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Deck 16: Stars in the Slow Lanelow-Mass Stellar Evolution

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Question
Which star spends the longest time as a main-sequence star?

A) <strong>Which star spends the longest time as a main-sequence star?</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Which star spends the longest time as a main-sequence star?</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Which star spends the longest time as a main-sequence star?</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Which star spends the longest time as a main-sequence star?</strong> A) B) C) D) <div style=padding-top: 35px>
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Question
A star like the Sun will eventually become an electron degenerate white dwarf star.
Question
A Type I supernova is as luminous as 10 billion Suns.
Question
Stars with masses similar to the Sun will loose about 30 percent of their mass before they become white dwarfs.
Question
The evolutionary cutoff between low- and high-mass stars occurs at approximately

A) <strong>The evolutionary cutoff between low- and high-mass stars occurs at approximately</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>The evolutionary cutoff between low- and high-mass stars occurs at approximately</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>The evolutionary cutoff between low- and high-mass stars occurs at approximately</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>The evolutionary cutoff between low- and high-mass stars occurs at approximately</strong> A) B) C) D) <div style=padding-top: 35px>
Question
The main-sequence lifetime of a star is given by the equation

A) <strong>The main-sequence lifetime of a star is given by the equation</strong> A) . B) . C) . D) . <div style=padding-top: 35px> .
B) <strong>The main-sequence lifetime of a star is given by the equation</strong> A) . B) . C) . D) . <div style=padding-top: 35px> .
C) <strong>The main-sequence lifetime of a star is given by the equation</strong> A) . B) . C) . D) . <div style=padding-top: 35px> .
D) <strong>The main-sequence lifetime of a star is given by the equation</strong> A) . B) . C) . D) . <div style=padding-top: 35px> .
Question
The Sun eventually could become a nova.
Question
When a star burns hydrogen in a shell,it will never produce as much energy (per unit time)as when it burns hydrogen in the core because the core has a higher temperature.
Question
If a main-sequence star's core temperature increased,fusion reaction rates would decrease because the protons would be moving faster.
Question
A main-sequence star is unique because

A) hydrostatic equilibrium exists at all radii.
B) energy transport occurs via convection throughout much of its interior.
C) hydrogen burning occurs in its core.
D) it emits strong surface winds.
Question
A low-mass star that burns helium in its core and hydrogen in a shell is more luminous than a similar star that burns only hydrogen in a shell around a dead core.
Question
The more massive a star,the more hydrogen it has to burn,and the longer its main-sequence lifetime will be.
Question
Pressure from degenerate electrons keeps the core of a red giant star from collapsing.
Question
The percent of hydrogen in the Sun's core today is roughly half of what it had originally.
Question
Stars evolve primarily because they run out of fuel in their cores.
Question
What factor is most important in determining a star's position on the main sequence and subsequent evolution?

A) Temperature
B) Pressure
C) Mass
D) Radius
Question
Binary stars can evolve to become novae and supernovae because slight differences in mass can mean large differences in main-sequence lifetimes.
Question
A A star will evolve through the same phases as a star.<div style=padding-top: 35px> star will evolve through the same phases as a A star will evolve through the same phases as a star.<div style=padding-top: 35px> star.
Question
The Sun will become a red giant star in about 2 billion years.
Question
Once the core of a low-mass main-sequence star runs out of hydrogen,fusion in the star stops until the core temperature is high enough for helium fusion to begin.
Question
As a red giant star evolves,hydrogen shell burning proceeds increasingly faster due to

A) rotational energy from the star's rapid rotation.
B) heat released from the core's contraction.
C) pressure from the contracting envelope.
D) This is a trick question.Hydrogen actually burns increasingly slower with time.
Question
The Sun will likely stop being a main-sequence star in

A) 5,000 years.
B) 5 million years.
C) 500 million years.
D) 5 billion years.
Question
When a G2 star leaves the main sequence,

A) its luminosity and surface temperature both stay the same.
B) its luminosity and surface temperature both decrease.
C) its luminosity increases and its surface temperature decreases.
D) its luminosity and surface temperature both increase.
Question
What is the escape velocity from the surface of a <strong>What is the escape velocity from the surface of a star that has a radius of ?</strong> A) 60 km/s B) 120 km/s C) 240 km/s D) 620 km/s <div style=padding-top: 35px> star that has a radius of <strong>What is the escape velocity from the surface of a star that has a radius of ?</strong> A) 60 km/s B) 120 km/s C) 240 km/s D) 620 km/s <div style=padding-top: 35px> ?

