Deck 12: Star Stuff

A) The core quickly heats up and expands.
B) The star breaks apart in a violent explosion.
C) The core suddenly contracts.
D) The core stops fusing helium.
E) The star starts to fuse helium in a shell outside the core.

A) that life would be impossible without energy from the Sun
B) that the Earth formed at the same time as the Sun
C) that the carbon, oxygen, and other elements essential to life were created by nucleosynthesis in stellar cores
D) that the Sun formed from the interstellar medium: the "stuff" between the stars
E) that the Universe contains billions of stars

A) molecular clouds do not have enough material to form such massive stars.
B) they would fragment into binary stars because of their rapid rotation.
C) they would generate so much power that they would blow themselves apart.
D) they would shine exclusively at X-ray wavelengths and would be difficult to detect.
E) they would be too massive for hydrogen fusion to occur in their cores.

A) hydrogen.
B) oxygen.
C) carbon.
D) nitrogen.
E) iron.

A) About 150 solar masses
B) About 50 solar masses
C) About 2 solar masses
D) About 1 solar mass
E) About 0.08 solar masses

A) nuclear fusion and gravitational contraction
B) nuclear fission and gravitational contraction
C) nuclear fusion and nuclear fission
D) chemical reactions and gravitational contraction
E) nuclear fusion and chemical reactions

A) how long ago it was born
B) when it will die
C) where it is located
D) what surface temperature and luminosity it will have at each stage of its life
E) all of the above

A) a disk of gas surrounding a protostar that may form into planets
B) what is left of its planets after a low-mass star has ended its life
C) the expanding shell of gas that is no longer gravitationally bound to the remnant of a low-mass star
D) the molecular cloud from which protostars form
E) the expanding shell of gas that is left when a white dwarf explodes as a supernova

A) when the protostar assembles from its parent molecular cloud
B) the instant when hydrogen fusion first begins in the star's core
C) when the rate of hydrogen fusion in the star's core is high enough to sustain gravitational equilibrium
D) when a star becomes luminous enough to emit thermal radiation
E) when hydrogen fusion is occurring throughout the star's interior

A) The outer layers of the star are no longer gravitationally attracted to the core.
B) Hydrogen fusion in a shell outside the core generates enough thermal pressure to push the upper layers outward.
C) Helium fusion in the core generates enough thermal pressure to push the upper layers outward.
D) Helium fusion in a shell outside the core generates enough thermal pressure to push the upper layers outward.
E) The internal radiation generated by the hydrogen fusion in the core has heated the outer layers enough that they can expand after the star is no longer fusing hydrogen.

A) hotter and brighter.
B) hotter and dimmer.
C) cooler and brighter.
D) cooler and dimmer.
E) the same temperature and brightness.

A) 100,000 K
B) 1 million K
C) 10 million K
D) 100 million K
E) 100 billion K

A) It will become a white dwarf.
B) It will become a neutron star.
C) It will become a black hole.
D) It will slowly evaporate to nothing.
E) It will remain a brown dwarf forever.

A) Degeneracy pressure varies with the temperature of the star.
B) Degeneracy pressure can halt gravitational contraction of a star even when no fusion is occurring in the core.
C) Degeneracy pressure keeps any protostar less than 0.08 solar mass from becoming a true, hydrogen-fusing star.
D) Degeneracy pressure is a consequence of the laws of quantum mechanics.

A) Its core contracts, but its outer layers expand and the star becomes bigger and brighter.
B) It contracts, becoming smaller and dimmer.
C) It contracts, becoming hotter and brighter.
D) It expands, becoming bigger but dimmer.
E) Its core contracts, but its outer layers expand and the star becomes bigger but cooler and therefore remains at the same brightness.

A) It contracts from a protostar to a main-sequence star.
B) It breaks apart in a violent explosion.
C) It becomes a white dwarf.
D) It becomes a neutron star.
E) none of the above

A) A low-mass star
B) An intermediate-mass star
C) A high-mass star

A) 2
B) 3
C) 4
D) It varies depending on the reaction
E) Helium cannot fuse into carbon

A) 10%
B) 20%
C) 50%
D) 90%
E) 100%

A) always a white dwarf
B) always a neutron star
C) always a black hole
D) either a white dwarf or a neutron star
E) either a neutron star or a black hole

A) by gravitational contraction
B) by hydrogen shell burning around an inert helium core
C) by core hydrogen fusion
D) by core helium fusion combined with hydrogen shell burning
E) by both hydrogen and helium shell burning around an inert carbon core

A) The core contracts and becomes a white dwarf.
B) The core contracts and becomes a ball of neutrons.
C) The core contracts and becomes a black hole.
D) The star explodes violently, leaving nothing behind.
E) Gravity is not able to overcome neutron degeneracy pressure.

A) the onset of helium burning after a helium flash in a star with mass comparable to that of the Sun
B) the sudden outpouring of X-rays from a newly formed accretion disk
C) the sudden collapse of an iron core into a compact ball of neutrons
D) the beginning of neon burning in an extremely massive star
E) the expansion of a low-mass star into a red giant

A) It doesn't make sense to find a giant in a binary star system.
B) The odds of ever finding two such massive stars in the same binary system are so small as to make it inconceivable.
C) The two stars in a binary system should both be at the same point in stellar evolution; that is, they should either both be main-sequence stars or both be giants.
D) The two stars should be the same age, so the more massive one should have become a giant first.
E) A star with a mass of 15 solar masses is too big to be a main-sequence star.

