Deck 11: The Lives of the Stars From Birth Through Middle Age

A) large quantities of dust that absorb and scatter light but no gas, either atomic or molecular.
B) variable amounts of gas but no dust, which forms only in planetary systems near stars.
C) a perfect vacuum.
D) gas, both atomic and molecular, and dust.

A) OH, hydroxyl
B) H₂, molecular hydrogen
C) CO, carbon monoxide
D) H₂O, water

A) carbon
B) helium
C) oxygen
D) hydrogen

A) the additional contribution to this starlight by emission from hydrogen gas in the ISM.
B) preferential scattering of blue starlight by fine dust grains.
C) Zeeman shift of the light by the powerful magnetic fields existing within the ISM.
D) scattering of this light from rapidly moving material; the light is Doppler-shifted toward the red end of the spectrum.

A) interstellar reddening.
B) the Balmer spectrum of hydrogen.
C) the Doppler effect.
D) any one of these three phenomena.

A) giant molecular cloud.
B) dark nebula.
C) reflection nebula.
D) stellar "nursery."

A) scattering of starlight
B) collection of dust and gas by spacecraft
C) emission of electromagnetic radiation by atoms and molecules
D) absorption of light from more distant stars

A) gamma-ray
B) ultraviolet
C) infrared
D) X-ray

A) helium
B) carbon
C) nitrogen
D) iron

A) Bode's law.
B) Wien's law.
C) the Stefan-Boltzmann law.
D) Kirchhoff's law.

A) the photons of light become "tired" and appear less bright as they travel.
B) the cosmological redshift has moved some of the light into the infrared spectral region.
C) star clusters are systematically smaller and hence less bright the farther they are from the galactic center and hence from the Sun.
D) light is scattered and absorbed by interstellar dust and gas between distant clusters and Earth.

A) interstellar reddening.
B) the Balmer spectrum of hydrogen.
C) the Doppler effect.
D) interstellar reddening, the Balmer spectrum of hydrogen, or the Doppler effect.

A) 90%
B) less than 1%
C) 50%
D) 10%

A) isolated atoms
B) isolated molecules
C) small pieces of dust
D) meteoroids

A) interstellar reddening.
B) the Balmer spectrum of hydrogen.
C) the Doppler effect.
D) interstellar reddening, the Balmer spectrum of hydrogen, or the Doppler effect.

A) optical telescopes.
B) gamma ray observatories.
C) radio telescopes.
D) ultraviolet detectors.

A) hydrogen and carbon
B) hydrogen and oxygen
C) hydrogen and helium
D) nitrogen and oxygen

A) atoms and ions
B) molecules
C) dust
D) radioactive elements

A) interstellar extinction.
B) interstellar reddening.
C) emission nebulae.
D) a reflection nebula.

A) ammonia (NH₃)
B) hydrogen (H₂)
C) formaldehyde (H₂CO)
D) carbon monoxide (CO)

A) in clumps, concentrated in interstellar clouds
B) concentrated in narrow river-like streams of gas that extend across the Galaxy
C) uniformly distributed through space
D) concentrated around existing stars because of the stars' gravitational pull

A) atomic hydrogen.
B) carbon monoxide.
C) carbon dioxide.
D) buckminsterfullerene (buckeyballs).

A) molecular hydrogen (H₂)
B) atomic hydrogen (H)
C) carbon monoxide (CO)
D) water vapor (H₂O)

A) 50%
B) 2%
C) 10%
D) 25%

A) the mass of about 1000 solar masses in a volume with a diameter of about 1000 ly
B) the mass of about 1 million solar masses in a volume with a diameter of about 100 ly
C) the mass of about 1 million solar masses in a volume with a diameter of about 100 AU, about the size of the solar system
D) the mass of about 1000 solar masses in a volume with a diameter of about 100 ly

A) 40,000 solar masses
B) 1 million solar masses
C) 1.5 million solar masses
D) 1.96 million solar masses

A) 500 million molecules of H₂ per cubic meter
B) 500 molecules of H₂ per cubic meter
C) 5 million molecules of H₂ per cubic meter
D) 50,000 molecules of H₂ per cubic meter

A) 100 ly across
B) 1000 ly across
C) anything up to about 1 ly across
D) 10 ly across

A) X-ray
B) visible
C) ultraviolet
D) radio

A) by direct sampling by space probes
B) by observing the chemical reactions in which they are created
C) only by theoretical modeling since it is known that the component elements (H, C, O) are present in space
D) by molecular emission lines

A) water vapor (H₂O)
B) formaldehyde (H₂CO)
C) methane (CH₄)
D) ammonia (NH₃)

A) 10 times the size of the solar system and contain 2 to 3 solar masses of material.
B) 10 pc across and contain a few thousand solar masses of material.
C) 100 pc across and contain 2 million solar masses of material.
D) 1000 pc across and contain 100 million solar masses of material.

