Deck 16: The Sun: Our Parent Star

A)Halley's Comet's nucleus
B)the Earth
C)Mercury
D)the Moon
E)Jupiter

A)troposphere
B)chromosphere
C)photosphere
D)ionosphere
E)corona

A)the Sun's radius.
B)the Sun's temperature.
C)the Sun's mass.
D)the Sun's luminosity.
E)the Sun's rotational period.

A)the energy received from the Sun on Earth's surface.
B)the energy received from the Sun at the location of Earth.
C)the energy received from the Sun at any location in the solar system.
D)the energy emitted by the Sun at the photosphere.
E)the total energy emitted by the Sun in all directions.

A)the temperature of the core of the Sun.
B)the structure of the atmosphere of the Sun.
C)the interior structure of the Sun.
D)the production of energy in the Sun.
E)the magnetic field of the Sun.

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

A)differentiation
B)ionization
C)radiation
D)convection
E)conduction

A)80-100%
B)70-90%
C)60-80%
D)50-70%
E)30-60%

A)the Sun is most dense somewhere between its surface and its core.
B)the Sun is least dense somewhere between its surface and its core.
C)the Sun is more dense at its surface than at its core.
D)the Sun is more dense at its core than at its surface.
E)the Sun has about the same density throughout its interior.

A)The Sun has no surface at all...the photosphere is an illusion.
B)You could stand on the surface.
C)The Sun doesn't have a solid surface.
D)The Sun's surface is too highly magnetized for anything to survive there.
E)You could stand on it, if a sufficiently protective spacesuit could be designed.

A)convection and radiation.
B)convection and gravitation.
C)pressure and radiation.
D)radiation and gravitation.
E)gravitation and pressure.

A)3,500 K.
B)5,800 K.
C)12,300 K.
D)300,000 K.
E)15 million K.

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

A)110
B)about a thousand
C)a little over a million
D)almost ten million
E)close to a billion

A)the energy received by the Sun on Earth's surface.
B)the energy received by the Sun at the location of Earth.
C)the energy received by the Sun at any location in the solar system.
D)the energy emitted by the Sun at the photosphere.
E)the total energy emitted by the Sun in all directions.

A)is balanced by the inward gravitational pressure.
B)is increasing the Sun's diameter.
C)is cooling the photosphere.
D)is responsible for variations in the sunspot cycle.
E)weakens the magnetic field.

A)91%.
B)71%.
C)27%.
D)9%.
E)less than 1%.

A)invisible.
B)violet.
C)blue.
D)yellow.
E)red.

A)the Zeeman Effect.
B)the Doppler Effect.
C)the selection effect.
D)the greenhouse effect.
E)adaptive optics.

A)in a geosynchronous orbit around the Earth.
B)in near-Earth orbit.
C)about 1.5 million kilometers from Earth at the L1 Lagrangian Point.
D)on the far side of the Sun at the L3 Langrangian Point.
E)on the far side of the Moon.

A)a flare.
B)a ray.
C)a coronal hole.
D)a prominence.
E)a coronal mass ejection.

A)91%.
B)71%.
C)27%.
D)9%.
E)less than 1%.

A)granules
B)sunspots
C)flares
D)prominences
E)coronal holes

A)chromosphere.
B)transition zone.
C)corona.
D)radiative zone.
E)granulation in the photosphere.

A)12 hours.
B)a week.
C)2 weeks.
D)a month.
E)5.5 years.

A)91%.
B)71%.
C)27%.
D)9%.
E)less than 1%.

A)filaments.
B)granulation.
C)sunspots.
D)convective projections.
E)prominences.

A)10,000 km
B)1,000 km
C)100 km
D)10 km
E)1 km

A)convection, conduction
B)radiative diffusion, convection
C)conduction, radiative diffusion
D)radiative diffusion, conduction
E)conduction, convection

A)between 25 and 35 days
B)365.25 days
C)about 7 years
D)about 11 years
E)about 76 years

A)No one knows why that part of the Sun's atmosphere does not drift away into space.
B)During total solar eclipses, the corona sometimes disappears from view.
C)The corona seems to absorb 2/3 of the neutrinos that pass through it.
D)The corona is much hotter than layers of the Sun that are closer to the solar interior.
E)The Sun's corona extends to the outer reaches of the solar system.

