orbiting around it
D) searching for tiny wobbles in the positions of absorption lines in a star's spectrum, caused by radial velocity variations of the star as the result of a planet orbiting around it

A) The planet was imaged directly by the Hubble Space Telescope.
B) Effects of the intense magnetic field of this planet can be detected by powerful radio telescopes.
C) The gravitational effect of this planet has created an off-center disk of dust and gas around the star.
D) The planet causes a measurable decrease in the brightness of Beta Pictoris when it transits across its disk.

A) astrometric method
B) radial velocity method
C) variable transit timing method
D) phase cycle brightness method

A) looking for tiny variations in the star's position in the sky, caused by the gravitational pull of one or more planets orbiting the star
B) looking for tiny variations in the star's radial velocity, caused by the gravitational pull of one or more planets orbiting the star
C) looking for tiny variations in the star's brightness, caused by the planet moving in front of the star
D) using space-based telescopes to search for tiny pinpoints of light that follow circular or elliptical paths around the star

A) increasing its radius
B) increasing its mass
C) increasing its orbital period
D) All of these are correct.

A) The transit duration time variation and eclipsing binary minima variation methods
B) The astrometric and transit photometry methods
C) The phase cycle brightness and radial velocity methods
D) The distorted disk and radial velocity methods

A) the lunar cycle
B) solar eclipses
C) the gravitational motion of the Sun induced by the planets
D) lunar eclipses

A) their effects on the measured radial velocities of exoplanets.
B) their effects on the duration of exoplanet transits.
C) their infrared emission.
D) the light they reflect from their star.

A) increasing its radius
B) increasing its mass
C) increasing its orbital period
D) All of these are correct.

A) has an exoplanet with a thick atmosphere.
B) is actually a binary star.
C) has multiple exoplanets.
D) has an exoplanet with a ring system.

A) detection of very regular pulses of radio energy from some stars.
B) spectroscopic evidence of large quantities of molecules such as ammonia and methane, which can exist only in planetary atmospheres.
C) direct photography of actual planets near other stars.
D) periodic wobbling of the positions and spectral line displacements of several nearby stars.

A) the gravitational attraction of its star
B) the gravitational attraction of a nearby planet
C) collisions with small bodies
D) heating from its star

A) open clusters.
B) black holes.
C) globular clusters.
D) the nucleus of our Galaxy.

A) The relative positions of where the planets formed are inverted, with the Jovian-type planets forming close to the stars and the terrestrial-type planets forming farther out.
B) Many terrestrial planets discovered so far have masses intermediate between the terrestrial planets of our system and the ice giants.
C) The massive Jovian-type planets appear to have formed at large distances, like our own Jovian planets, and then spiraled in close to their stars.
D) There are no Jovian-mass planets.

A) around stars in the disk of our Galaxy.
B) in globular clusters.
C) near the center of our Galaxy.
D) outside our Galaxy.

A) radial velocity method
B) transit method
C) direct imaging
D) microlensing

A) circumplanetary disks
B) oxygen-rich atmospheres
C) moons
D) rings

A) around Sunlike stars.
B) in globular clusters.
C) orbiting black holes.
D) around binary star systems.

A) distorted protoplanetary disks.
B) variations in the stars radial velocity.
C) pulsar timing.
D) transits of the exoplanet in front of its star.

A) by timing the duration of consecutive transits
B) by resolving images of exoplanets and searching for color variations
C) by measuring absorption of starlight during transits
D) by measuring emission lines of directly imaged planets

A) They are more massive.
B) They are older.
C) They have larger diameters.
D) They are closer to Earth.

A) More than half of the extrasolar planets have strong lines of molecular oxygen in their spectra, a possible indication of life on these planets.
B) The majority of the extrasolar planets rotate much faster than the planets in our solar system.
C) Many of the extrasolar planets are giant planets like Jupiter, orbiting at distances characteristic of terrestrial planets like Earth, where giant planets were not believed to be able to form.
D) Many of the extrasolar planets are terrestrial planets like Earth, orbiting at distances characteristic of giant planets like Jupiter, where terrestrial planets were not believed to be able to form.

A) It implies that Earth lost a great deal of mass in the early solar system.
B) Such a large planetary mass was thought to be gravitationally unstable.
C) Models had predicted that the formation of such a large rocky core requires a protoplanetary disk many times larger than that of the solar system.
D) Models had predicted that a rocky protoplanet of such a mass would attract enough hydrogen to form a gas giant.

A) none
B) hundreds
C) thousands
D) millions

A) 0.42 light-year
B) 4.2 light-years
C) 42 light-years
D) 42,000 light-years

A) transit method
B) microlensing
C) distorted protoplanetary disk
D) radial velocity method

A) Astronomers do not know, because none have been detected so far.
B) They orbit only one of the stars.
C) They have an orbit around the center of mass of both stars.
D) Some orbit one of the stars, while some have an orbit around the center of mass of both stars.

A) roughly the size of Earth
B) 1.5-3 times the size of Earth
C) roughly the size of Jupiter
D) larger than Jupiter

A) larger than Jupiter.
B) super-Earths.
C) hot Jupiters.
D) ice giants.

A) increasing its radius
B) increasing its mass
C) increasing its orbital period
D) All of these are correct.

A) variations in the brightness of a star that is distant from both the exoplanet and Earth.
B) variations in the brightness of the star the exoplanet orbits.
C) variations in the spectrum of a star that is distant from both the exoplanet and Earth.
D) variations in the spectrum of a star that the exoplanet orbits.