A) a white dwarf made primarily of carbon and oxygen.
B) a white dwarf made primarily of silicon and iron.
C) a neutron star.
D) a black hole.
E) a supernova.

A) the process by which helium is fused into carbon, nitrogen, and oxygen
B) the process by which carbon is fused into nitrogen and oxygen
C) a type of hydrogen fusion that uses carbon, nitrogen, and oxygen atoms as catalysts
D) the period of a massive star's life when carbon, nitrogen, and oxygen are fusing in different shells outside the core
E) the period of a low-mass star's life when it can no longer fuse carbon, nitrogen, and oxygen in its core

A) hotter and brighter.
B) hotter and dimmer.
C) cooler and brighter.
D) cooler and dimmer.
E) the same temperature and brightness.

A) red giant, protostar, main-sequence, white dwarf
B) white dwarf, main-sequence, red giant, protostar
C) protostar, red giant, main-sequence, white dwarf
D) protostar, main-sequence, white dwarf, red giant
E) protostar, main-sequence, red giant, white dwarf

A) Each successive stage of fusion requires higher temperatures than the previous stages.
B) As each stage ends, the core shrinks further.
C) Each successive stage creates an element with a higher atomic weight.
D) Each successive stage lasts for approximately as long as the first, hydrogen fusion stage.

A) It is significantly less massive than the Sun.
B) It is larger in radius than the Sun.
C) It is brighter than the Sun.
D) Its surface temperature is lower than the Sun's.
E) Its core temperature is higher than the Sun's.

A) all stars that are red in color
B) all stars that are yellow in color
C) stars that are at least several times the mass of the Sun
D) stars that are similar in mass to the Sun
E) stars that have reached an age of 10 billion years

A) were produced in the Big Bang.
B) are produced in the interstellar medium.
C) are produced in the atmospheres of red giant stars.
D) are produced in supernova explosions.
E) are produced in the cores of low-mass stars

A) Because the supernova event destroys the star, Betelgeuse would suddenly disappear from view.
B) We'd see a cloud of gas expanding away from the position where Betelgeuse used to be. Over a period of a few weeks, this cloud would fill our entire sky.
C) Betelgeuse would remain a dot of light but would suddenly become so bright that, for a few weeks, we'd be able to see this dot in the daytime.
D) Betelgeuse would suddenly appear to grow larger in size, soon reaching the size of the full moon. It would also be about as bright as the full moon.

A) It is likely to be located in the halo of the galaxy.
B) It contains some stars that are burning helium in their cores.
C) It is the type of cluster known as an open cluster of stars.
D) It probably contains no young stars at all.
E) It is likely to be spherical in shape.

A) less than 1 billion years.
B) about 1 billion years.
C) about 4.5 billion years.
D) about 10 billion years.
E) more than 15 billion years.

A) The giant must once have been the more massive star but transferred some of its mass to its companion.
B) Other than the very low odds of finding a system with two such massive stars, there is nothing surprising about the fact that such systems exist.
C) The two stars probably were once separate but became a binary when a close encounter allowed their mutual gravity to pull them together.
D) The main-sequence star probably is a pulsating variable star and therefore appears to be less massive than it really is.
E) Although both stars probably formed from the same clump of gas, the more massive one must have had its birth slowed so that it became a main-sequence star millions of years later than its less massive companion.

A) It occurred only a few dozen light-years from Earth.
B) It provided the first observational evidence that supernovae actually occur.
C) It provided the first evidence that neutron stars exist.
D) It was the first supernova detected in nearly 400 years.
E) It was the nearest supernova detected in nearly 400 years.

A) hydrogen
B) oxygen
C) silicon
D) iron

A) Because elements are mainly made in fusion reactions with hydrogen nuclei
B) Because when elements split in a fission reaction, they prefer to split with all the protons paired
C) Because elements are mainly made in fusion reactions with helium nuclei
D) There's no explanation, it's something of a mystery to be explained or it may be a coincidence.

A) It can only release energy by fusion.
B) It has the lowest mass per nuclear particle.
C) It has the highest nuclear mass.
D) It has the lowest nuclear mass.
E) It has the highest mass per nuclear particle. F) It can only release energy by fission.

A) Fusion reactions with neutrons
B) Radioactive decay of nuclei with odd numbers of protons
C) Fusion reactions with helium nuclei
D) Fusion reactions with hydrogen nuclei

A) Has higher main-sequence luminosities than high mass stars
B) Late in life, fuses carbon into oxygen
C) Ends its life as a supernova
D) Has longer lifetimes than high mass stars

A) The helium core will shrink and heat; a shell of hydrogen will start fusing.
B) The helium core will shrink, heat, and start fusing helium to carbon.
C) The core will collapse and a supernova will result.
D) The Sun will turn into a white dwarf and cool off forever.

A) They both are ways to fuse hydrogen nuclei to make helium.
B) They are both nuclear reactions; the CNO cycle makes carbon, nitrogen, and oxygen, and the proton cycle makes helium.
C) They are both cycles in star lives.
D) They both trigger at the same temperature.

A) O star
B) B star
C) M star
D) G star

A) A high-mass star
B) A white dwarf
C) The Sun
D) A low-mass star

A) O star
B) M star
C) B star
D) G star

A) Iron
B) Lead
C) Hydrogen
D) Oxygen
E) Uranium

A) Hydrogen
B) Boron
C) Oxygen
D) Lithium
E) Helium

A) Main sequence, red supergiant, supernova, neutron star
B) Main sequence, red supergiant, neutron star, supernova
C) Red supergiant, main sequence, neutron star, supernova
D) Red supergiant, main sequence, supernova, neutron star