A)less than a day
B)a few years
C)a few decades
D)a few centuries
E)tens of millions of years, comparable to the convection cycle in Earth's mantle

A)that the standard solar model requires substantial modification.
B)that all stars show the same kind of vibrations that our Sun does.
C)that there is an unknown energy transport mechanism in the Sun.
D)that there is less convection in the Sun than predicted by the standard solar model.
E)that the standard solar model accurately models the observed solar vibrations.

A)the Sun is hottest somewhere between its surface and its core.
B)the Sun is coolest somewhere between its surface and its core.
C)the Sun is hotter at its surface than at its core.
D)the Sun is hotter at its core than at its surface.
E)the Sun has about the same temperature throughout its interior.

A)green (the famous flash).
B)yellow, like the photosphere below it.
C)red, due to ionized hydrogen at lower pressure.
D)blue, due to the ionization of nitrogen by the magnetic fields.
E)white from the moonlight.

A)The Sun takes that time to rotate on its axis.
B)The complete sunspot cycle, including magnetic field reversals.
C)Solar vibrations begin every 22 years.
D)Solar activity goes from its maximum to minimum.
E)The corona reaches its maximum temperature and ejects gas every 22 years.

A)are always found close to the Sun's poles.
B)come in pairs, representing the north and south magnetic fields.
C)were most numerous during the Maunder Minimum.
D)travel over the surface of the Sun from pole to pole.
E)are relatively constant in number every year.

A)They would appear blue-white, like Sirius but brighter.
B)Because sunspots are dark spots, they would be invisible against the blackness of space.
C)They would shine bright orange in color, like Arcturus.
D)They would not appear any differently than on the surface of the Sun.
E)They would shine only with reflected sunlight, appearing similar to Venus.

A)the shift of spectral lines.
B)the temperature of the Sun.
C)the solar wind.
D)the splitting of spectral lines.
E)the spectral parallax.

A)the Dust Bowl drought of the 1930s.
B)the Maunder Minimum from 1645-1715.
C)the Sporer Minimum that doomed the Anasazi.
D)the fall of Rome.
E)Joseph's seven lean years in the Old Testament.

A)can change forms in the eight minutes from the Sun's core to us
B)almost massless
C)can travel very close to the speed of light
D)neutral in charge
E)cannot interact at all with normal matter

A)massless.
B)a spin conservation particle.
C)an anti-electron.
D)the chief means energy reaches the photosphere.
E)intermediate between the proton and neutron in mass.

A)disappears.
B)is more irregular.
C)cools almost to the temperature of the photosphere.
D)becomes smooth and even.
E)shrinks to half its normal size.

A)The Sun is less luminous than usual.
B)This is a period of low solar activity.
C)Earth's climate will be unusually cold.
D)The Sun's rotation is slower than average.
E)There are likely to be an above average number of flares and prominences.

A)5,800 K.
B)11,000 K.
C)127,000 K.
D)10 million K.
E)100 million K.

A)They are hotter than the surrounding areas of the Sun.
B)They are extremely cold objects, as cold as Pluto.
C)They are extremely hot, but cooler than the surrounding areas of the Sun.
D)They are solid bodies floating on the surface of the Sun.
E)They are associated with areas of very low magnetic fields.

A)simultaneously
B)8.5 minutes later
C)about 12 hours
D)about 4 days
E)no relation between the two

A)reverses every 22 years.
B)reverses every 11 years.
C)is consistent for all sunspots in the same hemisphere.
D)is unrelated between different sunspots.
E)changes the color of sunspots.

A)It is recycled back into hydrogen.
B)It is ejected into space.
C)It is converted to energy.
D)It is transformed into electrons.
E)Conservation of mass dictates no mass can be lost.

A)sunspots.
B)flares.
C)the entire photosphere.
D)coronal holes.
E)the Sun's poles only.

A)solar rainbows.
B)haloes.
C)prominences.
D)filaments.
E)flares.

A)sunspots
B)prominences
C)granulation
D)flares
E)aurora

A)droughts in North America.
B)asteroid impacts on Earth.
C)change of which political party has the majority in the U.S. Congress.
D)the length of Mercury's day.
E)the length of Saturn's year.

A)oxidation of carbon in the core.
B)gravitational collapse of the helium coreward.
C)dark energy.
D)the strong force fusing hydrogen into helium.
E)the weak force creating energy from uranium decay.

A)36 days.
B)6 months.
C)year.
D)11 years.
E)76 years.