A) 60 km/s
B) 120 km/s
C) 240 km/s
D) 620 km/s
Question
How long will a <strong>How long will a star live as a main-sequence star?</strong> A) 12 million years B) 1.8 billion years C) 12 billion years D) 180 million years <div style=padding-top: 35px> star live as a main-sequence star?

A) 12 million years
B) 1.8 billion years
C) 12 billion years
D) 180 million years
Question
A star's surface temperature during the horizontal branch phase is determined primarily by its

A) luminosity.
B) chemical composition.
C) magnetic field strength.
D) rotation rate.
Question
The luminosity of a star depends on

A) its mass,its age,and its distance.
B) its mass.
C) its age.
D) its mass and its age.
Question
When a star depletes its core supply of hydrogen,__________ dominates in the core and __________ dominates in the atmosphere.

A) pressure;pressure
B) pressure;gravity
C) gravity;gravity
D) gravity;pressure
Question
A low-mass main-sequence star's climb up the red giant branch is halted by

A) the end of hydrogen shell burning.
B) the beginning of helium fusion in the core.
C) electron-degeneracy pressure in the core.
D) instabilities in the star's expanding outer layers.
Question
Just as a low-mass main-sequence star runs out of fuel in its core,it grows more luminous.How is this possible?

A) It explodes.
B) It begins to fuse helium in the core.
C) Its core expands as it runs out of fuel.
D) Its core shrinks,bringing more hydrogen fuel into the burning region.
Question
During which phase of the evolution of a low-mass star does it have two separate regions of nuclear burning occurring in its interior?

A) main sequence
B) red giant
C) horizontal branch
D) white dwarf
Question
If the Milky Way formed stars at approximately a constant rate over the last 14 billion years,what fraction of the M stars that ever formed in it can still be found as main-sequence stars today? Note that M stars have a mass of approximately <strong>If the Milky Way formed stars at approximately a constant rate over the last 14 billion years,what fraction of the M stars that ever formed in it can still be found as main-sequence stars today? Note that M stars have a mass of approximately .</strong> A) 10 percent B) 33 percent C) 50 percent D) 100 percent <div style=padding-top: 35px> .

A) 10 percent
B) 33 percent
C) 50 percent
D) 100 percent
Question
A low-mass red giant star's energy comes from

A) hydrogen burning to helium in its core.
B) helium burning to carbon in its core.
C) hydrogen burning to helium in a shell surrounding its core.
D) helium burning to carbon in a shell surrounding its core.
Question
When a low-mass star becomes an AGB star and has a temperature of 3,300 K,at what wavelength will it shine the brightest?

A) 650 nm,red visible
B) 880 nm,infrared
C) 1 mm,microwave
D) 10 m,radio
Question
Degenerate refers to a state of matter at

A) high temperature.
B) high density.
C) high luminosity.
D) high mass.
Question
Asymptotic giant branch (AGB)stars have high-mass loss rates because

A) they are rotating quickly.
B) they have weak magnetic fields.
C) they have strong winds.
D) they have low surface gravity.
Question
When helium fusion begins in the core of a red giant star,the situation quickly gets out of control because electron-degeneracy pressure does not respond to changes in

A) luminosity.
B) density.
C) gravity.
D) temperature.
Question
Helium burns in the core of a horizontal branch star via __________ and produces __________.

A) the triple-alpha reaction;carbon
B) the proton-proton chain;lithium
C) the triple-alpha reaction;oxygen
D) the proton-proton chain;iron
Question
What is the radius of a red giant star that has a temperature of <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D) <div style=padding-top: 35px> and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )

A) <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D) <div style=padding-top: 35px>
Question
As a main-sequence star burns its core supply of hydrogen,what happens?

