Deck 13: Deaths of Stars

A) hydrogen core → hydrogen shell → helium shell → helium core
B) hydrogen core → helium core → hydrogen shell → helium shell
C) hydrogen core → hydrogen shell → helium core → helium shell → carbon core
D) hydrogen core → hydrogen shell → helium core → helium shell
E) hydrogen shell → hydrogen core → helium shell → helium core

A) they are formed from pure hydrogen
B) they never reach the minimum temperature required to fuse carbon
C) they never form white dwarf as remnants
D) they are always part of a close binary system
E) their interiors are well mixed, through strong convection

A) never develop a hydrogen-fusion shell
B) create large amounts of carbon and oxygen
C) have much shorter lifetimes than Sun-like stars
D) never begin hydrogen fusion
E) become brown dwarfs after they exhaust their hydrogen core

A) do not generate strong stellar winds
B) rotate faster
C) have stronger magnetic fields
D) can ignite carbon fusion
E) are never in binary systems

A) the solar wind will remove about 50% of the Sun's total mass
B) the solar wind will remove about 10% of the Sun's total mass
C) the solar wind will remove 1-2% of the Sun's total mass
D) the solar wind will remove a tiny fraction of the Sun's total mass
E) mass loss from the solar wind will be balanced by material falling onto the surface from the corona

A) the core expands as new fusion products collect there
B) the surface of the star becomes cooler
C) energy from hydrogen shell burning and helium fusion forces the outer layer to expand
D) the surface of the star becomes hotter
E) increased stellar winds carry large amounts of material off of the surface of the star

A) becomes completely degenerate in the core, changing the pressure-temperature relationship
B) cannot produce energy through fusion
C) will only fuse in the presence of even more massive nuclei
D) is not found in nature
E) decays radioactively before it can undergo fusion

A) generate more energy per atom than fusion of lighter elements
B) generate less total energy because less atoms are available
C) generate energy for longer periods of time for heavier elements
D) occur in shells further and further from the center of the core
E) occur in larger and larger volumes of the core

A) the difference between spherical and lobed appearance of planetary nebulae
B) production of heavy elements in supernova events
C) stars in close binaries that are lower mass, but more evolved, than their companion
D) the cooling of matter falling into a compact object in an accretion disk
E) the change in stellar winds from normal to superwind conditions

A) maximum mass of a white dwarf
B) lifetime of a white dwarf
C) temperature for carbon fusion
D) separation between medium- and high-mass stellar evolution
E) stellar surface temperature needed to ionize a planetary nebula

A) strongly affected by mass absorption from the interstellar medium
B) strongly affected by mass absorption from the corona
C) not affected by mass loss due to increased solar winds
D) strongly affected by mass loss due to increased solar winds
E) strongly affected by mass loss due to hydrogen fusion

A) hydrogen fusion in material on the surface of a white dwarf
B) carbon fusion in a white dwarf core
C) helium fusion in the core of a massive red giant
D) silicon fusion in the core of a high mass star
E) iron fusion in the core of a high mass star

A) their interior structure is controlled by radiative energy transport
B) they will never reach the temperature needed to ignite carbon fusion
C) their interior structure is controlled by convective energy transport
D) they have strong stellar winds throughout their main-sequence lifetimes
E) they will never reach the temperature required to establish a helium-fusion shell

A) electron-positron
B) electron-proton
C) proton-antiproton
D) neutrino-antineutrino
E) baryon-antibaryon

A) gravitational contraction
B) hydrogen fusion
C) helium fusion
D) mass loss
E) rapid rotation

A) ejected a planetary nebula
B) was a member of a close binary system
C) failed to ignite carbon
D) failed to ignite helium
E) became a red giant has a mass 20 times larger than our Sun

A) upward and to the right
B) upward and to the left
C) downward and to the right
D) straight downward
E) downward and to the left

A) the Sun
B) Jupiter
C) Earth
D) a large asteroid
E) a house

A) thousands of years
B) millions of years
C) hundreds of millions of years
D) billions of years
E) hundreds of billions of years

