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Deck 13: Stellar Evolution: the Lives and Deaths of Stars
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Deck 13: Stellar Evolution: the Lives and Deaths of Stars
1
Our Sun will fade in luminosity as its supply of hydrogen drops in a billion years.
False
2
A typical star burns helium for about the same amount of time it burns hydrogen.
False
3
Paradoxically, while the core of the red giant is contracting and heating up, its radiation pressure causes its photosphere to swell up and cool off.
True
4
Once the helium flash occurs at stage 10, the star stabilizes again on the horizontal branch of the H- R diagram, but now hundreds of times as bright as on the main sequence.
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5
The initial rise off the main sequence in stage 8 comes from gravitational energy of the contracting helium core.
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6
All stars have roughly the same luminosity after the helium flash.
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7
About 90% of the star's total life is spent on the main sequence.
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8
The luminosity of the red giant during its second trip to the upper right on the H- R diagram is less than before the helium flash expansion.
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9
The main reason that stars evolved off the main sequence is because they are becoming less massive as energy is lost into space from the proton- proton cycle.
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10
Helium fusion requires a higher temperature than hydrogen fusion.
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11
The helium flash increases the star's luminosity.
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12
The least massive red main- sequence stars may have lifetimes of a trillion years.
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13
The helium flash stage lasts several thousand years.
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14
Low- mass stars may become hundreds of times more luminous as giants than they were on the main sequence.
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15
A star system may undergo two or more nova outbursts.
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16
As a main- sequence star, the Sun's hydrogen supply should last about 10 billion years from the zero- age main sequence until its evolution to the giant stages.
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17
The helium flash shows up on the H- R diagram on the way to the horizontal branch.
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18
While more massive than most of its neighbors, our Sun is still technically a low- mass star.
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19
Our Sun should become a planetary nebula in another five billion years.
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20
A star may undergo two or more red giant expansion stages.
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21
It is the formation of iron in an evolved giant's core that triggers a Type II supernova event.
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22
White dwarfs were once the cores of stars that produced planetary nebulae.
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23
The density of white dwarf stars is about a million times that of the Sun.
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24
Our Sun will eventually become a nova.
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25
Compared to the interstellar medium, the gases in a planetary nebula will be richer in helium and carbon.
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26
Solar mass stars eventually become hot enough for carbon nuclei to fuse together.
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27
A massive star may change its color and size notably, but its high luminosity remains fairly constant.
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28
Although mass transfer can occur in binary stars, the small mass change does not impact the evolution of either companion.
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29
Only low mass stars experience the temporary instability of the helium flash; high mass stars go directly into heavier element formation.
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30
Our Sun will first become a red giant, then a white dwarf, and finally a brown dwarf.
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31
Today the majority of the mass of the universe is already in the form of black dwarfs, the solution to the "dark matter" problem.
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32
In the cores of the most massive stars, the electrons and protons fuse together and form neutrons.
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33
Our Sun will never become hot enough for carbon nuclei to fuse.
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34
As their name implies, all planetary nebulae feature spherical shells and look like the disks of Uranus or Neptune.
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35
The nova event is created by the helium flash.
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36
The formation of carbon requires a core temperature of about 100 million K, but iron takes much higher temperatures and pressures.
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37
While there are none yet, in the very distant future, most normal matter will be in the form of black dwarfs.
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38
Like emission nebulae, planetary nebulae glow because hot stars are causing the gases to ionize when exposed to strong ultraviolet radiation.
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39
A white dwarf's atoms have their electron orbitals crushed as closely as the Exclusion Principle allows.
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40
Elements heavier than iron are formed mainly in supernovae.
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41
Because they all involve the detonation of a carbon- rich white dwarf at the Chandrasekhar limit, all Type I supernovae are approximately equally luminous.
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42
Novae are more closely related to Type II than to Type I supernovae.
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43
Supernova 1987A was the first supernova observed by astronomers since Galileo first turned a telescope to the heavens.