A) Helium begins to fuse throughout the core.
B) Helium fuses in a shell surrounding the core.
C) Helium fusion takes place only at the very center of the core,where temperature and pressure are highest.
D) Helium builds up as ash in the core.
Question
What ionizes the gas in a planetary nebula and makes it visible?

A) X-ray photons emitted by a pulsar
B) Ultraviolet photons emitted by a white dwarf
C) The shock wave from a supernova
D) Hydrogen burning in the nebular gas
Question
Why does the core of a main-sequence star have to be hotter to burn helium into carbon than hydrogen into helium?
Question
Explain the two different forms of pressure that support the core of a low-mass main-sequence star and the core of a low-mass red giant star?
Question
How many times longer does a How many times longer does a main-sequence star live compared to a main-sequence star?<div style=padding-top: 35px> main-sequence star live compared to a How many times longer does a main-sequence star live compared to a main-sequence star?<div style=padding-top: 35px> main-sequence star?
Question
Calculate the main-sequence lifetimes of the following stars of different spectral types: Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results?<div style=padding-top: 35px> , Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results?<div style=padding-top: 35px> , Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results?<div style=padding-top: 35px> , Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results?<div style=padding-top: 35px> ,and Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results?<div style=padding-top: 35px> .What trend do you notice in your results?
Question
A Type I supernova has a luminosity of approximately

A) <strong>A Type I supernova has a luminosity of approximately</strong> A) . B) . C) . D) . <div style=padding-top: 35px> .
B) <strong>A Type I supernova has a luminosity of approximately</strong> A) . B) . C) . D) . <div style=padding-top: 35px> .
C) <strong>A Type I supernova has a luminosity of approximately</strong> A) . B) . C) . D) . <div style=padding-top: 35px> .
D) <strong>A Type I supernova has a luminosity of approximately</strong> A) . B) . C) . D) . <div style=padding-top: 35px> .
Question
The Ring Nebula is a planetary nebula that currently has a radius of 0.4 pc and an expansion velocity of 250 km/s.Approximately how long ago did its parent star die and eject its outer layers?

A) 1,600 years ago
B) 3,200 years ago
C) 5,400 years ago
D) 28,000 years ago
Question
In what two ways does temperature affect the rate of nuclear reactions?
Question
A <strong>A star in a binary system could create the following chemical element and eject it into the interstellar medium:</strong> A) carbon B) helium C) iron D) All of the above <div style=padding-top: 35px> star in a binary system could create the following chemical element and eject it into the interstellar medium:

A) carbon
B) helium
C) iron
D) All of the above
Question
A star like the Sun will lose about __________ of its mass before it evolves to become a white dwarf.

A) 3 percent
B) 10 percent
C) 30 percent
D) 70 percent
Question
If a <strong>If a white dwarf could accrete matter from a binary companion at a rate of ,how long would it take before it exploded as a Type I supernova?</strong> A) 600 thousand years B) 20 million years C) 200 milllion years D) 600 million years <div style=padding-top: 35px> white dwarf could accrete matter from a binary companion at a rate of <strong>If a white dwarf could accrete matter from a binary companion at a rate of ,how long would it take before it exploded as a Type I supernova?</strong> A) 600 thousand years B) 20 million years C) 200 milllion years D) 600 million years <div style=padding-top: 35px> ,how long would it take before it exploded as a Type I supernova?

A) 600 thousand years
B) 20 million years
C) 200 milllion years
D) 600 million years
Question
A nova is the result of which explosive situation?

A) Mass transfer onto a white dwarf
B) Helium burning in a degenerate stellar core
C) A white dwarf which exceeds the Chandrasekhar limit
D) The collision of members of a binary system
Question
What would you need to measure about a planetary nebula to determine how long ago its parent star died?

A) The mass of the white dwarf
B) The mass and radius of the white dwarf
C) The nebula's temperature and radius
D) The nebula's radius and expansion velocity
Question
In a white dwarf,what is the source of pressure that halts its contraction as it cools?

A) Thermal pressure of the extremely hot gas
B) Electrons packed so closely that they become incompressible
C) Neutrons that resist being pressed further together
D) Carbon nuclei that repulse each other strongly because they each contain six protons
Question
A white dwarf with a temperature of 30,000 K would shine brightest at what wavelength?

