Deck 10: The Sun: Our Parent Star

A) 3,200 K.
B) 5,800 K.
C) 11,000 K.
D) one million K.
E) ten million K.

A) 100
B) 1,000
C) 10,000
D) 100,000
E) one million

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

A) the fact that the amount of hydrogen turning into helium in the core is fixed
B) the stability of the Sun's luminosity for as long as life has existed on Earth
C) the regularity of the 11- year sunspot cycle
D) the amount of energy the Earth receives per unit area and unit time
E) the fact that features on the Sun appear to never change

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

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

A) 2020.
B) 2017.
C) 2019.
D) 2023.
E) 2027.

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

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

A) 3,000 K.
B) 5,800 K.
C) 2,300,000 K.
D) 10 million K.
E) 100 million K.

A) gravity
B) electromagnetic repulsion
C) the strong nuclear force
D) dark energy
E) the weak nuclear force

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

A) conduction; radiation
B) conduction; convection
C) radiation; convection
D) radiation; conduction
E) convection; conduction

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

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

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

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

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

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

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

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

A) the size of Earth, around 12,000 km across.
B) the size of Texas, about 1,000 km across.
C) as big as Jupiter, around 100,000 km wide.
D) the size of our Moon, about 3,000 km across.
E) the size of a city, 20- 30 kilometers across.

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

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

A) aurora
B) granule
C) sunspot
D) prominence
E) flare

A) prominence
B) aurora
C) granule
D) flare
E) sunspot

A) 2 protons -deuterium + a positron + an antineutrino + X- rays
B) 4 protons -1 helium 4 + a positron + a neutrino + gamma rays
C) 4 protons -1 helium 4 + 2 neutrinos + gamma rays
D) 4 protons -2 helium 2 + 2 positrons + ultraviolet radiation
E) 6 protons -2 helium 4 + 3 positrons + 3 neutrinos + gamma rays

A) prominences.
B) the solar wind.
C) flares.
D) sunspots.
E) aurora.

A) granules.
B) auroras.
C) prominences.
D) flares.
E) sunspots.

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

A) 2
B) 10
C) 11
D) 22
E) 44

A) iron
B) helium
C) oxygen
D) carbon
E) hydrogen

A) radio waves.
B) infrared radiation.
C) ultraviolet light.
D) gamma rays.
E) X- rays.

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

A) 6.00 × 108 J
B) 1.80 × 1017 J
C) 9.00 × 1016 J
D) 1.50 × 108 J
E) 6.00 × 104 J

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

A) the Sun's core is cooling down, producing less neutrinos that expected.
B) 2/3 of the neutrinos transform into a new type during the 8- minute trip to Earth.
C) the Earth's ozone layer absorbs 2/3 of the neutrinos in transit.
D) the corona is opaque to much of the neutrino radiation.
E) our solar energy equations were just wrong, and needed much reworking.

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