Deck 14: Our Starthe Sun

A) The Sun is combusting hydrogen in a fire and releasing energy.
B) The Sun is fusing hydrogen into uranium and releasing energy.
C) The Sun is creating hydrogen at very high temperatures.
D) The Sun is fusing hydrogen into helium and releasing energy.
E) The Sun is accumulating hydrogen from the solar wind and releasing energy.

A) None
B) 2
C) 4
D) 6
E) 12

A) Hydrogen is the most common element in stars.
B) Hydrogen nuclei have the smallest positive charge.
C) Hydrogen burning is the most efficient of all fusion or fission reactions.
D) Hydrogen can fuse at temperatures lower than other elements.
E) All these are valid reasons.

A) core, convective zone, radiative zone.
B) convective zone, radiative zone, core.
C) radiative zone, convective zone, core.
D) radiative zone, core, convective zone.
E) core, radiative zone, convective zone.

A) increases
B) decreases
C) stays the same
D) increases, and then decreases
E) There is not enough information to answer.

A) gravity
B) strong nuclear force
C) electric force
D) magnetic force
E) electrons pushing them together

A) It would produce less energy per second than it does now.
B) It would produce more energy per second than it does now.
C) Its energy production would vary more than it does now.
D) Its energy production would be more stable than it is now.
E) The Sun's energy production would not change.

A) only in the core, where energy production via fusion can balance gravity
B) in the outer layers of the atmosphere, where most of the visible light is produced
C) just outside the core, where heat from nuclear fusion is transported outward
D) throughout the Sun's interior.
E) only in the photosphere.

A) 10⁶ K
B) 1.5 * 10⁷ K
C) 2.5 * 10⁷ K
D) 10,000 K
E) 10⁹ K

A) It would shrink in size.
B) It would become more luminous.
C) It would greatly increase in size.
D) It would become less luminous.
E) It would not change.

A) 2 neutrons, 2 protons
B) 0 neutrons, 6 protons
C) 6 neutrons, 0 protons
D) 4 neutrons, 0 protons
E) 3 neutrons, 3 protons

A) gravitational contraction.
B) nuclear fission of uranium.
C) hydrogen fusion.
D) helium burning.
E) burning material as in a fire.

A) heat and centrifugal force.
B) core temperature and surface temperature.
C) pressure and gravity.
D) radiation and heat.
E) centrifugal force and gravity.

A) nuclear fission.
B) nuclear recombination.
C) nuclear splitting.
D) nuclear fusion.
E) ionization.

A) They quickly pass through the Sun's outer layers and are emitted into space.
B) They recombine to form electrons.
C) They eventually turn into neutrinos.
D) They are absorbed by other atoms, heating the Sun's core.
E) They are reflected around inside the Sun forever.

A) one helium nucleus as well as energy, electrons, and neutrinos.
B) one helium nucleus as well as deuterium, electrons, and energy.
C) one helium nucleus, as well as energy, positrons, and neutrinos.
D) two helium nuclei, as well as neutrinos and positrons.
E) pure energy.

A) visible wavelength photons
B) gamma ray photons, positrons, and neutrinos
C) ultraviolet photons and neutrinos
D) X-ray photons, electrons, and neutrinos
E) infrared photons and positrons

A) the energy production rate in the core equals the rate of radiation escaping the Sun's surface.
B) the source of energy in the core is stable and will sustain the Sun for millions of years.
C) the outer layers of the Sun absorb and re-emit the radiation from the core at increasingly shorter wavelengths.
D) radiation pressure does not contribute to supporting the weight of the overlying solar layers.
E) the core of the Sun has pressure that is lower than that of the outer layers.

A) only on its surface.
B) only in its core.
C) only in the solar wind.
D) both in its core and on its surface.
E) in its core, on its surface, and in the solar wind.