A) 4 nm,X-rays
B) 100 nm,ultraviolet
C) 400 nm,blue visible
D) 1 μ\mu m,infrared
Question
One star in a binary will almost always become a red giant before the other because

A) one star is always larger than the other.
B) binaries always have one star twice as massive as the other.
C) small differences in main-sequence masses yield large differences in main-sequence ages.
D) the more massive binary star always gets more mass from the less massive binary star when both are main-sequence stars.
Question
Consider a red giant star with a luminosity of Consider a red giant star with a luminosity of and a radius of .Using the luminosity-temperature-radius relationship ,calculate how hot this star's surface temperature will be compared to the Sun,whose temperature is 5,800 K.<div style=padding-top: 35px> and a radius of Consider a red giant star with a luminosity of and a radius of .Using the luminosity-temperature-radius relationship ,calculate how hot this star's surface temperature will be compared to the Sun,whose temperature is 5,800 K.<div style=padding-top: 35px> .Using the luminosity-temperature-radius relationship Consider a red giant star with a luminosity of and a radius of .Using the luminosity-temperature-radius relationship ,calculate how hot this star's surface temperature will be compared to the Sun,whose temperature is 5,800 K.<div style=padding-top: 35px> ,calculate how hot this star's surface temperature will be compared to the Sun,whose temperature is 5,800 K.
Question
A Type I supernova occurs when a white dwarf exceeds a mass of __________.

A) <strong>A Type I supernova occurs when a white dwarf exceeds a mass of __________.</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>A Type I supernova occurs when a white dwarf exceeds a mass of __________.</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>A Type I supernova occurs when a white dwarf exceeds a mass of __________.</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>A Type I supernova occurs when a white dwarf exceeds a mass of __________.</strong> A) B) C) D) <div style=padding-top: 35px>
Question
What is a planetary nebula?

A) A planet surrounded by a glowing shell of gas
B) The disk of gas and dust surrounding a young star that will soon form a star system
C) The ejected envelope of a giant star surrounding the remains of a star
D) A type of young,medium-mass star
Question
The gas in a planetary nebula is composed of

A) primarily hydrogen from the surrounding interstellar medium.
B) primarily hydrogen from the post-asymptotic giant branch star.
C) hydrogen and elements processed in the core of the post-asymptotic giant branch star.
D) primarily helium from the post-asymptotic giant branch star.
Question
What is the shortest phase of evolution for a one solar mass star that we can visibly see?
Question
When the Sun becomes an AGB star,its radius will be approximately When the Sun becomes an AGB star,its radius will be approximately .If its mass at this point will be approximately the same as it is now,how will its surface gravity as an AGB star compare to its present surface gravity as a main-sequence star? Note that .<div style=padding-top: 35px> .If its mass at this point will be approximately the same as it is now,how will its surface gravity as an AGB star compare to its present surface gravity as a main-sequence star? Note that When the Sun becomes an AGB star,its radius will be approximately .If its mass at this point will be approximately the same as it is now,how will its surface gravity as an AGB star compare to its present surface gravity as a main-sequence star? Note that .<div style=padding-top: 35px> .
Question
What stops a red giant from cooling to continuously lower temperatures,and why?
Question
What is "degenerate" in the degenerate core of a white dwarf?
Question
Explain the significance of Roche lobes in a binary system.
Question
Why are novae thought to be recurrent?
Question
What types of chemical elements can low-mass stars contribute to the enrichment of the interstellar medium and how are they produced?
Question
How can the core of a star be degenerate with respect to the electrons but nondegenerate with respect to the nuclei?
Question
Consider a Consider a star's journey up the red giant branch.Its luminosity will change from to nearly .How will its temperature and radius change as the star ascends? (Recall that . )<div style=padding-top: 35px> star's journey up the red giant branch.Its luminosity will change from Consider a star's journey up the red giant branch.Its luminosity will change from to nearly .How will its temperature and radius change as the star ascends? (Recall that . )<div style=padding-top: 35px> to nearly Consider a star's journey up the red giant branch.Its luminosity will change from to nearly .How will its temperature and radius change as the star ascends? (Recall that . )<div style=padding-top: 35px> .How will its temperature and radius change as the star ascends? (Recall that Consider a star's journey up the red giant branch.Its luminosity will change from to nearly .How will its temperature and radius change as the star ascends? (Recall that . )<div style=padding-top: 35px> . )
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Deck 16: Stars in the Slow Lanelow-Mass Stellar Evolution
1
Which star spends the longest time as a main-sequence star?