A) red
B) yellow
C) green
D) blue

A) visible light
B) radio waves
C) X rays
D) ultraviolet light

A) carbon monoxide (CO)
B) methane (CH₄)
C) water vapor (H₂O)
D) carbon dioxide (CO₂)

A) 40,000 solar masses
B) 1 million solar masses
C) 200,000 solar masses
D) 500,000 solar masses

A) 10 to 100 solar masses
B) 1000 to 10,000 solar masses
C) 100,000 to 1 million solar masses
D) 10 million to 1 billion solar masses

A) 2%
B) almost 50%
C) 74%
D) 98%

A) hydroxyl (OH)
B) water vapor (H₂O)
C) carbon dioxide (CO₂)
D) carbon monoxide (CO)

A) emission nebula.
B) black hole.
C) Bok gobule.
D) dark nebula.

A) ultraviolet radiation from O and B stars
B) X rays from the coronas of solar-type stars
C) infrared radiation from pre-main-sequence stars
D) gamma rays from neutron stars

A) a region of ionized hydrogen around one or more hot O- and B-type stars
B) a region of molecular hydrogen inside a giant molecular cloud
C) a region of neutral, atomic hydrogen in interstellar space
D) a region of gas and dust formed by the explosion of a massive star

A) Massive stars gradually shrink to the size of Earth.
B) We don't know how massive stars normally end their lives since their lifetimes are longer than the age of the universe.
C) Massive stars collapse and become black holes.
D) Massive stars explode.

A) hot supernova remnants.
B) activity around black holes in the centers of galaxies.
C) huge, cool dust and gas clouds.
D) pure energy in free space.

A) observation of the reddening of the spectra of these stars because of absorption of blue light by hydrogen.
B) observation of emission of characteristic red Balmer light from nebulosity around them.
C) theoretical calculations that correctly describe stellar formation by the gravitational contraction of hydrogen gas.
D) observation of the blue glow from scattered light in their reflection nebulae.

A) emission of red and infrared light by warm dust grains.
B) collective glow of many red giant stars in the region.
C) scattering of starlight by dust grains in the nebula.
D) ionization and subsequent recombination of hydrogen atoms.

A) gravitationally bound.
B) the result of star formation within a single giant molecular cloud.
C) associated with solo stars like our Sun.
D) known to contain more than about a hundred stars.

A) electrons dropping between energy levels n = 3 and n = 2 in hydrogen atoms
B) electrons dropping between energy levels n = 2 and n = 1 in hydrogen atoms
C) thermal blackbody radiation emitted by the hot gas
D) scattering of starlight from dust grains in the nebula

A) atoms of gas emitting light by fluorescence, having been excited by ultraviolet radiation from hot stars.
B) light emitted by interstellar gases but Doppler-shifted by motion toward the observer.
C) starlight reflected by blue-colored interstellar material.
D) starlight scattered and reflected by small dust grains in the interstellar material.

A) young O and B stars.
B) red supergiants.
C) hot white dwarfs.
D) T Tauri stars.

A) Open star clusters slowly condense into globular clusters as the stars drive off the remaining interstellar dust and gas.
B) One star in an open cluster eventually undergoes a supernova explosion that quickly disperses the other stars.
C) As open star clusters slowly condense, their residual rotation spins them into a flat pancake shape and they become spiral galaxies.
D) The motions of individual stars are such that all open clusters eventually disperse.

A) thermal energy emitted as a continuous spectrum by the very hot gas, much like that emitted by a hot body on Earth.
B) light from embedded stars reflected over a wide range of wavelengths toward Earth by crystals of water, methane, and ammonia ices.
C) emission lines from hydrogen, which itself has been ionized by UV light from embedded stars.
D) blue light preferentially scattered by dust grains.

A) the light of all colors predominantly in the red part of the spectrum, emitted by cool stars and reflected by crystals of water ice surrounding the stars.
B) several specific colors, resulting from fluorescence of atoms excited by ultraviolet radiation emitted by hot stars.
C) blue, caused by the scattering of light from dust grains.
D) red, resulting from the emission of light from hydrogen gas.

A) the centers of galaxies.
B) nebulae composed of gas and dust.
C) regions surrounding quasars.
D) the rarified space between galaxies.

A) UV emission from hot O and B stars.
B) supernovae (exploding stars).
C) collisions between gas clouds in interstellar space.
D) T Tauri stars.

A) bathing the cold, dark nebula in ultraviolet radiation and sweeping away some of the colder material.
B) compressing the gas and dust so that gravitation will overcome the gas pressure.
C) heating the gas so that gas pressure will overcome gravitation.
D) subjecting the dark nebula to an intense magnetic field so that supersonic jets will form.