A) corona, chromosphere, photosphere.
B) chromosphere, corona, photosphere.
C) photosphere, chromosphere, corona.
D) corona, photosphere, chromosphere.
E) photosphere, corona, chromosphere

A) jumps in density between zones.
B) their temperature profiles.
C) pressure differences inside each zone.
D) their modes of energy production transport.
E) all of these.

A) age.
B) interior density.
C) total mass.
D) size.
E) temperature.

A) radiation.
B) convection.
C) conduction.
D) convection and conduction.
E) radiation and conduction.

A) radiation.
B) convection.
C) conduction.
D) convection and radiation.
E) radiation and conduction.

A) many thousands of years.
B) many millions of years.
C) seconds.
D) a few hours.
E) months.

A) 10⁴ years
B) 10⁸ years
C) 10¹⁰ years
D) 10¹¹ years
E) 10¹⁴ years

A) months
B) a few hours
C) seconds
D) about 100,000 years
E) more than a million years.

A) radar observations.
B) neutrino detections.
C) high-energy (gamma ray) observations.
D) helioseismology.
E) infrared observations.

A) 7 *10³⁷ reactions per second; 3 *10²⁶ watts
B) 3 * 10³⁸ reactions per second; 10²⁷ watts
C) 3*10³⁸ reactions per second; 4 * 10²⁶ watts
D) 7 *10³⁷ reactions per second; 5 * 10²⁵ watts
E) 3 * 10³⁷ reactions per second; 6 * 10²⁴ watts

A) the core
B) the radiative zone
C) the convective zone
D) the photosphere
E) the chromosphere

A) 8 minutes
B) 16 hours
C) 1,000 years
D) 100,000 years
E) 4.6 billion years

A) one-half as many
B) one-third as many
C) one-fourth as many
D) one-fifth as many
E) We would detect no neutrinos.

A) adjusting the rate of hydrogen burning in solar models.
B) Fixing a flaw in neutrino detector design that had reduced detection efficiency.
C) postulating that neutrinos had mass and oscillated between three different types.
D) lowering the percentage of helium in models of solar composition.
E) correctly measuring the density of the Sun's interior.

A) They interact very weakly with other particles.
B) They interact very strongly with other particles.
C) They are the only particles that move quickly.
D) They move very slowly.
E) They can only be found in atomic nuclei.

A) It tells us how quickly the Sun is expanding with time.
B) It helps us understand the solar interior better.
C) It reveals how rapidly the Sun's magnetic field is changing.
D) It helps us determine the surface temperature of the Sun.
E) It shows the relative gravitational strength of the orbiting planets.

A) the Sun's core is powered by proton-proton fusion.
B) energy transport by radiation occurs throughout much of the solar interior.
C) magnetic fields are responsible for surface activity on the Sun.
D) convection churns the base of the solar atmosphere.
E) sunspots are cooler than the rest of the photosphere.

A) radiation.
B) convection.
C) conduction.
D) convection and conduction.
E) radiation and conduction.

A) neutrinos have a very large mass.
B) neutrinos oscillate between three different types.
C) some neutrinos become photons during their journey.
D) some neutrinos interact more strongly with matter such that they are absorbed locally inside the Sun.
E) neutrinos have zero mass like photons.

A) photons
B) electrons
C) protons
D) neutrons
E) neutrinos

A) The solar wind would contain a higher density of particles.
B) The solar wind would become hotter.
C) The solar wind would move faster.
D) The composition of the solar wind would change.
E) Nothing would change.

A) hotter than the penumbra.
B) cooler than the penumbra.
C) the same temperature as the penumbra.
D) brighter than the penumbra.
E) made of a different material than the rest of the surface.

A) densities that are higher
B) densities that are lower
C) pressures that are higher
D) temperatures that are lower
E) temperatures that are higher

A) the chromosphere casts shadows on the edges of the Sun from our perspective.
B) the corona casts shadows on the edges of the Sun from our perspective.
C) the Sun is a higher temperature at the edges of the disk.
D) the viewing angle and lower temperature of the Sun's outer layers results in a dimming effect.
E) sunspots look much bigger when viewed edge-on.