A) <strong>Which star spends the longest time as a main-sequence star?</strong> A) B) C) D)
B) <strong>Which star spends the longest time as a main-sequence star?</strong> A) B) C) D)
C) <strong>Which star spends the longest time as a main-sequence star?</strong> A) B) C) D)
D) <strong>Which star spends the longest time as a main-sequence star?</strong> A) B) C) D)
2
A star like the Sun will eventually become an electron degenerate white dwarf star.
True
3
A Type I supernova is as luminous as 10 billion Suns.
True
4
Stars with masses similar to the Sun will loose about 30 percent of their mass before they become white dwarfs.
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5
The evolutionary cutoff between low- and high-mass stars occurs at approximately

A) <strong>The evolutionary cutoff between low- and high-mass stars occurs at approximately</strong> A) B) C) D)
B) <strong>The evolutionary cutoff between low- and high-mass stars occurs at approximately</strong> A) B) C) D)
C) <strong>The evolutionary cutoff between low- and high-mass stars occurs at approximately</strong> A) B) C) D)
D) <strong>The evolutionary cutoff between low- and high-mass stars occurs at approximately</strong> A) B) C) D)
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6
The main-sequence lifetime of a star is given by the equation

A) <strong>The main-sequence lifetime of a star is given by the equation</strong> A) . B) . C) . D) . .
B) <strong>The main-sequence lifetime of a star is given by the equation</strong> A) . B) . C) . D) . .
C) <strong>The main-sequence lifetime of a star is given by the equation</strong> A) . B) . C) . D) . .
D) <strong>The main-sequence lifetime of a star is given by the equation</strong> A) . B) . C) . D) . .
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7
The Sun eventually could become a nova.
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8
When a star burns hydrogen in a shell,it will never produce as much energy (per unit time)as when it burns hydrogen in the core because the core has a higher temperature.
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9
If a main-sequence star's core temperature increased,fusion reaction rates would decrease because the protons would be moving faster.
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10
A main-sequence star is unique because

A) hydrostatic equilibrium exists at all radii.
B) energy transport occurs via convection throughout much of its interior.
C) hydrogen burning occurs in its core.
D) it emits strong surface winds.
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11
A low-mass star that burns helium in its core and hydrogen in a shell is more luminous than a similar star that burns only hydrogen in a shell around a dead core.
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12
The more massive a star,the more hydrogen it has to burn,and the longer its main-sequence lifetime will be.
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13
Pressure from degenerate electrons keeps the core of a red giant star from collapsing.
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14
The percent of hydrogen in the Sun's core today is roughly half of what it had originally.
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15
Stars evolve primarily because they run out of fuel in their cores.
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16
What factor is most important in determining a star's position on the main sequence and subsequent evolution?

A) Temperature
B) Pressure
C) Mass
D) Radius
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17
Binary stars can evolve to become novae and supernovae because slight differences in mass can mean large differences in main-sequence lifetimes.
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18
A A star will evolve through the same phases as a star. star will evolve through the same phases as a A star will evolve through the same phases as a star. star.
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19
The Sun will become a red giant star in about 2 billion years.
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20
Once the core of a low-mass main-sequence star runs out of hydrogen,fusion in the star stops until the core temperature is high enough for helium fusion to begin.
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21
As a red giant star evolves,hydrogen shell burning proceeds increasingly faster due to

A) rotational energy from the star's rapid rotation.
B) heat released from the core's contraction.
C) pressure from the contracting envelope.
D) This is a trick question.Hydrogen actually burns increasingly slower with time.
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22
The Sun will likely stop being a main-sequence star in

A) 5,000 years.
B) 5 million years.
C) 500 million years.
D) 5 billion years.
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23
When a G2 star leaves the main sequence,

A) its luminosity and surface temperature both stay the same.
B) its luminosity and surface temperature both decrease.
C) its luminosity increases and its surface temperature decreases.
D) its luminosity and surface temperature both increase.
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24
What is the escape velocity from the surface of a <strong>What is the escape velocity from the surface of a star that has a radius of ?</strong> A) 60 km/s B) 120 km/s C) 240 km/s D) 620 km/s star that has a radius of <strong>What is the escape velocity from the surface of a star that has a radius of ?</strong> A) 60 km/s B) 120 km/s C) 240 km/s D) 620 km/s ?