A) The shape of the cluster will remain more or less as it is at the present time as the stars in it age and die.
B) The stars in the cluster escape one by one until the cluster no longer exists.
C) Over time, the stars collide and merge, eventually creating a black hole.
D) The stars gradually sink toward the center, creating a globular cluster.

A) in or near old open clusters
B) around hot stars
C) in globular star clusters
D) around low-mass stars

A) starlight scattered from interstellar dust in the star cluster
B) starlight scattered by the light-sensitive grains in the photographic plate when the picture was taken
C) shock waves losing energy to interstellar gas in the star cluster, causing the atoms to emit light
D) starlight absorbed and reemitted by interstellar gas in the star cluster

A) a sphere of gas after collapse from an interstellar cloud but before nuclear reactions have begun
B) a small interstellar cloud before it collapses to become a star
C) a star near the end of its life before it explodes as a supernova
D) a shell of gas left behind from the explosion of a star as a supernova

A) while it is converting hydrogen into helium in its core
B) when it is expanding in size as a red giant or supergiant
C) after nuclear reactions end in its core but before the red giant phase
D) after condensation but before nuclear reactions begin in its core

A) The cloud must be alone in space (far from stars and other interstellar clouds).
B) Gravity must dominate gas pressure inside the cloud.
C) Gravity must be strong enough to reach all parts of the cloud.
D) The cloud must be cooler than 100 K.

A) infrared
B) X-ray
C) ultraviolet
D) optical

A) uniformly spread throughout the Galaxy, both in and above and below the spiral arms
B) the center of the Galaxy
C) above and below the plane of the spiral arms, over the galactic poles
D) along the spiral arms

A) gravitational contraction of a hot gas cloud
B) collisions between two interstellar clouds
C) supernova explosions and the resultant shock waves
D) radiation pressure from the intense UV radiation from hot stars

A) heating of an interstellar cloud by concentrated beams of neutrinos from nearby stars
B) compression of cold interstellar gas by radiation pressure from light from very bright stars
C) condensation of matter by the shock wave from a nearby supernova
D) collision of two cold interstellar clouds

A) Higher temperatures help star formation.
B) Star formation is independent of the temperature of the cloud.
C) Star formation is too complicated to be able to say how one quantity, such as temperature, affects it.
D) Higher temperatures inhibit star formation.

A) because of radioactive elements that were created in the supernova and carried along with the remnant.
B) when large hot stars form within the gas and dust of the remnant and emit radiation which excites the remaining gas.
C) when they collide with other clouds of gas and dust.
D) when they interact with the galaxy's strong magnetic field.

A) the outer part of the solar system
B) globular clusters
C) reflection nebulae
D) giant molecular clouds

A) near black holes
B) in dense dust and gas clouds
C) in the empty space between galaxies
D) in globular clusters of stars

A) open cluster.
B) galaxy.
C) constellation.
D) gravitational lens.

A) The innermost part collapses first; then the outer part is drawn in by the gravity of the inner part.
B) The collapse is turbulent and chaotic, with no overall pattern.
C) The outer, less dense part falls in first and its weight accelerates the collapse of the inner part.
D) All parts of the cloud accelerate inward more or less smoothly and evenly.

A) a few hundred members, often very young and still embedded in the gas and dust from which they were formed.
B) hundreds of thousands of members, all very old, surrounded by very little interstellar gas and dust.
C) a few dozen members, the remnant of a globular cluster of stars from which most of the members have escaped.
D) many thousands of members of different ages.

A) dark nebula.
B) reflection nebula.
C) supernova remnant.
D) giant molecular cloud.

A) explosion of a star at the end of its life, the supernova phenomenon.
B) overcoming of gas pressure by self-gravity in a cold and dense interstellar cloud to form a star.
C) conditions under which sufficient numbers of neutrinos can trigger the collapse of an interstellar cloud.
D) expansion of a gas cloud after gravitational contraction because of build-up of great heat within the cloud from gravitational potential energy.

A) collisions between interstellar clouds
B) heating of an interstellar cloud by radiation from embedded young stars
C) compression of an interstellar cloud by the shock waves from supernova explosion
D) compression of an interstellar cloud by the pressure of light from nearby stars

A) less than 1 K
B) 10 K
C) 1000 K
D) 100 K

A) temperature since higher temperatures act to prevent collapse
B) the amount of gravity pulling inward compared with gas pressure pushing outward
C) gas density, the ratio of the mass of the cloud over its volume, since density determines how gravity will act on the cloud material
D) the amount of mass in the cloud since mass determines the strength of gravity

A) in emission nebulae
B) in reflection nebulae
C) in dark nebulae
D) in planetary nebulae