A) 550 nm, visible
B) 2 * 10^-5 m, infrared
C) 4* 10^-7 m, ultraviolet
D) 3 *10^-9 m, X-rays
E) 6 m, radio

A) outer convection zone.
B) photosphere.
C) chromosphere.
D) corona.
E) solar wind.

A) region A
B) region B
C) region C
D) They are all the same temperature.
E) We would also need an X-ray image to determine relative temperatures.

A) sunspots
B) prominences
C) coronal mass ejections
D) solar flares
E) all of these

A) gravity
B) strong nuclear force
C) the Sun's magnetic field
D) the solar wind
E) sunspots

A) chromosphere
B) photosphere
C) radiative zone
D) convective zone
E) corona

A) emission
B) absorption
C) continuum
D) blackbody
E) X-ray

A) we observe it emitting radiation at visible wavelengths.
B) the chromosphere and the photosphere are that hot, too.
C) we observe absorption from highly ionized atoms of iron and calcium in its spectrum.
D) the gas emits most of its radiation at radio wavelengths.
E) all of the above

A) 550 nm, green visible light.
B) 656 nm, a red hydrogen emission line.
C) 16 mm, an ultraviolet emission line.
D) 21 cm, microwave emission.
E) 0.02 nm, X-ray emission.

A) penumbra.
B) umbra.
C) granule.
D) photosphere.
E) magnetic field.

A) chromosphere
B) photosphere
C) radiative zone
D) convective zone
E) corona

A) its differential rotation.
B) the solar wind.
C) changes in the rate of nuclear fusion in the core.
D) a liquid-conducting layer in the interior.
E) This is a trick question.The solar magnetic field is primordial.

A) coronal holes.
B) coronal mass ejections.
C) differential rotation.
D) temperature changes in the Sun's core.
E) all of these phenomena contribute.

A) it is hotter than the photosphere.
B) as the Sun rotates, the chromosphere appears to move away from us radially.
C) it has a higher concentration of heavy metals.
D) it is made of mostly helium.
E) its spectrum is dominated by H $\alpha$ emission.

A) the photosphere is cooler than the layers below it.
B) the photosphere is thin compared with the other layers in the Sun.
C) the photosphere is much less dense than the convection zone.
D) its high luminosity provides plenty of photons, resulting in extreme definition.
E) the Sun has a distinct surface.

A) A
B) B
C) C
D) D
E) E

A) debris from a comet collision blanketed the Sun.
B) almost no sunspots occurred on the Sun.
C) the Voyager 2 spacecraft traversed the heliopause.
D) very few dust storms occurred on Mars.
E) very few volcanic eruptions occurred on Mars.

A) about 8 minutes
B) several hours
C) about 2 days
D) about 1 week
E) around 1 month

A) is larger than the Moon.
B) is warmer than the Moon.
C) is shielded by the Moon.
D) has a magnetic field while the Moon does not.
E) is farther from the Sun than the Moon is.

A) returns to the same polarity every 11 years.
B) switches polarity every 22 years.
C) switches polarity every 11 years.
D) never changes polarity.
E) switches polarity every year.

A) 3625 K
B) 4100 K
C) 4500 K
D) 5200 K
E) 5500 K

A) when there are a maximum number of sunspots
B) when there are an average number of sunspots
C) when there are a minimum number of sunspots
D) The Sun's luminosity does not change.
E) The Sun's luminosity changes, but it has no relation to the number of sunspots.

A) sunspot.
B) corona.
C) Kuiper belt.
D) heliosphere.
E) solar shock.

A) 24 hours
B) 6 months
C) 1 year
D) 11 years
E) 22 years

A) expand.
B) contract.
C) remain approximately the same.
D) repel charged particles.
E) block out sunlight.

A) 24 hours.
B) 27 days.
C) 12 months.
D) 11 years.
E) 22 years.