A) 60 km/s
B) 120 km/s
C) 240 km/s
D) 620 km/s
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25
How long will a <strong>How long will a star live as a main-sequence star?</strong> A) 12 million years B) 1.8 billion years C) 12 billion years D) 180 million years star live as a main-sequence star?

A) 12 million years
B) 1.8 billion years
C) 12 billion years
D) 180 million years
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26
A star's surface temperature during the horizontal branch phase is determined primarily by its

A) luminosity.
B) chemical composition.
C) magnetic field strength.
D) rotation rate.
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27
The luminosity of a star depends on

A) its mass,its age,and its distance.
B) its mass.
C) its age.
D) its mass and its age.
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28
When a star depletes its core supply of hydrogen,__________ dominates in the core and __________ dominates in the atmosphere.

A) pressure;pressure
B) pressure;gravity
C) gravity;gravity
D) gravity;pressure
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29
A low-mass main-sequence star's climb up the red giant branch is halted by

A) the end of hydrogen shell burning.
B) the beginning of helium fusion in the core.
C) electron-degeneracy pressure in the core.
D) instabilities in the star's expanding outer layers.
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30
Just as a low-mass main-sequence star runs out of fuel in its core,it grows more luminous.How is this possible?

A) It explodes.
B) It begins to fuse helium in the core.
C) Its core expands as it runs out of fuel.
D) Its core shrinks,bringing more hydrogen fuel into the burning region.
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31
During which phase of the evolution of a low-mass star does it have two separate regions of nuclear burning occurring in its interior?

A) main sequence
B) red giant
C) horizontal branch
D) white dwarf
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32
If the Milky Way formed stars at approximately a constant rate over the last 14 billion years,what fraction of the M stars that ever formed in it can still be found as main-sequence stars today? Note that M stars have a mass of approximately <strong>If the Milky Way formed stars at approximately a constant rate over the last 14 billion years,what fraction of the M stars that ever formed in it can still be found as main-sequence stars today? Note that M stars have a mass of approximately .</strong> A) 10 percent B) 33 percent C) 50 percent D) 100 percent .

A) 10 percent
B) 33 percent
C) 50 percent
D) 100 percent
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33
A low-mass red giant star's energy comes from

A) hydrogen burning to helium in its core.
B) helium burning to carbon in its core.
C) hydrogen burning to helium in a shell surrounding its core.
D) helium burning to carbon in a shell surrounding its core.
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34
When a low-mass star becomes an AGB star and has a temperature of 3,300 K,at what wavelength will it shine the brightest?

A) 650 nm,red visible
B) 880 nm,infrared
C) 1 mm,microwave
D) 10 m,radio
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35
Degenerate refers to a state of matter at

A) high temperature.
B) high density.
C) high luminosity.
D) high mass.
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36
Asymptotic giant branch (AGB)stars have high-mass loss rates because

A) they are rotating quickly.
B) they have weak magnetic fields.
C) they have strong winds.
D) they have low surface gravity.
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37
When helium fusion begins in the core of a red giant star,the situation quickly gets out of control because electron-degeneracy pressure does not respond to changes in

A) luminosity.
B) density.
C) gravity.
D) temperature.
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38
Helium burns in the core of a horizontal branch star via __________ and produces __________.

A) the triple-alpha reaction;carbon
B) the proton-proton chain;lithium
C) the triple-alpha reaction;oxygen
D) the proton-proton chain;iron
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39
What is the radius of a red giant star that has a temperature of <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D) and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )

A) <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D)
B) <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D)
C) <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D)
D) <strong>What is the radius of a red giant star that has a temperature of and a temperature of 4,000 K? (Note that the temperature of the Sun is 5,800 K. )</strong> A) B) C) D)
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40
As a main-sequence star burns its core supply of hydrogen,what happens?