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44
Type II supernova spectra are poor in hydrogen because stars that explode this way use up all their hydrogen before they leave the main sequence.
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45
While luminous enough to be seen with the naked eye, Supernova 1987A was, in fact, in our companion galaxy, the Large Magellanic Cloud.
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46
A massive star can fuse only up to the element silicon in its core.
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47
Neutrinos can move faster than c, the speed of light, as was discovered in SN1987A in 1987.
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48
A star system can become a Type I supernova several times.
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49
Chandrasekhar's limit is 1.4 times the mass of our Sun.
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50
Most of the energy released during a supernova is emitted as neutrinos.
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51
A 100 million- year- old open cluster will no longer contain any O- type stars.
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52
The number of Type I and Type II supernovae observed are approximately equal.
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53
A carbon- detonation supernova starts out as a white dwarf in a close binary system.
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54
The helium flash is followed within a few million years by the Type II supernova.
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55
If a white dwarf gains enough mass from a nearby star to exceed its Chandrasekhar limit it will become a nova.
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56
Our Sun will likely die as a Type I supernova in about five billion years.
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57
Because they all involve formation of iron in the cores of massive stars, all Type II supernovae are approximately equally luminous.
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58
Supergiant stars are burning different fuels in several shells around the core.
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59
Gold is rare since the only time it can be formed is during a supernova.
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60
Novae and Type II supernovae are essentially the same phenomena.
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61
When a low mass star first runs short of hydrogen in its core, it becomes brighter because
A) its outer, cooler layers are shed, and we see the brighter central core.
B) the helium flash increases the size of the star immensely.
C) the core contracts, raising the temperature and extending the hydrogen burning shell outward.
D) it explodes as a nova.
E) helium fusion gives off more energy than does hydrogen.
A) its outer, cooler layers are shed, and we see the brighter central core.
B) the helium flash increases the size of the star immensely.
C) the core contracts, raising the temperature and extending the hydrogen burning shell outward.
D) it explodes as a nova.
E) helium fusion gives off more energy than does hydrogen.
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62
The helium flash converts helium nuclei into
A) iron.
B) carbon.
C) oxygen.
D) boron.
E) beryllium.
A) iron.
B) carbon.
C) oxygen.
D) boron.
E) beryllium.
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63
What temperature is needed to fuse helium into carbon?
A) 5,800 K
B) 100,000 K
C) 15 million K
D) 100 million K
E) one billion K
A) 5,800 K
B) 100,000 K
C) 15 million K
D) 100 million K
E) one billion K
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64
A surface explosion on a white dwarf, caused by falling matter from the atmosphere of its binary companion, creates what kind of object?
A) nova
B) black dwarf
C) brown dwarf
D) Type I supernova
E) Type II supernova
A) nova
B) black dwarf
C) brown dwarf
D) Type I supernova
E) Type II supernova
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65
Supernova 1987A matched the theoretical predictions for Type I supernovae well.
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66
A white dwarf has the mass of the Sun and the volume of
A) Earth.
B) the Moon.
C) Mars.
D) Jupiter.
E) Eros.
A) Earth.
B) the Moon.
C) Mars.
D) Jupiter.
E) Eros.
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67
During the hydrogen shell burning phase
A) the star remains at the same luminosity it had before.
B) the core is expanding.
C) the star becomes less luminous.
D) hydrogen is burning in the central core.
E) the star grows more luminous.
A) the star remains at the same luminosity it had before.
B) the core is expanding.
C) the star becomes less luminous.
D) hydrogen is burning in the central core.
E) the star grows more luminous.
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68
A star (no matter what its mass) spends most of its life
A) as a protostar.
B) as a red giant or supergiant.
C) as a planetary nebula.
D) as a main- sequence star.
E) as a T- Tauri variable star.
A) as a protostar.
B) as a red giant or supergiant.
C) as a planetary nebula.
D) as a main- sequence star.
E) as a T- Tauri variable star.
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69
Which of these is true of planetary nebulae?
A) They are the material which causes the eclipses in eclipsing binary systems.