A) blackbody continuum radiation from the interstellar medium
B) line emission from the interstellar medium
C) scattering from dust grains ejected by a dying star
D) blackbody continuum radiation from a hot gas ejected by a dying star
E) line emission from ionized hydrogen gas ejected by a dying star

A) common, and important for some types of stellar evolution
B) common, but not important for stellar evolution
C) uncommon, but important for some types of stellar evolution
D) uncommon, but not important for stellar evolution
E) very rare, but important for some types of stellar evolution

A) expanding envelope of ionized gas expelled by a dying medium-mass star
B) expanding envelope of neutral gas and dust expelled by a dying medium-mass star
C) contracting envelope of dusty material from planets destroyed by a dying medium-mass star
D) contracting envelope of ionized interstellar medium absorbed by a dying medium-mass star
E) expanding atmosphere of a medium-mass star as it becomes a red giant

A) rapid rotation
B) magnetic fields
C) gas pressure
D) neutron degeneracy
E) electron degeneracy

A) magnetic fields around the neutron star
B) disintegration of iron in the core of the star
C) radioactive decay of nickel formed in the expanding shell of the supernova
D) fusion of the remaining hydrogen in the star
E) matter-antimatter disintegration around the collapsed core

A) Type Ia supernovae
B) Type Ib supernovae
C) Type II supernovae
D) novae
E) planetary nebulae

A) Supernovae are the main source of background radiation needed for mutations.
B) Chemical elements necessary for life can only be formed in supernovae.
C) The formation of the Sun was triggered by a supernova event.
D) Planets form by accretion of material in the expanding remnant of a supernova.
E) Neutrino bombardment was necessary to form the first simple proteins.

A) Only type Ia
B) Only type Ib
C) Only type II
D) type Ia and type II
E) type Ib and type II

A) a shock wave from the collapse of the iron core
B) a blast of gravitational waves emanating from the creation of a neutron star
C) a burst of neutrinos generated in the core collapse
D) energy from the radioactive decay of heavy elements
E) fusion of the remaining hydrogen in the star through a chain reaction

A) very common: there are thousands of detectable events occurring in our galaxy each year
B) common: a few dozen are detected in our galaxy each year
C) uncommon: there are only one or two detected in our galaxy each year
D) rare: only one or two occur each century in our galaxy
E) extremely rare: only one or two are detected in the Universe each decade

A) the fusion of hydrogen in the core
B) an increase in luminosity as the core becomes helium-enriched
C) the expansion of the outer layers of the Sun as a red giant
D) the supernova explosion caused by the collapse of the iron core
E) hydrogen detonation on the white dwarf remnant

A) cosmic rays
B) helium
C) dust
D) carbon
E) synchotron radiation

A) will collapse to form a neutron star
B) will explode as a nova, and may repeat the cycle over time
C) is completely destroyed by carbon deflagration
D) breaks apart and forms an excretion disk
E) becomes a degenerate object

A) oceans of water
B) a breathable atmosphere
C) organic chemicals
D) uranium in Earth's interior
E) a nickel-iron core

A) the SN1987a supernova
B) a supernova which triggered a mass extinction on Earth
C) a supernova recorded by Chinese astronomers
D) a supernova which triggered the formation of the Sun
E) a supernova in the Large Magellanic cloud

A) does not show hydrogen emission lines in the spectrum of the remnant
B) does not produce iron in the core before the explosion
C) is less luminous because the companion star absorbs most of the remnant material
D) is more likely to produce a neutron star than an isolated supernova
E) triggers a supernova in the binary companion

A) neutrino emission
B) iron absorption lines
C) a difference in luminosity of several thousand times
D) the presence or absence of hydrogen absorption lines
E) the presence or absence of hydrogen emission lines

A) the fusion of hydrogen in the core
B) an increase in luminosity as the core becomes helium-enriched
C) the expansion of the outer layers of the Sun as a red giant
D) the supernova explosion caused by the collapse of the iron core
E) hydrogen detonation on the white dwarf remnant