A) Helium begins to fuse throughout the core.
B) Helium fuses in a shell surrounding the core.
C) Helium fusion takes place only at the very center of the core,where temperature and pressure are highest.
D) Helium builds up as ash in the core.
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41
What ionizes the gas in a planetary nebula and makes it visible?

A) X-ray photons emitted by a pulsar
B) Ultraviolet photons emitted by a white dwarf
C) The shock wave from a supernova
D) Hydrogen burning in the nebular gas
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42
Why does the core of a main-sequence star have to be hotter to burn helium into carbon than hydrogen into helium?
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43
Explain the two different forms of pressure that support the core of a low-mass main-sequence star and the core of a low-mass red giant star?
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44
How many times longer does a How many times longer does a main-sequence star live compared to a main-sequence star? main-sequence star live compared to a How many times longer does a main-sequence star live compared to a main-sequence star? main-sequence star?
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45
Calculate the main-sequence lifetimes of the following stars of different spectral types: Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results? , Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results? , Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results? , Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results? ,and Calculate the main-sequence lifetimes of the following stars of different spectral types: , , , ,and .What trend do you notice in your results? .What trend do you notice in your results?
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46
A Type I supernova has a luminosity of approximately

A) <strong>A Type I supernova has a luminosity of approximately</strong> A) . B) . C) . D) . .
B) <strong>A Type I supernova has a luminosity of approximately</strong> A) . B) . C) . D) . .
C) <strong>A Type I supernova has a luminosity of approximately</strong> A) . B) . C) . D) . .
D) <strong>A Type I supernova has a luminosity of approximately</strong> A) . B) . C) . D) . .
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47
The Ring Nebula is a planetary nebula that currently has a radius of 0.4 pc and an expansion velocity of 250 km/s.Approximately how long ago did its parent star die and eject its outer layers?

A) 1,600 years ago
B) 3,200 years ago
C) 5,400 years ago
D) 28,000 years ago
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48
In what two ways does temperature affect the rate of nuclear reactions?
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49
A <strong>A star in a binary system could create the following chemical element and eject it into the interstellar medium:</strong> A) carbon B) helium C) iron D) All of the above star in a binary system could create the following chemical element and eject it into the interstellar medium:

A) carbon
B) helium
C) iron
D) All of the above
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50
A star like the Sun will lose about __________ of its mass before it evolves to become a white dwarf.

A) 3 percent
B) 10 percent
C) 30 percent
D) 70 percent
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51
If a <strong>If a white dwarf could accrete matter from a binary companion at a rate of ,how long would it take before it exploded as a Type I supernova?</strong> A) 600 thousand years B) 20 million years C) 200 milllion years D) 600 million years white dwarf could accrete matter from a binary companion at a rate of <strong>If a white dwarf could accrete matter from a binary companion at a rate of ,how long would it take before it exploded as a Type I supernova?</strong> A) 600 thousand years B) 20 million years C) 200 milllion years D) 600 million years ,how long would it take before it exploded as a Type I supernova?

A) 600 thousand years
B) 20 million years
C) 200 milllion years
D) 600 million years
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52
A nova is the result of which explosive situation?

A) Mass transfer onto a white dwarf
B) Helium burning in a degenerate stellar core
C) A white dwarf which exceeds the Chandrasekhar limit
D) The collision of members of a binary system
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53
What would you need to measure about a planetary nebula to determine how long ago its parent star died?

A) The mass of the white dwarf
B) The mass and radius of the white dwarf
C) The nebula's temperature and radius
D) The nebula's radius and expansion velocity
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54
In a white dwarf,what is the source of pressure that halts its contraction as it cools?

A) Thermal pressure of the extremely hot gas
B) Electrons packed so closely that they become incompressible
C) Neutrons that resist being pressed further together
D) Carbon nuclei that repulse each other strongly because they each contain six protons
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55
A white dwarf with a temperature of 30,000 K would shine brightest at what wavelength?