B) They are ejected envelopes surrounding a highly evolved low- mass star.
C) They are expelled by the most massive stars in their final stages before supernova.
D) They are rings of material around protostars that will accrete into planets in time.
E) They are the envelopes that form when blue stragglers merge.
A) They are the material which causes the eclipses in eclipsing binary systems.
B) They are ejected envelopes surrounding a highly evolved low- mass star.
C) They are expelled by the most massive stars in their final stages before supernova.
D) They are rings of material around protostars that will accrete into planets in time.
E) They are the envelopes that form when blue stragglers merge.
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70
Blue stragglers are among the first stars formed in a cluster.
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71
The spectra of the oldest stars show the most heavy elements.
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72
The blue stragglers represent the horizontal branch for globular clusters.
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73
A solar- mass star will evolve off the main sequence when
A) it completely runs out of hydrogen.
B) it explodes as a violent nova.
C) it builds up a core of inert helium.
D) it expels a planetary nebula to cool off and release radiation.
E) it loses all its neutrinos, so fusion must cease.
A) it completely runs out of hydrogen.
B) it explodes as a violent nova.
C) it builds up a core of inert helium.
D) it expels a planetary nebula to cool off and release radiation.
E) it loses all its neutrinos, so fusion must cease.
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74
A star is on the horizontal branch of the H- R diagram. Which statement is true?
A) It is about to experience the helium flash.
B) It is burning both hydrogen and helium.
C) It is burning only helium.
D) The star is contracting.
E) The star is about to return to the main sequence.
A) It is about to experience the helium flash.
B) It is burning both hydrogen and helium.
C) It is burning only helium.
D) The star is contracting.
E) The star is about to return to the main sequence.
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75
A(n) represents a relatively peaceful mass loss as a red giant becomes a white dwarf.
A) supernova
B) supernova remnant
C) planetary nebula
D) nova
E) emission nebula
A) supernova
B) supernova remnant
C) planetary nebula
D) nova
E) emission nebula
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76
Can a star become a red giant more than once?
A) no, or we would see them as the majority of naked- eye stars
B) no, it will lose so much mass as to cross the Chandrasekhar Limit
C) yes, before and after the helium flash
D) yes, before and after the Type II supernova event
E) no, the planetary nebula blows off all the outer shells completely
A) no, or we would see them as the majority of naked- eye stars
B) no, it will lose so much mass as to cross the Chandrasekhar Limit
C) yes, before and after the helium flash
D) yes, before and after the Type II supernova event
E) no, the planetary nebula blows off all the outer shells completely
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77
Compared to our Sun, a typical white dwarf has
A) a smaller mass and half the density.
B) a larger mass and a hundred times lower density.
C) about the same mass and a million times higher density.
D) about the same mass and density.
E) a smaller mass and twice the density.
A) a smaller mass and half the density.
B) a larger mass and a hundred times lower density.
C) about the same mass and a million times higher density.
D) about the same mass and density.
E) a smaller mass and twice the density.
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78
Globular clusters are dominated by bright red supergiants at the top right of the H- R diagram.
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79
When a star's inward gravity and outward pressure are balanced, the star is said to be
A) in gravitational collapse.
B) in rotational equilibrium.
C) in hydrostatic equilibrium.
D) in thermal expansion.
E) a stage 2 protostar.
A) in gravitational collapse.
B) in rotational equilibrium.
C) in hydrostatic equilibrium.
D) in thermal expansion.
E) a stage 2 protostar.
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80
The outward pressure in the core of a red giant balances the inward pull of gravity when
A) the electrons and protons have combined to form neutrons.
B) hydrogen begins fusing into helium.
C) iron forms in the inner core.
D) carbon fuses into heavier elements.
E) the electron orbits are compressed so much they are all in contact.
A) the electrons and protons have combined to form neutrons.
B) hydrogen begins fusing into helium.
C) iron forms in the inner core.
D) carbon fuses into heavier elements.
E) the electron orbits are compressed so much they are all in contact.
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