A) 4 nm,X-rays
B) 100 nm,ultraviolet
C) 400 nm,blue visible
D) 1 μ\mu m,infrared
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56
One star in a binary will almost always become a red giant before the other because

A) one star is always larger than the other.
B) binaries always have one star twice as massive as the other.
C) small differences in main-sequence masses yield large differences in main-sequence ages.
D) the more massive binary star always gets more mass from the less massive binary star when both are main-sequence stars.
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57
Consider a red giant star with a luminosity of Consider a red giant star with a luminosity of and a radius of .Using the luminosity-temperature-radius relationship ,calculate how hot this star's surface temperature will be compared to the Sun,whose temperature is 5,800 K. and a radius of Consider a red giant star with a luminosity of and a radius of .Using the luminosity-temperature-radius relationship ,calculate how hot this star's surface temperature will be compared to the Sun,whose temperature is 5,800 K. .Using the luminosity-temperature-radius relationship Consider a red giant star with a luminosity of and a radius of .Using the luminosity-temperature-radius relationship ,calculate how hot this star's surface temperature will be compared to the Sun,whose temperature is 5,800 K. ,calculate how hot this star's surface temperature will be compared to the Sun,whose temperature is 5,800 K.
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58
A Type I supernova occurs when a white dwarf exceeds a mass of __________.

A) <strong>A Type I supernova occurs when a white dwarf exceeds a mass of __________.</strong> A) B) C) D)
B) <strong>A Type I supernova occurs when a white dwarf exceeds a mass of __________.</strong> A) B) C) D)
C) <strong>A Type I supernova occurs when a white dwarf exceeds a mass of __________.</strong> A) B) C) D)
D) <strong>A Type I supernova occurs when a white dwarf exceeds a mass of __________.</strong> A) B) C) D)
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59
What is a planetary nebula?

A) A planet surrounded by a glowing shell of gas
B) The disk of gas and dust surrounding a young star that will soon form a star system
C) The ejected envelope of a giant star surrounding the remains of a star
D) A type of young,medium-mass star
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60
The gas in a planetary nebula is composed of

A) primarily hydrogen from the surrounding interstellar medium.
B) primarily hydrogen from the post-asymptotic giant branch star.
C) hydrogen and elements processed in the core of the post-asymptotic giant branch star.
D) primarily helium from the post-asymptotic giant branch star.
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61
What is the shortest phase of evolution for a one solar mass star that we can visibly see?
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62
When the Sun becomes an AGB star,its radius will be approximately When the Sun becomes an AGB star,its radius will be approximately .If its mass at this point will be approximately the same as it is now,how will its surface gravity as an AGB star compare to its present surface gravity as a main-sequence star? Note that . .If its mass at this point will be approximately the same as it is now,how will its surface gravity as an AGB star compare to its present surface gravity as a main-sequence star? Note that When the Sun becomes an AGB star,its radius will be approximately .If its mass at this point will be approximately the same as it is now,how will its surface gravity as an AGB star compare to its present surface gravity as a main-sequence star? Note that . .
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63
What stops a red giant from cooling to continuously lower temperatures,and why?
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64
What is "degenerate" in the degenerate core of a white dwarf?
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65
Explain the significance of Roche lobes in a binary system.
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66
Why are novae thought to be recurrent?
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67
What types of chemical elements can low-mass stars contribute to the enrichment of the interstellar medium and how are they produced?
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68
How can the core of a star be degenerate with respect to the electrons but nondegenerate with respect to the nuclei?
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69
Consider a Consider a star's journey up the red giant branch.Its luminosity will change from to nearly .How will its temperature and radius change as the star ascends? (Recall that . ) star's journey up the red giant branch.Its luminosity will change from Consider a star's journey up the red giant branch.Its luminosity will change from to nearly .How will its temperature and radius change as the star ascends? (Recall that . ) to nearly Consider a star's journey up the red giant branch.Its luminosity will change from to nearly .How will its temperature and radius change as the star ascends? (Recall that . ) .How will its temperature and radius change as the star ascends? (Recall that Consider a star's journey up the red giant branch.Its luminosity will change from to nearly .How will its temperature and radius change as the star ascends? (Recall that . ) . )
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